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INTRODUCTION

Toxigenic cyanobacteria are one of the major health
risks associated with water resources, in Europe and be-
yond. Cyanobacteria can produce a wide range of potent
toxins (cyanotoxins) with adverse health effects on hu-
mans and animals exposed e.g., via drinking water, aqua-
culture and recreation. 

The hepatotoxic peptide toxins (microcystins: MCs)
occur annually in most countries and this cyanotoxin family
is considered a major concern in the European context.
MCs have been identified as undisputed health hazards by
the World Health Organization (WHO). Emerging cyan-
otoxins are also of concern in Europe; e.g., cylindrosper-

mopsin (CYN) which was viewed as being limited to
(sub)tropical waters but has been recently found in several
European countries. It has been postulated that such emerg-
ing cyanotoxins could be related to invasive cyanobacterial
species that are colonizing European waters. Recent re-
search has also demonstrated a definite relationship, on a
global scale, between temperature and the dominance of
cyanobacteria in water bodies (O’Neil et al., 2012).

Advanced methods have already been developed in
European laboratories to detect, identify and quantitate
cyanotoxins. Although ISO 20179:2005 introduced a stan-
dard method to determine MCs, other methods for cyan-
otoxin analysis are not harmonized across Europe.
Techniques including liquid chromatography - mass spec-

Advances in Oceanography and Limnology, 2017; 8(1): 161-178 ARTICLE
DOI: 10.4081/aiol.2017.6429
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0).

Toxic cyanobacteria and cyanotoxins in European waters - recent progress
achieved through the CYANOCOST Action and challenges for further research

Jussi Meriluoto,1,2* Ludek Blaha,3 Gorenka Bojadzija,4 Myriam Bormans,4 Luc Brient,4 Geoffrey A. Codd,5,6
Damjana Drobac,2 Elisabeth J. Faassen,7 Jutta Fastner,8 Anastasia Hiskia,9 Bastiaan W. Ibelings,10 Triantafyllos Kaloudis,11
Mikolaj Kokocinski,12 Rainer Kurmayer,13 Dijana Pantelić,2 Antonio Quesada,14 Nico Salmaso,15 Nada Tokodi,2
Theodoros M. Triantis,9 Petra M. Visser,16 Zorica Svirčev1,2

1Biochemistry, Faculty of Science and Engineering, Åbo Akademi University, Tykistökatu 6A, 20520 Turku, Finland; 2Laboratory for
Paleoenvironmental Reconstruction, Faculty of Sciences, University of Novi Sad, Trg Dositeja Obradovica 2, 21000 Novi Sad, Serbia;
3RECETOX, Faculty of Science, Masaryk University, Kamenice 5, CZ62500 Brno, Czech Republic; 4UMR ECOBIO 6553 CNRS
Université de Rennes, 1 Campus de Beaulieu, Rennes, France; 5Biological and Environmental Sciences, University of Stirling, Stirling
FK9 4LA, Scotland; 6College of Life Sciences, University of Dundee, Dow Street, Dundee DD1 5EH, Scotland; 7Aquatic Ecology &
Water Quality Management Group, Wageningen University, P.O. Box 47, Wageningen 6700 DD, The Netherlands; 8Section Drinking
Water Resources and Water Treatment, German Environment Agency, Corrensplatz 1, 14195 Berlin, Germany; 9Institute of Nanoscience
& Nanotechnology, National Center for Scientific Research “DEMOKRITOS”, Neapoleos 10, Ag. Paraskevi 153 10, Athens, Greece;
10Department F.-A. Forel for Environmental and Aquatic Sciences and Institute for Environmental Sciences, University of Geneva, 66
Boulevard Carl-Vogt, 1211 Geneva 4, Switzerland; 11Department of Water Quality Control, Athens Water Supply and Sewerage Com-
pany, Laodikias 29, Athens, Greece; 12Department of Hydrobiology, Faculty of Biology, Adam Mickiewicz University, Wieniawskiego
1, 61-712 Poznań, Poland; 13Research Institute for Limnology, University of Innsbruck, Mondseestrasse 9,
5310 Mondsee, Austria; 14Department of Biology, Universidad Autónoma de Madrid, 28049 Madrid, Spain; 15Department of Sustainable
Agrosystems and Bioresources, Research and Innovation Centre, Fondazione Edmund Mach, Via E. Mach 1, 38010 San Michele
all’Adige, TN, Italy; 16Department of Aquatic Microbiology, Institute for Biodiversity and Ecosystem Dynamics, University
of Amsterdam, P.O. Box 94248, 1090 GE Amsterdam, The Netherlands
*Corresponding author: jussi.meriluoto@abo.fi

ABSTRACT
This review aims to summarise the outcomes of some recent European research concerning toxic cyanobacteria and cyanotoxins,

with an emphasis on developments within the framework of the CYANOCOST Action: COST Action ES1105, Cyanobacterial Blooms
and Toxins in Water Resources: Occurrence, Impacts and Management. Highlights of the Action include phycological and ecological
studies, development of advanced techniques for cyanotoxin analysis, elucidation of cyanotoxin modes of action, management techniques
to reduce cyanobacterial mass development, and research on methods and practices for cyanotoxin removal during drinking water treat-
ment. The authors have identified a number of gaps in knowledge. Proposed directions for future research on toxic cyanobacteria and
cyanotoxins are also discussed.

Key words: Cyanobacteria; cyanotoxins; Europe; trends; gaps of knowledge.

Received: 29 November 2016. Accepted: 7 March 2017.N
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J. Meriluoto et al.162

trometry (LC-MS) have enabled cyanotoxin detection and
identification at very low concentrations. Rapid im-
munoassay methods, for on-site use, are also being devel-
oped in Europe, and merit dissemination with verification,
as kits, to increase capabilities in regions without high-
technology resources. 

Multiple techniques (proactive and reactive) have al-
ready been used to control cyanobacterial blooms in Eu-
rope, with varying degrees of success. Control measures
for cyanobacterial and cyanotoxin management have been
developed, and these range from catchment and basin-scale
management, to drinking water treatment methods for the
removal of cyanobacterial cells and cyanotoxins, including
sorption, filtration and advanced oxidation processes. 

An important part of almost any research is end-user
involvement. This is especially true in research concern-
ing public health questions including the research activi-
ties related to CYANOCOST. 

OCCURRENCE OF CYANOBACTERIA
AND CYANOTOXINS, AND METHODS
FOR MONITORING AND ANALYSIS

The continuing eutrophication of many aquatic
ecosystems and water resources in Europe is causing con-
cern because the deterioration of water quality and poten-
tially toxic blooms of cyanobacteria threaten human and
animal health. Throughout the CYANOCOST Action it
was shown that toxic cyanobacteria and various cyanotox-
ins are commonly found in all parts of Europe. However,
it is difficult to make firm conclusions about any trends
in the occurrence of toxic cyanobacteria and cyanotoxins
as monitoring has only recently been introduced in some
parts of Europe. There has been very little systematic
cyanotoxin monitoring of waters in most countries as the
cyanotoxin analyses have been primarily carried out by
academic partners involved in specific research projects
or, in some cases, by public or private water utilities ab-
stracting water from potentially high-risk sources. It is
also likely that there has been a certain bias towards the
cyanotoxins for which the analytical methods are more
widely established, i.e. for the MCs, and the full spectrum
of cyanotoxins present in Europe still remains to be com-
prehensively assessed. What can be concluded without
doubt is that those laboratories that have been involved in
cyanotoxin analyses for a longer time (some since the
1980s) continue to find MCs in many water environments
monitored since that time. In addition, further cyanobac-
terial hazards (invasive species and emerging/less-studied
toxins) are being discovered. The joint activity of
CYANOCOST and the NETLAKE COST Action
(ES1201), the European Multilake Survey (EMLS) con-
ducted in 2015 will be able to provide a snapshot of the
cyanobacterial/cyanotoxin situation in a wide range of Eu-

ropean waters when the analytical work concentrated in
selected laboratories has been finished. It would be highly
desirable to be able to continue and expand the monitoring
activities initiated within the EMLS and thus get a clearer
picture of any trends in cyanotoxin occurrence and abun-
dance in Europe.

Hepatotoxic MCs appear to be the most common and
to have the greatest known impacts on human health and
activities among the known cyanotoxins in aquatic ecosys-
tems including lakes and rivers across Europe. Major pro-
ducers of MCs include cyanobacteria from the genus
Microcystis and members of other cyanobacterial genera
including Planktothrix, Nostoc, Anabaena/Dolichosper-
mum and Anabaenopsis (Merel et al., 2013a, 2013b;
Bernard et al., 2017). Nodularin (NOD) hepatotoxins are
mostly known from the Baltic Sea. However, recently
nodularin was found also in aquatic ecosystems in Turkey
(Mazur-Marzec et al., 2013; Sahindokuyucu Kocasari et
al., 2015). Moreover, Nodularia spumigena Mertens ex
Bornet & Flahault, a NOD-producer, was recently observed
not only in brackish waters but also in freshwater lakes
(Akcaalan et al., 2009). 

Acutely-acting neurotoxins are much less common
than hepatotoxins but are still found in a large variety of
water ecosystems. Anatoxin-a (ANTX-a) and/or ho-
moanatoxin-a (hANTX-a) have been detected in lakes and
rivers in the UK, Ireland, France, Netherlands, Germany,
Italy, Denmark, Portugal, and Poland (Edwards et al.,
1992; Furey et al., 2003; Gugger et al., 2005; Messineo
et al., 2009; Osswald et al., 2009; Ballot et al., 2010;
Faassen et al., 2012b; Kobos et al., 2013). These toxins
are associated with several cyanobacteria including,
among others, species of Anabaena, Dolichospermum and
Aphanizomenon (for an updated list see Bernard et al.,
2017). A less toxic analogue, dihydroanatoxin-a was iso-
lated from different strains of Oscillatoria sp., Phormid-
ium sp. and Cylindrospermum stagnale Bornet & Flahault
(Méjean et al., 2014). Evidence for the potent acetyl-
cholinesterase inhibitor anatoxin-a(S) (Onodera et al.,
1997) has been found more rarely in Europe: to date, in
Denmark (Henriksen et al., 1997) and Scotland (Devic et
al., 2002). Saxitoxins (STXs) have also been rarely re-
ported from European freshwaters. These potent neuro-
toxins were observed in several countries including
France, Finland, and Spain associated mostly with the oc-
currence of Aphanizomenon spp. (Rapala et al., 2005;
Ledreux et al., 2010; Cirés et al., 2014).

The cytotoxin and genotoxin CYN was until recently
only known from warmer regions. During the last decade,
it has been detected in several European countries. A fur-
ther discussion about CYN is found later in this section. 

In addition to these three major groups of cyanotoxins,
i.e., hepatotoxins, neurotoxins and cytotoxins, there is
abundant toxicological evidence for further unidentified

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Toxic cyanobacteria in Europe - research progress through CYANOCOST 163

cyanobacterial bioactive/toxic compounds in aquatic
ecosystems in Europe (Elersek et al., 2017). Besides new
toxins and indications of a widening occurrence of known
toxins, future research may reveal new environments af-
fected with toxic/noxious cyanobacteria and their toxins.
Additional threats to aquatic ecosystems may be caused by
alien and invasive species that are expanding their geo-
graphical range (Kokociński et al., 2017). Cylindrosper-
mopsis raciborskii (Woloszynska) Seenayya & Subba Raju
is an example of a cyanobacterium that has increased its
distribution from tropical and subtropical regions towards
the temperate zone where it is now widespread. This
species is known for the production of CYN and STXs in
warmer regions but, so far, this was not confirmed in Eu-
rope. Recent studies, however, revealed the ability of this
cyanobacterium to produce unknown metabolites causing
toxic effects (Poniedziałek et al., 2015). Among other alien
species that occur more and more frequently in Europe are
Chrysosporum bergii (Ostenfeld) E. Zapomělová, O.
Skácelová, P. Pumann, R. Kopp & E. Janeček, Chrysospo-
rum ovalisporum (Forti) E. Zapomělová, O. Skácelová, P.
Pumann, R. Kopp & E. Janeček, and Sphaerospermopsis
aphanizomenoides (Forti) Zapomělová, Jezberová,
Hrouzek, Hisem, Reháková & Komárková. These are
known CYN-producers (with the exception of the last one
the toxicity of which remains debatable) (Quesada et al.,
2006; Kaštovskỳ et al., 2010; Koreivienė and Kasper-
ovičenė, 2011) and an increasing distribution and abun-
dance of these species may contribute to additional toxic
stress in European freshwaters. 

Already before 2012, i.e., the start of the CYANOCOST
Action, MCs and ANTXs had been involved in poisoning
episodes affecting animal and/or human health in Europe
but no health effects caused by CYN had been observed/re-
ported. The (apparent or true) increasing occurrence of
CYN in Europe is likely to change this picture, and health
effects caused by CYN can be expected especially in
Southern and Central Europe, the source of most of the re-
ports concerning CYN. In addition, there have been cases
of reported poisonings in European waters where un-
known/new cyanotoxins have been inferred but a more
exact identification was lacking. 

Health effects and poisoning episodes related to cyan-
otoxin-contaminated drinking and recreational waters
were documented during the lifetime of CYANOCOST.
However, the number of reported cases was relatively
low. This may indicate an increased awareness and im-
plementation of better monitoring and management sys-
tems for toxic cyanobacteria. There have also been
improvements in analytical capability for cyanotoxin de-
tection in many countries, partly thanks to increased in-
ternational collaboration and the spreading of know-how.
A possible reason for fewer reports in the scientific liter-
ature may be the fact that it is increasingly difficult to get

cyanotoxin episodes published unless something really
dramatic or novel is involved.

However, as shown by the Užice case reported here
(see Fate, impact and health effects), recognition of the
occurrence and impacts of toxigenic cyanobacteria re-
mains inadequate in Europe, and cyanotoxins continue to
cause serious health effects, not only in individuals but
also at the population level. The lack of international and
national regulatory guidelines for most cyanotoxins in
drinking water is a serious problem which needs to be ad-
dressed urgently and which was highlighted also in the
Užice case. While modern sensitive analytical equipment
can relatively easily comply with the most demanding
monitoring needs, the lack of regulatory guidelines for
most cyanotoxins is likely to give the cyanotoxins a lower
priority in monitoring. Also, the lack of commercial ana-
lytical reference materials is problematic. 

Among the cyanotoxins, there are two toxins of grow-
ing importance in European waters and elsewhere: CYN
and β-N-methylamino-L-alanine (BMAA). CYN is a potent
cytotoxic and genotoxic cyanotoxin initially detected in
Australia (Ohtani et al., 1992; Saker and Neilan, 2001).
Later, it was reported in New Zealand (Stirling and Quil-
liam, 2001), Thailand (Li et al., 2001) and other tropical
and subtropical regions (Rzymski and Poniedziałek, 2014).
CYN was named after the first identified producer C. raci-
borskii being involved in human poisoning and an outbreak
of hepatoenteritis among the aboriginal community in Aus-
tralia. Nowadays CYN has been detected more widely and
there are more than 12 known producers (de la Cruz et al.,
2013). In Europe, this toxin was first reported in Germany
in 2000 in two shallow lakes in the eastern part of Bran-
denburg (Fastner et al., 2003). Further, in Hungary in 2002
(Kiss et al., 2002), Italy and Spain in 2004 (Manti et al.,
2005; Quesada et al., 2006), Finland, France, the Czech Re-
public and Poland in 2006 (Spoof et al., 2006; Bláhová et
al., 2009; Brient et al., 2009; Kokociński et al., 2009). In
Europe, cyanobacteria capable of producing CYN have
most often been found in the genera Aphanizomenon, An-
abaena/Dolichospermum, Chrysosporum and Oscillatoria
(Kokociński et al., 2013; Rzymski and Poniedziałek, 2014;
Bernard et al., 2017). More potential producers of CYN
have been revealed lately including Dolichospermum men-
dotae (W. Trelease) P. Wacklin, L. Hoffmann & J. Komárek
in Turkey and the terrestrial cyanobacterium Hormoscilla
pringsheimii Anagnostidis & Komárek (Akcaalan et al.,
2014; Bohunická et al., 2015). Moreover, Gkelis and Za-
outsos (2014) for the first time reported CYN and a C. raci-
borskii bloom producing STX in Greece but a definitive
identification of the CYN producer could not be made. In
Europe, in contrast to warmer regions, thus only non-CYN
producing populations of C. raciborskii have been so far
identified except for a recent report from Serbia (Đorđević
et al., 2015). The latter observation however is disputable

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as no studies on isolated cultures of this cyanobacterium
were performed. Complementary studies have been re-
cently conducted on the toxicity of CYN (Guzmán-Guillén
et al., 2015; Sierosławska et al., 2015;), mechanisms of tox-
icity (Poniedziałek et al., 2014), biodegradation (Dziga et
al., 2016) and biological role and allelopathy (B-Béres et
al., 2015). These works have contributed valuable knowl-
edge on these aspects but at the same time have revealed
many gaps in understanding of the role(s) of CYN in
aquatic ecosystems and its impact on their functioning
(Sukenik et al., 2015). Future studies are needed also on
factors regulating biosynthesis of this toxin, its biodegra-
dation by bacterial communities and other potential pro-
ducers including benthic and terrestrial cyanobacteria.
7-deoxy-CYN and 7-epi-CYN are naturally occurring con-
geners of CYN (reviewed by de la Cruz et al., 2013). Dif-
ferent Aphanizomenon sp. strains obtained from German
lakes were confirmed as producers of 7-deoxy-CYN while
strains of Chr. ovalisporum and C. raciborskii are known
to produce also 7-epi-CYN (Rzymski and Poniedziałek,
2014; Cirés and Ballot, 2016). Recently two new analogs,
7-deoxy-desulfo-CYN and 7-deoxy-desulfo-12-acetyl-
CYN, were isolated from a Thai strain of C. raciborskii
(Wimmer et al., 2014). 

In the period of 2012-2016, important steps towards a
better understanding of the presence of the neurotoxin
BMAA in surface waters have been made. The presence of
BMAA in a diversity of cyanobacterial strains was first de-
scribed in 2005 (Cox et al., 2005), and subsequent studies
reported conflicting results (reviewed by Faassen, 2014).
Differences in analytical approaches were assumed to be
one of the main causes of these diverging results, and in
2012, two independent studies recommended suitable ana-
lytical methods for BMAA determination (Cohen 2012;
Faassen et al., 2012a). Although some analytical challenges
remain (Lage et al., 2015; Faassen et al., 2016), a more con-
sistent picture of the presence of BMAA in aquatic systems
appears when only the studies that used recommended an-
alytical approaches (Cohen, 2012; Duncan, 2012; Faassen
et al., 2012a) are considered (Faassen, 2014).

In Europe, BMAA has frequently been detected in
aquatic organisms sometimes intended for human con-
sumption, including fish, molluscs and other seafood, at
or below the low µg g–1 DW level (Faassen, 2014; Jiang
et al., 2014b; Réveillon et al., 2016b). Similar levels are
found in some phytoplankton samples or strains (Faassen
2014). While at first cyanobacteria were hypothesised to
be the source of BMAA in aquatic systems, BMAA has
now also been detected in diatoms (Jiang et al., 2014a;
Lage et al., 2015; Réveillon et al., 2015), and a diatom
strain has been shown to contain BMAA during different
growth phases (Réveillon et al., 2016a). Recently, a major
fraction of BMAA was found to be present in a soluble,
bound form in a diversity of samples (Faassen et al., 2016;

Rosén et al., 2016), where traditionally BMAA was con-
sidered to be present either as a free molecule or in a pro-
tein-associated form (Murch et al., 2004). Only if more
consensus is created on the presence of BMAA in aquatic
systems, and human exposure levels can be assessed with
confidence, will it be possible to determine whether
BMAA does indeed play a role in the globally-occurring
neurodegenerative diseases Alzheimer’s, Parkinsonism
and amyotrophic lateral sclerosis, as is currently hypoth-
esized (Bradley and Mash, 2009).

The traditional identification of cyanobacteria has
been based on light microscopy and this technique con-
tinues to dominate in most laboratories throughout Europe
as documented in the recent Handbook of Cyanobacterial
Monitoring and Cyanotoxin Analysis (Meriluoto et al.,
2017). However, the morphological species concept is
changing in the microbial world, and molecular tools are
impacting on this regarding cyanobacteria. The rapidly
growing body of information from molecular biological
studies (see the text about the second handbook later in
this section, Kurmayer et al., 2017) is also very useful in
distinguishing between potentially toxigenic and non-tox-
igenic cyanobacterial strains but which may have identical
morphological features. 

Advances are being made in cyanotoxin screening and
trace analysis. Commercial enzyme-linked immunoassays
(ELISAs) are being applied for the screening for some
cyanotoxins, as are protein phosphatase inhibition assays
for the detection of MCs and NODs. However, the need
for users to themselves verify the specificity of these
methods, taking into account false positives and responses
to cyanotoxin detoxification products, is emphasised. The
most rapid and dramatic (in terms of sensitivity) advances
have been made in instrumental analyses based on liquid
chromatography-tandem mass spectrometry (LC-
MS/MS). LC-MS/MS is extremely well suited for regu-
latory settings as it can target individual analytes and the
methods can be fully validated. In addition, LC-MS can
be used simultaneously for several classes of compounds.
Zervou et al. (2017) provide a good example of this multi-
toxin approach where 12MCs, NOD, CYN, ANTX-a, and
the marine algal toxins domoic acid and okadaic acid were
concentrated by a dual-cartridge solid-phase extraction
procedure and determined in a single LC-MS/MS run.
One obvious complication with LC-MS/MS analyses is
the need for reference materials which are currently not
commercially available for all cyanotoxins. 

What has become increasingly evident during the last
few years is that various bioassays are still needed in iden-
tifying new toxic agents produced by cyanobacteria. New
bioassays based on cell lines or invertebrates have almost
totally replaced the traditional mouse bioassay which was
relied upon in the 1980s when the knowledge about cyan-
otoxins and their effects on mammalian/human health was

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Toxic cyanobacteria in Europe - research progress through CYANOCOST 165

still developing. Such bioassays can possibly detect novel
bioactive, including potentially harmful, compounds.
However, the broader application of bioassays in the mon-
itoring of toxic cyanobacteria is still an open issue. The
ongoing discussion among scientists and regulators aims
to clarify important points such as causality between
bioassay responses and toxin concentrations, bioassay
specificity, action or regulatory limits, etc.

In the past two decades, molecular biology has pro-
vided a major contribution to understanding cyanotoxin
biosynthesis pathways (Kurmayer et al., 2017). The elu-
cidation of the pathways of MC and NOD biosynthesis
(Tillett et al., 2000; Moffitt and Neilan, 2004) was fol-
lowed by discovery of the pathways of CYN biosynthesis
(Shalev-Alon et al., 2002; Mihali et al., 2008), STX
biosynthesis (Kellmann et al., 2008) and ANTX-a biosyn-
thesis (Méjean et al., 2009). In general, cyanotoxin mol-
ecules are synthesized by non-ribosomal peptide synthesis
(NRPS) partly involving polyketide synthases (PKS) and
tailoring enzymes following a thiotemplate mechanism
which is widely distributed among bacteria and fungi (Fis-
chbach and Walsh, 2006). Synthesis pathways have been
explored by characterizing specific enzymatic steps in
vitro (Hicks et al., 2006), by experimental inactivation of
core and tailoring enzymatic steps in vivo (Christiansen
et al., 2003), and by crystallization of heterologously-ex-
pressed enzymes (Mazmouz et al., 2011). 

In parallel with gene cluster elucidation: i) various
gene loci have been tested for their reliability to indicate
the presence of a specific cyanotoxin biosynthesis path-
way (Jungblut and Neilan, 2006); and ii) phylogenetic
analysis of various gene loci has been used to investigate
the inheritance of cyanotoxin biosynthesis pathways
(Rantala et al., 2004). This research has revealed specific
gene loci indicative of MC/NOD biosynthesis (Rantala et
al., 2004), ANTX-a biosynthesis (Rantala-Ylinen et al.,
2011), and CYN biosynthesis (Mihali et al., 2008), and
preliminary candidate gene loci indicative of STX biosyn-
thesis (Kellmann et al., 2008). Today it is understood that
MC and STX biosynthesis pathways are both ancient and
evolved about 2 billion years ago corresponding to the
evolution of the heterocytous cyanobacteria as an adap-
tation to the oxygen-containing atmosphere (Rantala et
al., 2004; Murray et al., 2011). Consequently, due to an
ancestral common origin for these cyanotoxins
(MC/NOD, STX), their present-day production is widely
distributed among extant cyanobacteria and is likely to be
more so than is currently recognised. This type of phylo-
genetic analysis has further suggested that, in comparison
with horizontal gene transfer events, the vertical inheri-
tance and ongoing cyanotoxin gene cluster loss processes
are probably important in explaining the rather patchy dis-
tribution among cyanobacterial taxa. Correspondingly, for
CYN, phylogenetic congruence with cyanobacterial evo-

lution and CYN biosynthesis has been reported (Jiang et
al., 2012). For ANTX-a biosynthesis, recent phylogenetic
analysis has revealed significant homology within the
ANTX-a biosynthesis pathway across cyanobacterial taxa
(Brown et al., 2016).

Current understanding of the molecular biology of
cyanotoxin biosynthesis has been recently compiled into
a molecular tools handbook which contains protocols de-
scribing methods to detect and to quantify toxigenic
cyanobacteria in aquatic and terrestrial environments and
in food supplements (Kurmayer et al., 2017). This com-
pilation contains protocols on sampling and cyanobacte-
rial isolation and identification, and standard protocols on
DNA (mRNA) extraction and PCR amplification of gene
loci indicative of cyanotoxin biosynthesis. In addition to
toxigenic cyanobacterial detection and quantification pro-
tocols, methods to analyze the regulation of cyanotoxin
synthesis are also included. For quantitative analysis, the
techniques used in qPCR have been collected. The com-
pilation also includes traditional microarray and denatur-
ing gradient gel electrophoresis protocols to characterize
genetic community/population structure based on cyan-
otoxin synthesis gene fragments. High-throughput se-
quencing protocols have been included to aid the
investigation of cyanobacterial community composition.
Finally, the application of molecular tools in the scientific
literature has been collected and reviewed (Kurmayer et
al., 2017). 

In principal, molecular tools only can reveal the po-
tential for cyanotoxin biosynthesis and cannot provide
information about actual toxin concentrations or con-
tents. In general, the scientific experience of the pre-
dictability of cyanotoxin occurrence qualitatively and
quantitatively in environmental samples based upon the
determination of cyanotoxin synthesis genes is still in-
sufficient. Particularly for MC/NOD biosynthesis, efforts
have been made to correlate cyanotoxin biosynthesis
gene abundance with MC/NOD occurrence and concen-
trations (Koskenniemi et al., 2007; Okello et al., 2010;
Ostermaier and Kurmayer, 2010). In some cases, these
efforts did not show the expected correlations and further
molecular biological analyses will be needed to under-
stand the relevant influences, for example mobile ele-
ments, leading to inactivation (Chen et al., 2016). For
CYN, STX and ANTX-a occurrence, the predictability
from potential indicative biosynthesis genes is even less
explored and considerable further effort will be needed
(Savela et al., 2015). 

The occurrence of false positives in laboratory and en-
vironmental samples has been reported repeatedly and
needs clarification. In particular, for CYN, STX and
ANTX-a the identification of conserved gene (fragments)
parts of the core synthesis pathways is still in progress,
and needs to identify indicative gene loci to be either used

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J. Meriluoto et al.166

singly or in combination. On the other hand, if genes in-
dicative of the above mentioned cyanotoxin synthesis
genes are absent, the occurrence of the corresponding
cyanotoxins might be excluded. This approach has been
partly successful but again depends on the reliability of
genetic indication. Thus, the idea that molecular tools can
guide the application of more sophisticated chemical-an-
alytical techniques through the detection of cyanotoxin-
indicator genes is still under development. 

FATE, IMPACT AND HEALTH EFFECTS

Recent reviews on human and animal health aspects in-
clude: a health review chapter (Codd et al., 2017), an epi-
demiological assessment of cancers in Serbia with reference
to cyanobacterial blooms (Svirčev et al., 2014a), a review
of production, toxinology and toxicology of the ANTX-a
and STX neurotoxins (Testai et al., 2016) and a review on
epidemiological investigations on health issues related to
cyanotoxins (Svirčev et al., 2017a). Recently reported ani-
mal intoxications involving cyanobacterial blooms and
cyanotoxins have included dogs in the Netherlands, with
hANTX-a (Faassen et al., 2012b) and MC-LR (Lürling and
Faassen, 2013) as likely proximal causes. Fish-kills associ-
ated with cyanobacterial blooms have continued throughout
CYANOCOST, e.g. in Greece and Russia (Kormas KA, Pa-
padimitriou T, Chernova E: personal communications). An
ongoing likelihood for the role of additional (or alternative)
uncharacterised or novel cyanotoxins of health significance
was provided in a further, major fish-kill in Serbia in which
candidate cyanotoxins (CYN, STXs, MCs) were not de-
tected although the C. raciborskii bloom material was lethal
by bioassay using Artemia salina (Svirčev et al., 2016). It
is evident that the range of health hazards presented by
cyanobacteria and their metabolites is only partially under-
stood. For example, in vitro bioassays have revealed a stim-
ulation of mammalian estrogenic activity by cyanobacterial
exudates (Sychrova et al., 2012) and a stimulation of pro-
inflammatory responses by MC-LR; the latter effect not
being attributable to the long-known inhibition of protein
phosphatases by MCs (Adamovsky et al., 2015). Recogni-
tion of the roles of exposure media and routes via which
cyanotoxins may present risks to human health has also been
increased: one of the first risk assessments of exposure to
cyanotoxins from terrestrial sources concerned potential in-
halation exposure to airborne MCs from cyanobacterial
desert crusts (Metcalf et al., 2012). 

The following paragraphs summarise some examples
and case studies which have been well documented in Ser-
bia, which is greatly affected by toxic cyanobacterial
blooms (Simeunović et al., 2010; Svirčev et al., 2013;
Svirčev et al., 2014b). On 14 December 2013, a
bloom of Planktothrix rubescens (de Candolle ex
Gomont) K. Anagnostidis & J. Komárek was observed in

the Vrutci reservoir which is the drinking water source for
the city of Užice, Serbia, where 70,000 inhabitants were
potentially exposed to cyanotoxins. The first comprehen-
sive analysis showed the presence of P. rubescens in the
treated water at about 10,000 cells per litre, and approxi-
mately 1000 cells per litre in a sample from the piped-
water network (Institute of Public Health Serbia, 2014).
Therefore, from 26 December 2013, the use of tap water
for drinking and cooking purposes was prohibited by the
Sanitary Inspectorate of the Republic of Serbia. This ini-
tially provoked panic among the citizens. However, the
situation was manageable and satisfactorily resolved (at
least in the short-term). Further analysis showed that the
number of P. rubescens cells reached as high as 107,900
cells per millilitre in the reservoir (Agency for Environ-
mental Protection, 2013). The MC-LR concentration in a
piped-water network sample was below the WHO provi-
sional guideline value (1 µg L–1) (Institute of Public
Health Serbia, 2014). Later research (Drobac, 2015;
Svirčev et al., 2017b) confirmed the toxicity of the
cyanobacterial biomass by A. salina bioassay. MCs were
detected in the lake water by LC-MS/MS (Drobac, 2015;
Svirčev et al., 2017b). MC was also detected in the treated
tap water and in fish from the reservoir. Additional inves-
tigations in the form of questionnaires, epidemiological
studies and analysis of cyanotoxins in frozen fish sug-
gested that cyanobacterial blooms might have occurred in
the waterbody considerably earlier than the observed
bloom in December 2013. Furthermore, questionnaire and
epidemiological studies indicated the occurrence of gas-
trointestinal and skin diseases, possible as a result of ex-
posure to cyanobacterial blooms from the reservoir Vrutci
(Đenić, 2014; Drobac, 2015; Svirčev et al., 2017b).While
the Vrutci reservoir continued to bloom, a radical but tem-
porary ‘Užice solution’ was implemented in order to pro-
tect human health, and after 7 February 2014 the
abstraction of water from the blooming reservoir was
switched to an alternative source, Sušičko vrelo. 

The Užice case showed the importance of giving ad-
equate information and advice to the general public. In
order to prevent panic and to support the affected popu-
lation, additional measures should be employed: inform-
ative flyers distributed in regions with the problem; daily
or weekly updates on the situation; a hotline for the pub-
lic for further questions and suggestions for dealing with
the problem. Also, the value of displaying visible, clear
and understandable warnings in areas near blooming wa-
ters to inform the public of the problem was emphasised,
with examples of their successful use in several other
countries. The importance of contingency planning, in-
cluding the prior preparation of warning materials in an-
ticipation of cyanobacterial bloom events was also
stressed.

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PREVENTION AND CONTROL MEASURES

Prevention and control measures which could be used
to combat toxic cyanobacteria and cyanotoxins have been
addressed by some recent European research. The Special
Issue edited by Visser et al. (2016b) “Cyanobacterial
blooms. Ecology, prevention, mitigation and control” in
the journal Aquatic Ecology compiles a variety of meth-
ods that can be used by water managers to control
cyanobacteria in lakes and reservoirs. It provides a state
of the art overview on prevention, control and mitigation
methods for cyanobacterial blooms. 

The basis of lake management aiming to reduce
cyanobacterial blooms is a comprehensive system analy-
sis which assesses all point and non-point sources of nu-
trient loading in relation to lake characteristics including
morphology, nutrient concentrations and retention times.
This multiple approach helps to define the best method
to manage cyanobacteria as detailed by Stroom and Kar-
dinaal (2016). In addition, for an effective implementa-
tion of control measures in lakes, these should be
preferably developed in collaboration with stakeholders
and the citizens in a socio-ecological systems approach
(Van Dolah et al., 2016).

The most effective and sustainable way to prevent
cyanobacterial blooms is by a strong reduction of the in-
lake nutrient concentration. This comprises both the reduc-
tion of the nutrient load from the catchment (Hamilton et
al., 2016) and the inflows to the waterbody (Fastner et al.,
2016). If internal loading is substantial, hypolimnetic aer-
ation (Bormans et al., 2016), dredging or sediment capping
(Douglas et al., 2016) can reduce the release of phosphorus
from the sediment. Nevertheless, changes in chlorophyll
and abundance of cyanobacteria in lakes where phosphorus
in the inflow was reduced show that it may take years be-
fore the phytoplankton responds, depending largely on the
extent of the decrease in the nutrient load achieved (Fastner
et al., 2016). To overcome cyanobacterial problems in these
intervening years, or in cases where sufficient reduction of
nutrient loading is too costly or not feasible, control and
mitigation measures can be used. 

The effectiveness of control measures depends on lake
characteristics including trophic state, depth and retention
time, but also on the cyanobacterial species that bloom in
the lake. Various cyanobacterial groups have different key
functional traits which make them sensitive to certain con-
trol measures while being insensitive to others (Mantzouki
et al., 2016). The requirements and limits of the different
methods are summarized by Ibelings et al. (2016) and will
be briefly listed here. Artificial mixing can be a good tech-
nique to reduce cyanobacterial blooms in relatively deep
systems (>15 m) if the aeration system is well distributed
in the lake and strong enough to keep cyanobacterial
colonies entrained in the turbulent flow (Visser et al.,

2016a). Cases in which artificial mixing was applied in a
way that did not meet these criteria were unsuccessful in
reducing cyanobacterial biomass. Furthermore, the tech-
nique works best for buoyant colony-forming cyanobacte-
ria like Microcystis. If mixing is intermittently applied, the
technique can also be successful for filamentous cyanobac-
teria including Planktothrix and Cylindrospermopsis (An-
tenucci et al., 2005). Decreasing the retention time in a lake
can reduce the cyanobacterial biomass if the flushing rate
is higher than the growth rate of the cyanobacteria and can
thus apply for all cyanobacterial species as documented e.g.
for Microcystis (Bowling and Baker, 1996; Ibelings et al.,
1998; Verspagen et al., 2006) and Dolichospermum (Web-
ster et al., 2000; Mitrovic et al., 2011). Biomanipulation
can be successful in lakes where the external and internal
loading have been reduced as it can promote the develop-
ment of submerged macrophytes and help to move from a
turbid state to a clear water state (Noordhuis et al., 2016;
Triest et al., 2016). This holds true for water-level manage-
ment (Bakker and Hilt, 2016). Cyanocides can also be used
to reduce the cyanobacterial biomass regardless of the
cyanobacterial species. Matthijs et al. (2016) discussed the
application of conventional and new cyanocides in drinking
water reservoirs and bathing waters. Especially, hydrogen
peroxide appears to be a promising substance for bloom
mitigation since cyanobacteria typically show a higher sen-
sitivity to hydrogen peroxide than other groups of aquatic
biota. This control agent does not leave any harmful resid-
uals due to its breakdown into oxygen and water, and cyan-
otoxins degrade rapidly in the treated lakes. There are
several further measures that can help in the control of
cyanobacteria as discussed by Stroom and Kardinaal
(2016). However, several of the commercially offered end-
of-pipe techniques should be considered with caution as
controlled tests with these techniques were often not very
promising (Lürling et al., 2016). Mitigation techniques in-
cluding harvesting of scums, shifting the intake-depth in
drinking-water reservoirs, deployment of bubble screens or
the selective withdrawal of hypolimnetic waters may be
used when water quality improvement is urgent for either
drinking or recreational use of water. A ban on swimming
or bathing may further reduce the risks associated with
cyanobacterial bloom exposure at recreational sites.

Future developments in lake management should aim
for clearer guidance in the selection procedure from the
suite of available methods, optimization and sustainability
of methods and further research into the efficacy and side-
effects of the methods. Furthermore, an overview of in-
vestments, economic depreciation over time and annual
running and maintenance costs will be important elements
in the most (cost) effective selection of measures. Method
selection should also pay attention to the carbon footprint
of the different methods (e.g., energy use).

There are several conventional and advanced options

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available for the removal/detoxification of cyanotoxins
during drinking water treatment (Hiskia et al., 2017).
Physical treatment methods can remove cyanotoxins fully
or partly from contaminated water. As their aim is the sep-
aration of toxins as intact molecules, further processing for
the management of the resulting waste is also required.
Among these methods, adsorption by activated carbon, ei-
ther as granular activated carbon (GAC) or powdered ac-
tivated carbon (PAC), has been reported to be effective for
the removal of several dissolved cyanotoxins. The amount
and nature of natural organic matter (NOM) in water
greatly influences the adsorption and capacity of activated
carbon for cyanotoxins. NOM is typically present at higher
concentrations than cyanotoxins and competes for active
sites on the sorbent material. Activated carbon technolo-
gies may also be combined with biological or membrane
technologies to create integrated methods. Reverse osmo-
sis and nano-filtration membranes have been tested for MC
removal. Although efficient, the above technologies should
be evaluated in terms of the operational costs and engi-
neering considerations (Antoniou et al., 2014).

Chemical oxidation processes are a promising addi-
tional treatment option due to the potential for complete
destruction of cyanotoxins, transformation to less toxic
by-products and even complete mineralization (Sharma
et al., 2012). On the other hand, oxidants have been found
to lyse cyanobacteria, which may release toxins. It is
therefore recommended that coagulation or other separa-
tion procedures be applied to remove whole cells and to
minimise cyanobacterial cell disruption before oxidation.

Although studies have been carried out mainly with
MCs, all conventional oxidation processes (ozonation,
chlorination, oxidation with permanganate) can degrade
cyanotoxins in water. Among them, ozone seems to be the
most effective for MC destruction, reacting preferentially
with their double bonds. The ability of ozone to oxidize
the Adda moiety, which is linked to the toxic properties
of MCs, makes treatment with ozone a very promising
water detoxification technology for these contaminants.
Ozone has also been found to be effective for the destruc-
tion of ANTX-a and CYN, although it is less effective
with STX (Newcombe, 2002). 

Chlorination is also an option for the degradation of
MCs and CYN in water, but its efficiency depends on op-
erational parameters, including the nature of the chlorine
compounds used. Chlorine-based weaker oxidants (and
disinfectants) including chlorine dioxide and chloramines
have been found to be ineffective for cyanotoxin degra-
dation. Contrary to the above, ANTX-a has been shown
to be quite stable upon chlorination (Sklenar et al., 2016).

Permanganate reacts differently with each group of
cyanotoxins. It has high reactivity with most MC variants
examined and inactivates Microcystis aeruginosa cells
without significant release of MCs after treatment. The

low release of cyanotoxins during treatment in combina-
tion with its effectiveness to inactivate M. aeruginosa and
oxidize MCs makes permanganate a potential oxidant for
their elimination in drinking water treatment (Sharma et
al., 2012). Permanganate is also very reactive with
ANTX-a, with pH playing an important role in the process
(Ho et al., 2009), while it is not effective with CYN (Ro-
driguez et al., 2007).

The reactivity of MCs towards different conventional
oxidants is strongly affected by water quality parameters
including pH, dissolved organic carbon (DOC) and oxidant
dose. Although there is a general trend for cyanotoxins ox-
idation (ozone > permanganate > chlorine >>> chlorine-
based oxidants), the selection of the appropriate oxidant
should be assessed for each particular source of water. 

Advanced Oxidation Processes (AOPs) are generally
more effective in degrading cyanotoxins than conven-
tional oxidation processes since they generate hydroxyl
radicals, which react rapidly with all of the groups of
cyanotoxins investigated with high second order reaction
rate constants. Although the detoxification of water and
complete mineralization of cyanotoxins can also be
achieved by AOPs, the roles of water quality parameters
(e.g., DOC) have to be taken into account. The presence
of inorganic and organic water constituents often inhibits
the degradation of target pollutants through radical scav-
enging mechanisms resulting in lower degradation rates.
Overall, while there are promising results in removing
cyanotoxins using AOPs under laboratory conditions,
scale-up studies are needed before these methods are con-
sidered as economically feasible and practical sustainable
alternatives in water treatment facilities (He et al., 2012;
Fotiou et al., 2016).

In conclusion, effective water treatment strongly de-
pends on both water quality parameters and treatment op-
tions. It is recommended that water utilities examine all
available alternatives and develop a clear set of goals ac-
cording to their needs and the expected investment and
operational costs before applying measures for cyanotoxin
treatment at their facilities.

END-USER AND OUTREACH TOOLS,
MATERIALS AND PRODUCTS

While CYANOCOST has not been the first network fo-
cusing on toxic cyanobacteria and cyanotoxins, it is deemed
to be the network that has actively involved the highest
number of countries as well as reaching the most researchers
and other stakeholders. This part of the review concentrates
solely on the outreach tools of the CYANOCOST Action as
the different approaches taken by the Action can serve as an
excellent model for similar programmes.

When the CYANOCOST Action was planned, it was
understood that one of the main objectives of the proposal

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should be the dissemination of the results of the Action
throughout the EU and neighbouring countries. The pro-
ponents perceived that the cyanotoxin problem in Europe
was widespread but that different countries and regions
had very different management and control mechanisms
and policies in place, ranging from extremely low levels
of control, to very sophisticated intensive management
tools. Awareness of the water and health authorities of the
problem varied from country to country. 

The CYANOCOST Action turned out to be a useful ve-
hicle to extend and increase recognition and awareness of
the occurrence of cyanobacteria and cyanotoxins, and to
make key management tools more widely available to
counteract the adverse effects of cyanobacterial mass
growths and cyanotoxins. Dissemination of the scientific
and practical results of the CYANOCOST Action needed
to target a broad range of audiences and end-users. These
included: i) researchers, especially young ones, from di-
verse disciplines: analytical chemists, (molecular) biolo-
gists, ecologists, toxicologists, water engineers; ii) the
drinking water industry, especially managers involved in
water quality control; iii) recreational water facility man-
agers; iv) aquaculture and agriculture enterprises and man-
agers; v) environmental laboratories, both public and
private; vi) equipment and material designers and manu-
facturers; vii) public health and clinical professionals, water
district authorities and organizations; viii) environmental
and public health policy makers at national and European
level; ix) non-governmental organizations active in envi-
ronmental public awareness;(x) regional and national water
sports organizations; and xi) the general public.

What are the relevant approaches to be considered for
a successful dissemination in a scientific project? As ex-
emplified above, CYANOCOST needed to engage a large
number of end-users and stakeholders. The value of dif-
ferent dissemination approaches using databases, web-
pages, social media, flyers, specialized books, special
issues in scientific journals, training schools and short-
term scientific missions (STSMs) were considered within
the Action, and these approaches were developed, based
on responses from the Action participants and stakehold-
ers. The approaches taken by the Action are described in
the following text as examples that can be generalised and
used in similar projects. 

A Europe-wide rolling database (https://sites.google.
com/site/cyanocost/) which was an extension of the 2005
UNESCO CYANONET database (Codd et al., 2005) was
developed within the Action. The CYANOCOST database
contains useful contacts of researchers, organizations, com-
panies involved in this field, with extended profiles, expert-
ise, publications, projects, collaborations and contact
details. Links to national risk management policies in use
in Europe and in neighbouring states, including guidelines
and legislation, are included. The database has been origi-

nally designed for use by CYANOCOST participants only
but it is expected to be made freely available for the public.
In addition to this Europe-wide database, a freely-accessi-
ble local database, the Serbian Cyanobacterial Database
(https://cloud.pmf.uns.ac.rs/index.php/s/v6tErVCV-
cAuaXQN), was developed. It is expected that these data-
bases/repositories will be used as sources of information
beyond the lifetime of the Action. The databases contain
material from both pre-CYANOCOST publications and pa-
pers arising from the CYANOCOST Action. Based on the
CYANOCOST experience, it is recommended that the fol-
lowing matters receive attention during the lifetime of any
action or project establishing public databases: i) intellec-
tual property rights and terms of use; ii) accessibility of in-
formation and design of the database; iii) mechanisms to
ensure correctness of data; iv) continued updating of the
database; and v) maintenance of the database.

To address the needs of various professional groups,
including water managers, the drinking water industry, the
environmental and public health sectors, and academia,
CYANOCOST outcomes were communicated in the form
of the three handbooks mentioned in this paper and two
special issues in Aquatic Ecology and Advances in
Oceanography and Limnology, i.e. the present themed
issue). The handbooks and special issues have been in-
tended to serve as coherent and up-to-date compilations of
theoretical and practical knowledge relating to toxic
cyanobacteria and the problems they cause. As today the
scientific knowledge is scattered over a multitude of sci-
entific individual papers, the value of single-source col-
lections of information is probably appreciated by
end-users. Furthermore, a Decision Support Tool based on
the outcomes of the EU-FP6 project PEPCY was translated
from German into English and has been made available
on-line (https://toxische-cyanobakterien.de/en/). In order
to promote networking between various professionals, the
Action’s Management Committee meetings have had at-
tendees from the local water and public health authorities,
water companies, and the academic community. Besides
ordinary Management Committee members, representa-
tives from different institutions in e.g. Greece, Bulgaria,
Hungary, Spain, the Netherlands, etc., participated in the
meetings. Representatives from other key Europe-wide
projects such as the NETLAKE COST Action or the SO-
LUTIONS EU project attended some of the meetings, too.

As a reaction to the water crisis in Užice, Serbia, an in-
ternational conference ‘Water challenges of the future’ was
organized in Belgrade on 24th March 2014. This scientific
and educational meeting was organized by the Faculty of
Sciences of the University of Novi Sad. Eminent experts
presented information on cyanobacterial blooms and pro-
duction of toxic metabolites with the aim of raising pre-
paredness, knowledge and engagement among authorities
and citizens. The objective was education of target groups

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including the authorities and citizens of Užice, representa-
tives from water-supply facilities, as well as users of recre-
ational waters, and the provision of information on
cyanotoxin problems to the institutes of public health, med-
ical and veterinary practitioners, governmental and regional
bodies, students of ecology and the general public. Further-
more, the merits of introducing guidelines and/or legislation
regarding cyanotoxins in Serbia (for drinking water, recre-
ational usage and edible fish) were discussed at the meeting
with an emphasis on their introduction into national legis-
lation on hazardous substances. The conference provided
an example of how an international network can give sup-
port to local academics, authorities and other stakeholders
in combatting an environmental problem.

Early-stage researchers (ESRs) and other younger
professionals were seen as an important group of stake-
holders. To increase awareness of cyanobacterial blooms
and cyanotoxin problems among young scientists and to
promote network-building, summer schools were organ-
ized. These included the Advanced Course on Cyanobac-
teria and Cyanotoxins, Madrid, June-July 2015, and the
12th Summer Course on Environmental Toxicology, Brno,
June 2015. Both summer schools had wide participation
from many countries. Thematic expert workshops were
also organized within the Action, including the training
school on the use of hydrogen peroxide against
cyanobacterial blooms (Amsterdam, September 2014)
and the analytical workshop on BMAA (Wageningen,
May 2015). Furthermore, a total of 37 STSMs were fi-
nanced to promote mobility between different laborato-
ries in countries and these exchange periods were
especially targeted to ESRs.

The CYANOCOST webpage (http://www.cyanocost.c
om) served as a major forum with information about the
Action, the subject matter, and as a main communication
medium for end-users and others interested in the recogni-
tion and risk management of cyanobacterial blooms, cyan-
otoxins and their impacts. This webpage has received over
30,000 visitors that have visited over 116,000 webpages in
18 months, and the visitors have posted questions, news,
announcements, discussions etc. Social networks have also
been used for dissemination of the CYANOCOST Action.
In particular, the Twitter account (@Cyanocost) was quite
successful with over 500 followers and over 2500 ‘tweets’
from June 2013. A CYANOCOST Facebook page has also
had over 350 ‘likes’ (followers) and some posts reached to
over 1000 followers. 

Taken together, the dissemination efforts of the
CYANOCOST Action have allowed an ample distribution
of the information regarding cyanobacteria and cyanotox-
ins not only in COST member countries but also in other
countries dealing with cyanobacterial problems such as
the United States, Australia, etc. 

GAPS IN KNOWLEDGE AND ACTIONS
NECESSARY TO STRENGTHEN MANAGEMENT
CAPABILITIES

The problem of toxic cyanobacterial blooms is prima-
rily linked to non-sustainable consumption by the still-
growing human population, which brings enormous
pressures on global hydrological regimes, nutrient loads
and on the global climate. A truly holistic approach will
need to be taken at all levels to apply strategies leading to
real solutions (Paerl et al., 2016) and to develop particular
managerial approaches and risk mitigation measures
(Bullerjahn et al., 2016; Ibelings et al., 2016). This section
aims to summarize some of the open issues and knowledge
gaps which require attention in order to strengthen capa-
bilities for the management of toxic blooms in the future.

Horizontal and cross-cutting issues

With the widening of research on cyanobacteria and
their toxins, and the essential involvement of different dis-
ciplines, an increasing need is emerging for a proper har-
monization and definition of terminology. Terms
including ‘harmful blue-green algae’, ‘toxic’ or ‘toxi-
genic’ cyanobacteria, ‘cyanobacteria-l’ and/or ‘algal
harmful blooms’, and acronyms such as ‘cyanoHABs’ and
’CHABs’ are being used in different parts of the world, in
different contexts (e.g., marine vs freshwater) and both
within- and between different communities (e.g., scien-
tists vs stakeholders). For example, the validity of the
terms ‘toxic’ and ‘non-toxic’ as applied to cyanobacteria,
depends not only on the presence of cyanotoxins but also
on their concentrations and/or the target organisms con-
sidered (Codd and Metcalf, 2014). Another emerging
problem of terminology relates to current changes in the
nomenclature and classification of cyanobacteria (Sciuto
and Moro, 2015; Komárek, 2016). Current systematics
and nomenclature are undergoing rapid changes that can
be appreciated only by specialized scientists. However,
practitioners and water managers tend to benefit rather
from simplification based on mutual agreements among
scientists and stakeholders. This approach helps to assure
the effective exploitation of different information re-
sources and to streamline the development of manage-
ment options and policies.

The accessibility, reliability, use, and quality of the in-
formation are another complex problem related to the risk
management of cyanobacteria. For example, regarding
spatial information, recent meta-analysis (Merel et al.,
2013a) identified a disproportionality between well-cov-
ered regions including the USA, Canada, Europe and Aus-
tralia, versus other (highly vulnerable) areas including
much of South America, Asia or Africa (Codd et al., 2005,
Merel et al., 2013a). However, a recent survey has col-

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lated more information on activities in Africa (Ndlela et
al., 2016). Further surveys in these continents are needed
for truly global mapping of toxic cyanobacteria risks.
Even existing information may not be fully accessible
(Merel et al., 2013b). For example, blooms may eventu-
ally be monitored and cyanotoxin analyses performed, but
the information may be only locally available and not re-
ported to any recognized national or international data-
base(s). Thus, the occurrence and potential risks of toxic
blooms can be considerably underestimated, and future
efforts should aim to implement ‘open environmental
data’ principles (e.g., via the GEOSS system;
https://www.earthobservations.org), and to strengthen the
role of the public (i.e., via ‘citizen science’) in the field
of toxic cyanobacterial blooms. On the contrary, there is
a major lag between the speed of newly generated data on
cyanobacteria (related to biotechnological advances, next
generation sequencing or other ‘omics’; Pearson et al.,
2016), the actual ‘quality’ of such data (ageing), and very
slow progress in the development of bioinformatics self-
learning tools that would make use of these ‘big data’. Fi-
nally, the current ‘publish or perish’ culture in the science
research community also negatively affects the field of
toxic cyanobacteria. Both science and the practical imple-
mentation of research results for risk management pur-
poses would greatly benefit from improvements that could
be achieved by applying more thorough and critical peer-
review during the publication of research on toxic
cyanobacteria.

Surveys 

Surveys of cyanobacterial hazards often combine several
methods including: i) taxonomy - microscopy determina-
tions of phytoplankton; and/or ii) analyses of cyanotoxins;
and/or iii) molecular biology investigations; and/or iv) ob-
servations of poisonings or other direct field effects.

The information obtained from field surveys may be
used not only for immediate managerial actions but is im-
portant also for development of models and bloom dy-
namics predictions, which still remain a major challenge
(Humbert and Fastner, 2017). Because of the variability
both between and within individual waterbodies, effective
predictions are currently possible only a few days in ad-
vance, and useful monitoring schemes for risk manage-
ment require adaptation to local conditions, case-by-case
definitions of locations or sampling and analytical details.

However, as demonstrated for example by the EMLS
initiative, jointly organized by COST Actions
CYANOCOST and NETLAKE, improvements in future
monitoring are possible by successful combinations of
harmonized methods along with continuous and real-time
sampling and standardized analysis methods (Humbert
and Törökné, 2017). Recently, numerous multiparameter
tools have been developed and integrated into au-

tonomous buoys or drones that may increase our future
understanding of detailed spatial and temporal cyanobac-
terial bloom dynamics. Future improvements in bloom
monitoring should also consider integration of aerial or
space-observations (Hunter et al., 2017) and investigation
of less explored factors recently suggested as drivers of
toxic blooms (Carvalho et al., 2011).

Future surveys of toxigenic cyanobacteria in Europe
should assess not only traditional cyanotoxins-producers
but investigate also alien or invasive species as discussed
in previous sections. In particular, distribution and poten-
tial toxigenicity of C. bergii, C. ovalisporum or S. apha-
nizomenoides should not be overlooked. Future surveys
should also cover picocyanobacteria that often remain
overlooked due to their very small size but they have been
suggested as potential cyanotoxin-producers by numerous
studies (Jasser et al., 2017). Also benthic cyanobacteria
that have previously been associated with animal poison-
ings still remain to be fully explored (Quiblier et al.,
2013), including investigations of newly observed cou-
plings in ecology of benthic and pelagic communities
(Zhang et al., 2015).

Considering the assessment of individual toxins, mod-
ern analytical equipment can easily comply with the most
demanding monitoring needs, and robust multitarget meth-
ods for simultaneous quantification of multiple compounds
are being developed for future implementation. As well,
non-target approaches could provide more insights into pro-
filing of cyanotoxins and other metabolites in the future.
However, there is a strong need to develop regulatory
guidelines for cyanotoxins which would give a higher pri-
ority to their monitoring and assessment. Another important
issue for the future is the current lack of reference materials
that are urgently needed for validation and improvements
of standardized surveys. As also discussed in previous sec-
tions, there are disproportionalities in our knowledge of
MCs versus other cyanotoxins. In particular, the occurrence
of STX across Europe is poorly understood. Future surveys
should provide insights into STX occurrence and risks
specifically focusing e.g. on the association of STX with
Cylindrospermopsis sp., which has been shown elsewhere
but not investigated in Europe. With respect to CYN, the
main gaps include our understanding of its role in aquatic
ecosystems, and studies on factors affecting CYN biosyn-
thesis and biodegradation are needed. Also the risks of the
neurotoxic amino acid BMAA and its relevance for
cyanobacterial blooms will require thorough attention and
open discussion among scientists.

Despite the strengths of molecular biology tools, they
are still mainly confined to the field of research, and sev-
eral issues need to be addressed before they can be widely
applied to environmental monitoring. It is accepted that
these tools can be developed to provide high-throughput
methods that can be used for early-warning purposes dur-

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J. Meriluoto et al.172

ing environmental surveillance. However, due to their
high sensitivity, genetic methods in general and PCR as-
says in particular are prone to errors, i.e. the production
of false positive results. For example, in laboratories
working routinely on the detection of pathogens by ge-
netic methods, a full catalogue of quality assurance and
quality control criteria needs to be met in order to guar-
antee reliable results. For cyanotoxin synthesis gene de-
tection, in particular, this quality assurance catalogue still
needs to be developed; hopefully based on the experience
collectively presented in the new handbook on molecular
tools (Kurmayer et al., 2017). Molecular tools can also be
expected to make a major contribution to the understand-
ing of the patchy occurrence of the genes for cyanotoxin
biosynthesis and of the production of the toxins them-
selves among cyanobacteria at different levels of taxo-
nomic resolution, e.g. within and between families, genera
and species (Kurmayer et al., 2015). This variability can
be observed for isolated strains and also with environmen-
tal samples on a global scale. For example, the biogeog-
raphy of cyanotoxin biosynthesis might be resolved at a
geographically higher resolution, using PCR-based tech-
niques with the aim to map toxigenic genotype occur-
rence. Putting toxigenic genotype distribution on a map
could be further combined with phylogenetic analysis to
reveal the phylogeographic dependence on cyanotoxin
synthesis in nature.

Effects

With respect to effects and impacts, new evidence has
been collected throughout the CYANOCOST Action on a
range of newly-recognised types of health hazards which
cyanobacteria may present. These include for example the
production of endocrine- or pro-inflammatory-modulators
(Sychrova et al., 2012; Adamovsky et al., 2015), and of
retinoic acid receptors which cause malformations during
fish embryogenesis (Kaya and Sano, 2017). Several
cyanobacterial exposure routes e.g. aerial exposure via in-
halation, though long-recognised (Codd et al., 1999) re-
quire further epidemiological research. In addition,
cyanobacterial mats have been discussed as the growth
matrix for pathogenic microorganisms (e.g., Legionella
sp., Vibrio cholerae or Clostridium sp.; Manganelli et al.,
2012). Future research should critically evaluate the rele-
vance and relative importance of microbial pathogens and
further hazards including metals and pesticides to those
posed by cyanobacteria. The true incidence of cyanotoxin-
related acute poisonings can hardly be fully quantified but
the case reports recently summarized clearly confirm that
cyanobacterial blooms present ongoing health risks to
both animals and humans (Wood, 2016). In addition to
traditionally studied liver and neurological symptoms fol-
lowing acute intoxications, new studies are needed to in-
vestigate hazards and modes of action (MoA) in other

tissues or systems (immune-, intestine-, respiratory- etc.).
In contrast to the relatively broad knowledge on the acute
effects of cyanotoxins, the chronic exposures and related
toxic risks and adverse health outcomes remain to be stud-
ied in the future (Ibelings et al., 2014).

Preventative and control measures

Despite the significant progress in our understanding of
bloom development and progress in their reduction or pre-
vention, including by in-lake technologies, future improve-
ments are still needed. As pointed out here and summarized
elsewhere (Ibelings et al., 2016), future lake management
would benefit from innovative and clear recommendations
on the selection of available methods, their optimization,
assessment of efficacy, evaluation of their sustainability and
the estimation of potential side effects. Furthermore, as-
sessment of the overall cost-effectiveness of individual ap-
proaches should be done in the future including evaluation
of investments, economic depreciation over time as well as
all necessary running and maintenance costs.

With regard to the removal of cyanotoxins from wa-
ters, current technologies can allow efficient transforma-
tions of investigated individual cyanotoxins by at least
one known process. However, no universal treatment has
been proven to simultaneously and completely remove all
cyanotoxins in mixtures, and combinations of different
methods (multibarrier concept) should be implemented in
advanced treatment plants (Merel et al., 2013b). Addi-
tional measures, such as cyanotoxin removal by home fil-
ters, should also be considered under specific situations.
Improvements are still needed regarding water treatment
under variable situations of changing pH or dissolved or-
ganic material also with the help of continuous monitoring
tools of cyanobacterial breakthroughs (Zamyadi et al.,
2014). Scale-up of promising AOPs will be needed to
evaluate the cost-effectiveness and sustainability of these
methods (He et al., 2012; Fotiou et al., 2016). Finally, the
current lack of harmonized international and national reg-
ulatory guidelines for cyanotoxins in drinking waters is
among the main obstacles for effective risk management
in the future, as demonstrated e.g. in the Užice case re-
cently (Svirčev et al., 2017b). The development of appro-
priate guidelines and their implementation in
most-affected European regions is urgently needed.

CONCLUSIONS

As shown by this review, scientific knowledge on toxic
cyanobacteria and cyanotoxins has advanced rapidly dur-
ing recent years. Progress has been achieved in e.g. phy-
cological and ecological studies, techniques for cyanotoxin
analysis, molecular biology related to toxin biosynthesis,
biochemical and medical studies related to cyanotoxin ac-

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Toxic cyanobacteria in Europe - research progress through CYANOCOST 173

tions, as well as various management and control aspects.
However, the recent cyanotoxin poisonings in Europe and
elsewhere illustrate clearly that water-users are still expe-
riencing serious cyanobacterial hazards. Expertise from
various professional groups and collaboration between the
stakeholders are necessary in order to help to protect the
safety of water consumers and users. Answers to some
open key questions identified in this review are still pend-
ing and will necessitate further research efforts.

ACKNOWLEDGMENTS

The authors would like to acknowledge the European
Cooperation in Science and Technology, COST Action ES
1105 ‘CYANOCOST - Cyanobacterial blooms and toxins
in water resources: Occurrence, impacts and management’
for adding value to this paper through networking and
knowledge sharing with European experts and researchers
in the field.

REFERENCES

Akcaalan R, Köker L, Oğuz A, Spoof L, Meriluoto J, Albay M,
2014. First report of cylindrospermopsin production by two
cyanobacteria (Dolichospermum mendotae and Chrysospo-
rum ovalisporum) in Lake Iznik, Turkey. Toxins 6:3173-3186.

Akcaalan R, Mazur-Marzec H, Zalewska A, Albay M, 2009. Phe-
notypic and toxicological characterization of toxic Nodularia
spumigena from a freshwater lake in Turkey. Harmful Algae
8:273-278.

Adamovsky O, Moosova Z, Pekarova M, Basu A, Babica P,
Sindlerova LS, Kubala L, Blaha L 2015. Immunomodulatory
potency of microcystin, an important water-polluting
cyanobacterial toxin. Environ. Sci. Technol. 49:12457-12464. 

Agency for Environmental Protection (Agencija za zaštitu životne
sredine) 2013. Accessed on: 21 January 2016. Available from:
h t t p : / / w w w . s e p a . g o v . r s / i n d e x . p h p ? m e n u
=504000000&id=20013&akcija=showArhiva 

Antenucci JP, Ghadouani A, Burford MA, Romero JR, 2005. The
long-term effect of artificial destratification on phytoplankton
species composition in a subtropical reservoir. Freshwater
Biol. 50:1081-1093.

Antoniou MG, Pelaez MA, Song W, O’Shea K, Ho L, Newcombe
G, Teixeira MR, de La Cruz AA, Triantis TM, Kaloudis T,
Hiskia A, Balasubramanian R, Pavagadhi S, Han C, Sharma
V, Dixon M, He X, Dionysiou DD, 2014. Practices that pre-
vent the formation of cyanobacterial blooms in water re-
sources and remove cyanotoxins during physical treatment of
drinking water, p. 173-195. In: S. Ahuja (ed.), Comprehensive
water quality and purification. Elsevier.

B-Béres V, Gábor V, Dobronoki D, Gonda S, Nagy SA, Bácsi I,
2015. Effects of cylindrospermopsin producing cyanobac-
terium and its crude extracts on a benthic green alga - com-
petition or allelopathy? Mar. Drugs 13:6703-6722.

Bakker ES, Hilt S, 2016. Impact of water level fluctuations on
cyanobacterial blooms: options for management. Aquat.
Ecol. 50:485-498. 

Ballot A, Fastner J, Lentz M, Wiedner C. 2010. First report of
anatoxin-a-producing cyanobacterium Aphanizomenon is-
satschenkoi in northeastern Germany. Toxicon 56:964-71.

Bernard C, Ballot A, Thomazeau S, Maloufi S, Furey A,
Mankiewicz-Boczek J, Pawlik-Skowronska B, Capelli C,
Salmaso N, 2017. Appendix 2. Cyanobacteria associated
with the production of cyanotoxins, p. 503-527. In: J. Mer-
iluoto, L. Spoof and G.A. Codd (eds.), Handbook on
cyanobacterial monitoring and cyanotoxin analysis. Wiley.

Bláhová L, Oravec M, Maršálek B, Šejnohová L, Šimek Z,
Bláha L, 2009. The first occurrence of the cyanobacterial al-
kaloid toxin cylindrospermopsin in the Czech Republic as
determined by immunochemical and LC/MS methods. Tox-
icon 53:519-524.

Bohunická M, Mareš J, Hrouzek P, Urajová P, Lukeš M, Šmarda
J, Komárek J, Gaysina LA, Sturnecký O, 2015. A combined
morphological, ultrastructural, molecular, and biochemical
study of the peculiar family Gomontiellaceae (Oscillatori-
ales) reveals a new cylindrospermopsin-producing clade of
cyanobacteria. J. Phycol. 51:1040-1054.

Bormans M, Maršálek B, Jančula D, 2016. Controlling internal
phosphorus loading in lakes by physical methods to reduce
cyanobacterial blooms - a review. Aquat. Ecol. 50:407-422. 

Bullerjahn GS, McKay RM, Davis TW, Baker DB, Boyer BL,
D’Anglada LV, Doucette GJ, Ho JC, Irwin EG, Kling EG,
Kudela RM, Kurmayer R, Michalak AM, Ortiz JD, Otten
TG, Paerl HW, Qin BQ, Sohngen BL, Stumpf RP, Visser
PM, Wilhelm SW, 2016. Global solutions to regional prob-
lems: Collecting global expertise to address the problem of
harmful cyanobacterial blooms. A Lake Erie case study.
Harmful Algae 54:223-238.

Bowling LC, Baker PD, 1996. Major cyanobacterial bloom in
the Barwon-Darling river, Australia, in 1991, and underlying
limnological conditions. Mar. Freshw. Res. 47:643-657.

Bradley WG, Mash DC, 2009. Beyond Guam: The cyanobacte-
ria/BMAA hypothesis of the cause of ALS and other neu-
rodegenerative diseases. Amyotroph. Lateral Scler. 10:7-20.

Brient L, Lengronne M, Bormans M, Fastner J, 2009. First oc-
currence of cylindrospermopsin in freshwater in France. En-
viron. Toxicol. 24:415-420.

Brown NM, Mueller RS, Shepardson JW, Landry ZC, Morré JT,
Maier CS, Hardy FJ, Dreher TW, 2016. Structural and func-
tional analysis of the finished genome of the recently iso-
lated toxic Anabaena sp. WA102. BMC Genomics 17:1-18.

Carvalho L, Miller CA, Scott EM, Codd GA, Davies PS, Tyler
AN, 2011. Cyanobacterial blooms: Statistical models de-
scribing risk factors for national-scale lake assessment and
lake management. Sci. Total. Environ. 409:5353-5358.

Chen Q, Christiansen G, Deng L, Kurmayer R, 2016. Emer-
gence of nontoxic mutants as revealed by single filament
analysis in bloom-forming cyanobacteria of the genus
Planktothrix. BMC Microbiol. 16:1-12.

Christiansen G, Fastner J, Erhard M, Börner T, Dittmann E,
2003. Microcystin biosynthesis in Planktothrix: genes, evo-
lution, and manipulation. J. Bacteriol. 185:564-572. 

Cirés S, Ballot A, 2016. A review of the phylogeny, ecology and
toxin production of bloom-forming Aphanizomenon spp.
and related species within the Nostocales (cyanobacteria).
Harmful Algae 54:21-43.

Cirés S, Wörmer L, Ballot A, Agha R, Wiedner C, Velázquez D,

No
n-

co
mm

er
cia

l u
se

 on
ly



J. Meriluoto et al.174

Casero MC, Queseda A, 2014. Phylogeography of cylin-
drospermopsin and paralytic shellfish toxin-producing Nos-
tocales cyanobacteria from Mediterranean Europe (Spain).
Appl. Environ. Microbiol. 80:1359-70.

Codd GA, Azevedo SMFO, Bagchi SN, Burch MD, Carmichael
WW, Harding WR, Kaya K, Utkilen HC, 2005.
CYANONET - A Global Network for Cyanobacterial bloom
and Toxin Risk Management. Initial Situation Assessment
and Recommendations. International Hydrobiological Pro-
gramme. Technical Documents in Hydrology No. 76. UN-
ESCO, Paris: 138 pp.

Codd GA, Bell SG, Kaya K, Ward CJ, Beattie KA, Metcalf JS,
1999. Cyanobacterial toxins, exposure routes and human
health. Eur. J. Phycol 34:405-415.

Codd GA, Metcalf JS, 2014. Toxic and non-toxic cyanobacteria:
evolving concepts. Perspect. Phycol. 1: 3-5.

Codd GA, Testai E, Funari E, Svirčev Z (2017). Cyanobacteria,
cyanotoxins and human health. In: A. Hiskia, D. Dionysiou,
M. Antoniou, T. Kaloudis, and T. Triantis (eds.), Water treat-
ment for purification from cyanobacteria and cyanotoxins.
Wiley (in press). 

Cohen SA, 2012. Analytical techniques for the detection of α-
amino-β- methylaminopropionic acid. Analyst 137:1991-2005.

Cox PA, Banack SA, Murch SJ, Rasmussen U, Tien G, Bidigare
RR, Metcalf JS, Morrison LF, Codd GA, Bergman B, 2005.
Diverse taxa of cyanobacteria produce β-N-methylamino-L-
alanine, a neurotoxic amino acid. P. Natl. Acad. Sci. USA
102: 5074-5078.

Devic E, Li D, Dauta A, Henriksen P, Codd GA, Marty J-L,
Fournier D, 2002. Detection of anatoxin-a(s) in environmen-
tal samples of cyanobacteria using a biosensor with engi-
neered acetylcholinesterases. Appl. Environ. Microbiol.
68:4102-4106. 

Đenić D, 2014. Cyanobacterial blooms in Vrutci reservoir (Cve-
tanje cijanobakterija u hidroakumulaciji Vrutci). Master’s
thesis, University of Novi Sad, Serbia.

Đorđević NB, Simić SB, Ćirić AR, 2015. First identification of
the cylindrospermopsin (CYN)-producing cyanobacterium
Cylindrospermopsis raciborskii (Wołoszyńska) Seenaya &
Subba Raju in Serbia. Fresen. Environ. Bull. 24:3736-3742.

Douglas GB, Hamilton DP, Robb MS, Pan G, Spears BM, Lür-
ling M, 2016. Guiding principles for the development and
application of solid phase phosphorus- adsorbents for fresh-
water ecosystems. Aquat. Ecol. 50:385-406. 

Drobac D, 2015. Human exposure to cyanotoxins and their
health effects (Putevi izloženosti čoveka cijanotoksinima i
njihov uticaj na zdravlje). Doctoral dissertation. University
of Novi Sad.

Duncan MW, 2012. Good mass spectrometry and its place in
good science. J. Mass. Spectrom. 47:795-809.

Dziga D, Kokociński M, Maksylewicz A, Czaja-Prokop U,
Barylski J, 2016. Cylindrospermopsin biodegradation abil-
ities of Aeromonas sp. isolated from Rusałka Lake. Toxins
(Basel) 8:55.

de la Cruz AA, Hiskia A, Kaloudis T, Chernoff N, Hill D, Anto-
niou MG, He X, Loftin K, O’Shea K, Zhao C, Pelaez M,
Han C, Lynch TJ, Dionysiou DD, 2013. A review on cylin-
drospermopsin: the global occurrence, detection, toxicity
and degradation of a potent cyanotoxin. Environ. Sci.
Process. Impacts 15:1979-2003. 

Edwards C, Beattie KA, Scrimgeour CM, Codd GA, 1992. Iden-
tification of anatoxin-a in benthic cyanobacteria (blue-green
algae) and in associated dog poisonings at Loch Insh, Scot-
land. Toxicon 30:1665-1175. 

Elersek T, Bláha L, Mazur�Marzec H, Schmidt W, Carmeli S,
2017. Other cyanobacterial bioactive substances, p. 179-195.
In: J. Meriluoto, L. Spoof and G.A. Codd (eds.), Handbook
on cyanobacterial monitoring and cyanotoxin analysis. Wiley.

Faassen EJ, 2014. Presence of the neurotoxin BMAA in aquatic
ecosystems: What do we really know? Toxins 6:1109-1138.

Faassen EJ, Antoniou MG, Beekman-Lukassen W, Blahova L,
Chernova E, Christophoridis C, Combes A, Edwards C,
Fastner J, Harmsen J, Hiskia A, Ilag LL, Kaloudis T, Lopicic
S, Lürling M, Mazur-Marzec H, Meriluoto J, Porojan C,
Viner-Mozzini Y, Zguna N, 2016. A collaborative evaluation
of LC-MS/MS based methods for BMAA analysis: Soluble
bound BMAA found to be an important fraction. Mar. Drugs
14:45.

Faassen EJ, Gillissen F, Lürling M, 2012a. A comparative study
on three analytical methods for the determination of the neu-
rotoxin BMAA in cyanobacteria. PLoS One 7:e36667.

Faassen EJ, Harkema L, Begeman L, Lürling M, 2012b. First
report of (homo)anatoxin-a and dog neurotoxicosis after in-
gestion of benthic cyanobacteria in The Netherlands. Toxi-
con 60:378-384. 

Fastner J, Abella S, Litt A, Morabito G, Vörös L, Pálffy K,
Straile D, Kümerlin R, Matthews D, Phillips MG, Chorus I,
2016. Combating cyanobacterial proliferation by avoiding
or treating inflows with high P load - experiences from eight
case studies. Aquat. Ecol. 50:367-384. 

Fastner J, Heinze R, Humpage AR, Mischke U, Eaglesham GK,
Chorus I, 2003. Cylindrospermopsin occurrence in two Ger-
man lakes and preliminary assessment of the toxicity and
toxin production of Cylindrospermopsis raciborskii
cyanobacteria isolates. Toxicon 42:313-321.

Fischbach MA, Walsh CT, 2006. Assembly-line enzymology for
polyketide and nonribosomal peptide antibiotics: Logic, ma-
chinery, and mechanisms. Chem. Rev. 106:3468-3496.

Fotiou T, Triantis TM, Kaloudis T, O’Shea KE, Dionysiou DD,
Hiskia A, 2016. Assessment of the roles of reactive oxygen
species in the UV and visible light photocatalytic degrada-
tion of cyanotoxins and water taste and odor compounds
using C-TiO2. Water Res. 90: 52-61.

Furey A, Crowley J, Shuilleabhain AN, Skulberg OM, James
KJ. 2003. The first identification of the rare cyanobacterial
toxin, homoanatoxin-a, in Ireland. Toxicon 41:297-303. 

Gkelis S, Zaoutsos N, 2014. Cyanotoxin occurrence and poten-
tially toxin producing cyanobacteria in freshwaters of
Greece: a multi-disciplinary approach. Toxicon 78:1-9.

Gugger M, Lenoir S, Berger C, Ledreux A, Druart J-C, Humbert
J-F, Guette C, Bernard C, 2005. First report in a river in
France of the benthic cyanobacterium Phormidium favosum
producing anatoxin-a associated with dog neurotoxicosis.
Toxicon 45:919-28.

Guzmán-Guillén R, Prieto AI, Moreno IM, Vasconcelos VM,
Moyano R, Blanco A, Cameán AM, 2015. Cyanobacterium
producing cylindrospermopsin causes histopathological
changes at environmentally relevant concentrations in sub-
chronically exposed tilapia (Oreochromis niloticus). Envi-
ron. Toxicol. 30:261-277.

No
n-

co
mm

er
cia

l u
se

 on
ly



Toxic cyanobacteria in Europe - research progress through CYANOCOST 175

Hamilton DP, Salmoso N, Pearl HW, 2016. Catchment control
strategies to mitigate harmful cyanobacterial blooms: nitro-
gen and phosphorus controls. Aquat. Ecol. 50:351-366.

He X, Pelaez M, Williams C, Westrick JA, O’Shea KE, Hiskia A,
Triantis T, Kaloudis T, de la Cruz AA, Dionysiou DD, 2012.
Efficient removal of microcystin-LR by UV-C/H2O2 in syn-
thetic and natural water samples. Water Res. 46:1501-1510.

Henriksen P, Carmichael WW, An J, Moestrup Ø, 1997. Detec-
tion of an anatoxin-a(s)-like anticholinesterase in natural
blooms and cultures of cyanobacteria/blue-green algae from
Danish lakes and in the stomach contents of poisoned birds.
Toxicon 35: 901-913.

Hicks LM, Moffitt MC, Beer LL, Moore BS, Kelleher NL, 2006.
Structural characterization of in vitro and in vivo intermedi-
ates on the loading module of microcystin synthetase. ACS
Chem. Biol. 1:93-102.

Hiskia A, Dionysiou D, Antoniou M, Kaloudis T, Triantis T
(eds.), 2017. Water Treatment for Purification from
Cyanobacteria and Cyanotoxins, Wiley (in press).

Ho L, Tanis-Plant P, Kayal N, Slyman N, Newcombe G, 2009.
Optimising water treatment practices for the removal of An-
abaena circinalis and its associated metabolites, geosmin
and saxitoxins. J. Water Health 7:544-56.

Humbert J-F, Fastner J, 2017. Ecology of cyanobacteria, p. 11-
18. In: J. Meriluoto, L. Spoof, and G.A. Codd (eds.), Hand-
book on Cyanobacterial Monitoring and Cyanotoxin
Analysis, Wiley.

Humbert J-F, Törökné A., 2017. New tools for the monitoring
of cyanobacteria in freshwater ecosystems, p. 84-88. In: J.
Meriluoto, L. Spoof, and G.A. Codd (eds.), Handbook on
Cyanobacterial Monitoring and Cyanotoxin Analysis, Wiley.

Hunter PD, Matthews MW, Kutser T, Tyler AN, 2017. Remote
sensing of cyanobacterial blooms in inland, coastal, and
ocean Waters, p. 89-99. In: J. Meriluoto, L. Spoof, and G.A.
Codd (eds.), Handbook on Cyanobacterial Monitoring and
Cyanotoxin Analysis, Wiley.

Ibelings BW, Admiraal W, Bijkerk R, Ietswaart T, Prins H, 1998.
Monitoring of algae in Dutch rivers: does it meet its goals?
J. Appl. Phycol. 2:171-181.

Ibelings BW, Backer LC, Kardinaal WEA, Chorus I, 2014. Cur-
rent approaches to cyanotoxin risk assessment and risk man-
agement around the globe. Harmful Algae 40:63-74.

Ibelings BW, Bormans M, Fastner J, Visser PM, 2016.
CYANOCOST special issue on cyanobacterial blooms - a
critical review of the management options for their preven-
tion, control and mitigation. Aquat. Ecol. 50:595-605.

Institute of Public Health Serbia “Dr Milan Jovanović Batut”
2014. Report on the request for access to information of public
importance No.8301/1, Belgrade. http://uimenaroda.rs/pred-
meti/li%C4%8Dni-stav/190-u%C5%BEice-vodosnabde-
vanje-slika-srbije.html (accessed 21 January 2016).

Jasser I, Callieri C, 2017. Picocyanobacteria: the smallest cell-
size cyanobacteria, p. 19-27. In: J. Meriluoto, L. Spoof, and
G.A. Codd (eds.), Handbook on Cyanobacterial Monitoring
and Cyanotoxin Analysis, Wiley.

Jiang YG, Xiao P, Yu GL, Sano T, Pan QQ, Li RH, 2012. Molec-
ular basis and phylogenetic implications of deoxycylindros-
permopsin biosynthesis in the cyanobacterium Raphidiopsis
curvata. Appl. Environ. Microbiol. 78:2256-2263.

Jiang L, Eriksson J, Lage S, Jonasson S, Shams S, Mehine M,

Ilag LL, Rasmussen U, 2014a. Diatoms: a novel source for
the neurotoxin BMAA in aquatic environments. PLoS ONE
9(1):e84578.

Jiang L, Kiselova N, Rosén J, Ilag LL, 2014b. Quantification of
neurotoxin BMAA (β-N-methylamino-L-alanine) in seafood
from Swedish markets. Sci. Rep. 4:6931.

Jungblut A, Neilan B, 2006. Molecular identification and evo-
lution of the cyclic peptide hepatotoxins, microcystin and
nodularin, synthetase genes in three orders of cyanobacteria.
Arch. Microbiol. 185:107-114.

Kaštovskỳ J, Hauer T, Mareš J, Krautová M, Bešta T, Komárek
J, Desortová B, Heteša J, Hindáková A, Houk V, Janeček E,
Kopp R, Marvan P, Pumann P, Skácelova O, Zapomělová
E, 2010. A review of the alien and expansive species of
freshwater cyanobacteria and algae in the Czech Republic.
Biol. Invasions 12:3599-3625. 

Kaya K, Sano T, 2017. Cyanobacterial retinoids, p. 173-178. In:
J. Meriluoto, L. Spoof, and G.A. Codd (eds.), Handbook on
Cyanobacterial Monitoring and Cyanotoxin Analysis, Wiley.

Kellmann R, Mihali TK, Jeon YJ, Pickford R, Pomati F, Neilan
BA, 2008. Biosynthetic intermediate analysis and functional
homology reveal a saxitoxin gene cluster in cyanobacteria.
Appl. Environ. Microbiol. 74:4044-4053.

Kiss T, Vehovszky A, Hiripi L, Kovacs A, Voros L, 2002. Mem-
brane effect of toxins isolated from a Cyanobacterium,
Cylindropermopsis raciborskii, on identified molluscan neu-
rons. Comp. Biochem. Physiol. C Toxicol. Pharmacol.
131C:167-176.

Kobos J, Błaszczyk A, Hohlfeld N, Toruńska-Sitarz A,
Krakowiak A, Hebel A, Sutryk K, Grabowska M,
Toporowska M, Kokociński M, Messyasz B, Rybak A,
Napiórkowska-Krzebietke A, Nawrocka L, Pełechata A,
Budzyńska A, Zagajewski P, Mazur-Marzec H, 2013.
Cyanobacteria and cyanotoxins in Polish freshwater bodies.
Oceanol. Hydrobiol. Stud. 42:358-378.

Kokociński M, Dziga D, Spoof L, Stefaniak K, Jurczak T,
Mankiewicz-Boczek J, Meriluoto J, 2009. First report of the
cyanobacterial toxin cylindrospermopsin in the shallow, eu-
trophic lakes of western Poland. Chemosphere. 74:669-675.

Kokociński M, Akçaalan R, Salmaso N, Stoyneva-Gärtner MP,
Sukenik A, 2017. Expansion of alien and invasive cyanobac-
teria, p. 28-39. In: J. Meriluoto, L. Spoof, and G.A. Codd
(eds.), Handbook on Cyanobacterial Monitoring and Cyan-
otoxin Analysis, Wiley.

Kokociński M, Mankiewicz-Boczek J, Jurczak T, Spoof L, Mer-
iluoto J, Rejmonczyk E, Hautala H, Vehniäinen M, Pawełczyk
J, Soininen J, 2013. Aphanizomenon gracile (Nostocales), a
cylindrospermopsin-producing cyanobacterium in Polish
lakes. Environ. Sci. Pollut. Res. Int. 20:5243-5264. 

Komárek J, 2016. A polyphasic approach for the taxonomy of
cyanobacteria: principles and applications. Eur. J. Phycol.
51:346-353. 

Koreivienė J, Kasperovičenė J, 2011. Alien cyanobacteria An-
abaena bergii var. limnetica Coutė et Preisig from Lithuania:
Some aspects of taxonomy, ecology and distribution. Lim-
nologica 41: 325-333.

Koskenniemi K, Lyra C, Rajaniemi-Wacklin P, Jokela J, Sivonen
K, 2007. Quantitative real-time PCR detection of toxic
Nodularia cyanobacteria in the Baltic Sea. Appl. Environ.
Microbiol. 73:2173-2179.

No
n-

co
mm

er
cia

l u
se

 on
ly



J. Meriluoto et al.176

Kurmayer R, Blom JF, Deng L, Pernthaler J, 2015. Integrating
phylogeny, geographic niche partitioning and secondary
metabolite synthesis in bloom-forming Planktothrix. ISME
J. 9:909-921.

Kurmayer R, Sivonen K, Wilmotte A, Salmaso N (eds.), 2017.
Molecular Tools for the Detection and Quantification of
Toxigenic Cyanobacteria. Wiley (in press).

Lage S, Burian A, Rasmussen U, Costa PR, Annadotter H,
Godhe A, Rydberg S, 2015. BMAA extraction of cyanobac-
teria samples: which method to choose? Environ. Sci. Pollut.
Res. Int. 23(1):338-350.

Ledreux A, Thomazeau S, Catherine A, Duval C, Yéprémian C,
Marie A, et al. 2010. Evidence for saxitoxins production by
the cyanobacterium Aphanizomenon gracile in a French
recreational water body. Harmful Algae. 10:88-97.

Li R, Carmichael WW, Brittain JE, Eaglesham GK, Shaw GR,
Mahakhant A, Noparatnaraporn N, Yongmanitchai W, Kaya
K, Watanabe MM, 2001. Isolation and identification of the
cyano-toxin cylindrospermopsin and deoxycylindrosper-
mopsin from a Thailand strain of Cylindrospermopsis raci-
borskii (Cyanobacteria). Toxicon 39:973-980

Lürling M, Faassen EJ, 2013. Dog poisoning associated with a
Microcystis aeruginosa bloom in the Netherlands. Toxins
5:556-567. 

Lürling M, Waajen G, de Senerpont Domis LN, 2016. Evalua-
tion of several end-of-pipe measures proposed to control
cyanobacteria. Aquat. Ecol. 50:499-520. 

Manganelli M, Scardala S, Stefanelli M, Palazzo F, Funari E,
Vichi S, Buratti FM, Testai E, 2012. Emerging health issues
of cyanobacterial blooms. Ann. Ist. Super. Sanita 48:415-428.

Manti G, Mattei D, Messineo V, Melchiorre S, Bogialli S, Sechi
N, Casiddu P, Luglie’ A, Di Brizio M, Bruno M, 2005. First
report of Cylindrospermopsis raciborskii in Italy. Harmful
Algae News 28: 8-9.

Mantzouki E, Visser PM, Bormans M, Ibelings BW, 2016. Un-
derstanding the key ecological traits of cyanobacteria as a
basis for their management and control in changing lakes.
Aquat. Ecol. 50:333-350. 

Matthijs HCP, Jančula D, Visser PM, Maršálek B, 2016. Existing
and emerging cyanocidal compounds, new perspectives for
cyanobacterial bloom mitigation. Aquat. Ecol. 50:443-460. 

Mazmouz R, Chapuis-Hugon F, Pichon V, Méjean A, Ploux O,
2011. The last step of the biosynthesis of the cyanotoxins
cylindrospermopsin and 7-epi-cylindrospermopsin is catal-
ysed by CyrI, a 2-oxoglutarate-dependent iron oxygenase.
ChemBioChem 12:858-862.

Mazur-Marzec H, Kaczkowska MJ, Blaszczyk A, Akcaalan R,
Spoof L, Meriluoto J, 2013. Diversity of peptides produced
by Nodularia spumigena from various geographical regions.
Mar. Drugs 11:1-19.

Méjean A, Mann S, Maldiney T, Vassiliadis G, Lequin O, Ploux
O, 2009. Evidence that biosynthesis of the neurotoxic al-
kaloids anatoxin-a and homoanatoxin-a in the cyanobac-
terium Oscillatoria PCC 6506 occurs on a modular
polyketide synthase initiated by L-Proline. J. Am. Chem.
Soc. 131:7512-7513.

Méjean A., Paci G, Gautier V, Ploux O, 2014. Biosynthesis of
anatoxin-a and analogues (anatoxins) in cyanobacteria. Tox-
icon 91:15-22.

Merel S, Villarin MC, Chung K., Snyder S, 2013a Spatial and

thematic distribution of research on cyanotoxins. Toxicon
76:118-131.

Merel S, Walker D, Chicana R, Snyder S, Baures E, Thomas O,
2013b State of knowledge and concerns on cyanobacterial
blooms and cyanotoxins. Environ. Int.. 59:303-327.

Meriluoto J, Spoof L, Codd GA (eds.), 2017. Handbook of
Cyanobacterial Monitoring and Cyanotoxin Analysis. Wiley.

Messineo V, Bogialli S, Melchiorre S, Sechi N, Lugliè A,
Casiddu P, Mariani MA, Padedda BM, Di Corcia A, Mazza
R, Carloni E, Bruno M, 2009. Cyanobacterial toxins in Ital-
ian freshwaters. Limnologica 39:95-106.

Metcalf JS, Richer R, Cox PA, Codd GA, 2012. Cyanotoxins in
desert environments may present a risk to human health. Sci.
Total Environ. 421-422:118-123. 

Mihali TK, Kellmann R, Muenchhoff J, Barrow KD, Neilan BA,
2008. Characterization of the gene cluster responsible for
cylindrospermopsin biosynthesis. Appl. Environ. Microbiol.
74:716-722.

Mitrovic SM, Hardwick L, Dorani F, 2011. Use of flow man-
agement to mitigate cyanobacterial blooms in the Lower
Darling River, Australia. J. Plankton Res. 2:229-241.

Moffitt MC, Neilan BA, 2004. Characterization of the nodularin
synthetase gene cluster and proposed theory of the evolution
of cyanobacterial hepatotoxins. Appl. Environ. Microbiol.
70:6353-6362. 

Murch SJ, Cox PA, Banack SA, 2004. A mechanism for slow
release of biomagnified cyanobacterial neurotoxins and neu-
rodegenerative disease in Guam. Proc. Natl. Acad. Sci.
U.S.A. 101: 12228-12231.

Murray SA, Mihali TK, Neilan BA, 2011. Extraordinary con-
servation, gene loss, and positive selection in the evolution
of an ancient neurotoxin. Mol. Biol. Evol. 28(3):1173-1182.

Ndlela LL, Oberholster PJ, Van Wyk JH, Cheng PH, 2016. An
overview of cyanobacterial bloom occurrences and research
in Africa over the last decade. Harmful Algae 60:11-26

Newcombe G, 2002. Removal of Algal Toxins from Drinking
Water Using Ozone and GAC. AWWA Research Foundation
and American Water Works Association, Denver, CO, USA:
133 pp.

Noordhuis R, van Zuidam BG, Peeters ETHM, 2016. Further
improvements in water quality of the Dutch borderlakes:
two types of clear states at different nutrient levels. Aquat.
Ecol. 50:521-540. 

Ohtani I, Moore RE, Runnegar MTC, 1992. Cylindrospermopsin:
a potent hepatotoxin from the blue-green alga Cylindrosper-
mopsis raciborskii. J. Am. Chem. Soc. 114:7941-7942

Okello W, Ostermaier V, Portmann C, Gademann K, Kurmayer
R, 2010. Spatial isolation favours the divergence in micro-
cystin net production by Microcystis in Ugandan freshwater
lakes. Water Res. 44:2803-2814.

O’Neil JM, Davis TW, Burford MA, Gobler CJ, 2012. The rise
of harmful cyanobacteria blooms: The potential roles of eu-
trophication and climate change. Harmful Algae 14:313-
334.

Onodera H, Oshima Y, Henriksen P, Yasumoto T, 1997. Confir-
mation of anatoxin-a(s), in the cyanobacterium Anabaena
lemmermannii, as the cause of bird kills in Danish lakes.
Toxicon 35: 1645-1648.

Osswald J, Rellán S, Gago-Martinez A, Vasconcelos V, 2009.
Production of anatoxin-a by cyanobacterial strains isolated

No
n-

co
mm

er
cia

l u
se

 on
ly



Toxic cyanobacteria in Europe - research progress through CYANOCOST 177

from Portuguese fresh water systems. Ecotoxicology
18:1110-1115.

Ostermaier V, Kurmayer R, 2010. Application of real-time PCR
to estimate toxin production by the cyanobacterium Plank-
tothrix sp. Appl. Environ. Microbiol. 76:3495-3502.

Paerl HW, Gardner WS, Havens KE, Joyner AR, McCarthy MJ,
Newell SE, Qin BQ, Scott JT, 2016. Mitigating cyanobac-
terial harmful algal blooms in aquatic ecosystems impacted
by climate change and anthropogenic nutrients. Harmful
Algae 54:213-222.

Pearson LA, Dittmann E, Mazmouz R, Ongley SE, P.
D’Agostino M, Neilan BA, 2016. The genetics, biosynthesis
and regulation of toxic specialized metabolites of cyanobac-
teria. Harmful Algae 54:98-111.

Poniedziałek B, Rzymski P, Wiktorowicz K, 2014. Toxicity of
cylindrospermopsin in human lymphocytes: proliferation,
viability and cell cycle studies. Toxicol. In Vitro 5: 968-974. 

Poniedziałek B, Rzymski P, Kokociński M, Karczewski J, 2015.
Toxic potencies of metabolite(s) of non-cylindrospermopsin
producing Cylindrospermopsis raciborskii isolated from
temperate zone in human white cells. Chemosphere
120:608-614. 

Quesada A, Moreno E, Carrasco D, Paniagua T, Wormer L, De
Hoyos C, Sukenik A, 2006. Toxicity of Aphanizomenon
ovalisporum (Cyanobacteria) in Spanish water reservoir.
Eur. J. Phycol. 41:39-45. 

Quiblier C, Wood S, Echenique-Subiabre I, Heath M, Villeneuve
A, Humbert JF, 2013. A review of current knowledge on
toxic benthic freshwater cyanobacteria - Ecology, toxin pro-
duction and risk management. Water Res. 47:5464-5479.

Rantala A, Fewer DP, Hisbergues M, Rouhiainen L, Vaitomaa
J, Börner T, Sivonen K, 2004. Phylogenetic evidence for the
early evolution of microcystin synthesis. Proc. Natl. Acad.
Sci. U.S.A. 101:568-573. 

Rantala-Ylinen A, Kana S, Wang H, Rouhiainen L, Wahlsten M,
Rizzi E, Berg K, Gugger M, Sivonen K, 2011. Anatoxin-a
synthetase gene cluster of the cyanobacterium Anabaena sp
Strain 37 and molecular methods to detect potential produc-
ers. Appl. Environ. Microbiol. 77:7271-7278. 

Rapala J, Robertson A, Negri AP, Berg KA, Tuomi P, Lyra C,
Erkomaa K, Lahti K, Hoppu K, Lepistö L, 2005. First report
of saxitoxin in Finnish lakes and possible associated effects
on human health. Environ. Toxicol. 20:331-40. 

Réveillon D, Abadie E, Séchet V, Masseret E, Hess P, Amzil Z,
2015. β-N-methylamino-l-alanine (BMAA) and isomers: Dis-
tribution in different food web compartments of Thau lagoon,
French Mediterranean Sea. Mar. Environ. Res. 110:8-18.

Réveillon D, Séchet V, Hess P, Amzil Z, 2016a. Production of
BMAA and DAB by diatoms (Phaeodactylum tricornutum,
Chaetoceros sp., Chaetoceros calcitrans and, Thalassiosira
pseudonana) and bacteria isolated from a diatom culture.
Harmful Algae 58:45-50.

Réveillon D, Séchet V, Hess P, Amzil Z, 2016b. Systematic de-
tection of BMAA (β-N-methylamino-l-alanine) and DAB
(2,4-diaminobutyric acid) in mollusks collected in shellfish
production areas along the French coasts. Toxicon 110:35-46.

Rodriguez E, Sordo A, Metcalf JS, Acero JL, 2007. Kinetics of
the oxidation of cylindrospermopsin and anatoxin-a with
chlorine, monochloramine and permanganate. Water Res.
41:2048-2056.

Rzymski P, Poniedziałek B, 2014. In search of environmental
role of cylindrospermopsin: a review on global distribution
and ecology of its producers. Water Res. 66:320-337.

Rosén J, Westerberg E, Schmiedt S, Hellenäs KE, 2016. BMAA
detected as neither free nor protein bound amino acid in blue
mussels. Toxicon 109:45-50.

Sahindokuyucu Kocasari F, Gulle I, Kocasari S, Pekkaya S, Mor
F, 2015. The occurrence and levels of cyanotoxin nodularin
from Nodularia spumigena in the alkaline and salty Lake
Burdur, Turkey. J. Limnol. 74:530-536. 

Saker ML, Neilan BA, 2001. Varied diazotrophies, morphologies,
and toxicities of genetically similar isolates of Cylindrosper-
mopsis raciborskii (Nostocales, Cyanophyceae) from north-
ern Australia. Appl. Environ. Microbiol. 67:1839-1845.

Savela H, Spoof L, Perälä N, Preede M, Lamminmäki U,
Nybom S, Häggqvist K, Meriluoto J, Vehniäinen M, 2015.
Detection of cyanobacterial sxt genes and paralytic shellfish
toxins in freshwater lakes and brackish waters on Åland Is-
lands, Finland. Harmful Algae 46:1-10.

Sciuto K, Moro I, 2015. Cyanobacteria: the bright and dark sides
of a charming group. Biodivers. Conserv. 24:711-738.

Shalev-Alon G, Sukenik A, Livnah O, Schwarz R, Kaplan A,
2002. A novel gene encoding amidinotransferase in the
cylindrospermopsin-producing cyanobacterium Aphani-
zomenon ovalisporum. FEMS Microbiol. Lett. 209:87-91.

Sharma VK, Triantis TM, Antoniou MG, He X, Pelaez M, Han
C, Song W, O’Shea KE, de la Cruz AA, Kaloudis T, Hiskia
A, Dionysiou DD, 2012. Destruction of microcystins by
conventional and advanced oxidation processes: A review.
Sep. Purif. Technol. 91:3-17.

Sierosławska A, Rymuszka A, 2015. Effects of cylindrosper-
mopsin on a common carp leucocyte cell line. J. Appl. Tox-
icol. 35:83-89.

Simeunović J, Svirčev Z, Karaman M, Knezević P, Melar M
2010. Cyanobacterial blooms and first observation of mi-
crocystin occurrences in freshwater ecosystems in Vojvodina
region (Serbia). Fresen. Environ. Bull. 19:198-207.

Sklenar K, Westrick J, Szlag D, 2016. Managing Cyanotoxins
in Drinking Water: A Technical Guidance Manual for Drink-
ing Water Professionals. American Water Works Association
and Water Research Foundation, Denver, CO, USA: 61 pp.

Spoof L, Berg KA, Rapala J, Lahti K, Lepistö L, Metcalf JS,
Codd GA, Meriluoto J, 2006. First observation of cylindros-
permopsin in Anabaena lapponica isolated from the boreal
environment (Finland). Environ. Toxicol. 21:552-560.

Stirling DJ, Quilliam MA, 2001. First report of the cyanobacte-
rial toxin cylindrospermopsin in New Zealand. Toxicon
39:1219-1222.

Stroom JM, Kardinaal WEA, 2016. How to combat cyanobac-
terial blooms: strategy toward preventive lake restoration
and reactive control measures. Aquat. Ecol. 50:521-576.

Sukenik A, Quesada A, Salmaso N, 2015. Global expansion of
toxic and non-toxic cyanobacteria: effect on ecosystem func-
tioning. Biodivers. Conserv. 24:889-908. 

Svirčev Z, Drobac D, Tokodi N, Lužanin Z, Munjas AM,
Nikolin B, Vuleta D, Meriluoto J, 2014a. Epidemiology of
cancers in Serbia and possible connection with cyanobacte-
rial blooms. J. Env. Sci. Health C Environ. Carcinog. Eco-
toxicol. Rev. 32:319-337. 

Svirčev Z, Drobac D, Tokodi N, Codd GA, Meriluoto J, 2017a.

No
n-

co
mm

er
cia

l u
se

 on
ly



J. Meriluoto et al.178

Toxicology of microcystins with reference to cases of
human intoxications and epidemiological investigations of
exposures to cyanobacteria and cyanotoxins. Arch. Toxicol.
91:621-650.

Svirčev Z, Drobac D, Tokodi N, Đenić D, Simeunović J, Hiskia
A, Kaloudis T, Mijović B, Šušak S, Protić M, Vidović M,
Onjia A, Nybom S, Važić T, Palanački Malešević T, Dulić
T, Pantelić D, Vukašinović M, Meriluoto J, 2017b. Lessons
from the Užice case: how to complement analytical data, p.
298-308. In: J Meriluoto, L Spoof, and GA Codd (eds.),
Handbook of Cyanobacterial Monitoring and Cyanotoxin
Analysis, Wiley. 

Svirčev Z, Obradović V, Codd GA, Marjanović P, Spoof L,
Drobac D, Tokodi N, Petković A, Nenin T, Simeunović J,
Važić T, Meriluoto M, 2016. Massive fish mortality and
Cylindrospermopsis raciborskii bloom in Aleksandrovac
Lake. Ecotoxicology 25:1352-1363.

Svirčev Z, Simeunović J, Subakov-Simić G, Krstić S, Pantelić
D, Dulić T, 2013. Cyanobacterial blooms and their toxicity
in Vojvodina lakes, Serbia. Int. J. Environ. Res. 7:745-758. 

Svirčev Z, Tokodi N, Drobac D, Codd GA, 2014b. Cyanobacteria
in aquatic ecosystems in Serbia: effects on water quality,
human health and biodiversity. System. Biodivers. 12:261-270.

Sychrova E, Stepankova T, Novakova K, Blaha L, Giesy JP,
Hilscherova H, 2012. Estrogenic activity in extracts and ex-
udates of cyanobacteria and green algae. Environ. Int.
39:134-140. 

Testai E, Scardala S, Victu S, Buratti M, Funari E, 2016. Risk
to human health associated with the environmental occur-
rence of cyanobacterial neurotoxic alkaloids anatoxins and
saxitoxins. Crit. Rev. Toxicol. 46:285-419. 

Tillett D, Dittmann E, Erhard M, vonDöhren H, Börner T, Neilan
BA, 2000. Structural organization of microcystin biosynthe-
sis in Microcystis aeruginosa PCC7806: an integrated pep-
tide-polyketide synthetase system. Chem. Biol. 7:753-764.

Triest L, Stiers I, Van Onsem S, 2016. Biomanipulation as a na-
ture-based solution to reduce cyanobacterial blooms. Aquat.
Ecol. 50:461-484. 

Van Dolah ER, Paolisso M, Sellner K, Place A, 2016. Employ-
ing a socio-ecological systems approach to engage harmful
algal blooms stakeholders. Aquat. Ecol. 50:577-594. 

Verspagen JM, Passarge J, Jöhnk KD, Visser PM, Peperzak L,
Boers P, Laanbroek HJ, Huisman J, 2006. Water manage-
ment strategies against toxic Microcystis blooms in the
Dutch delta. Ecol. Appl. 16:313-327.

Visser PM, Ibelings BW, Bormans M, Huisman J, 2016a. Arti-
ficial mixing to control cyanobacterial blooms: a review.
Aquat. Ecol. 50:423-442. 

Visser PM, Ibelings BW, Fastner J, Bormans M (eds.), 2016b.
Special Issue ‘Cyanobacterial blooms. Ecology, prevention,
mitigation and control.’ Aquat Ecol. 50:327-605.

Webster IT, Sherman BS, Bormans, M, Jones G, 2000. Manage-
ment strategies for cyanobacterial blooms in an impounded
lowland river. Regul. Rivers Res. Manag. 16:513-525.

Wimmer KM, Strangman WK, Wright JLC, 2014. 7-Deoxy-
desulfo-cylindrospermopsin and 7-deoxy-desulfo-12-acetyl-
cylindrospermopsin: two new cylindrospermopsin analogs
isolated from a Thai strain of Cylindrospermopsis raci-
borskii. Harmful Algae 37: 203-206.

Wood R, 2016. Acute animal and human poisonings from cyan-
otoxin exposure - A review of the literature. Environ. Int.
91:276-282.

Zamyadi A, Dorner S, Ndong M, Ellis D, Bolduc A, Bastien C,
Prevost M, 2014. Application of in vivo measurements for
the management of cyanobacteria breakthrough into drink-
ing water treatment plants. Environ. Sci. Process. Impacts
16:313-323.

Zervou S-K, Christophoridis C, Kaloudis T, Triantis TM, Hiskia
A, 2017. New SPE-LC-MS/MS method for simultaneous
determination of multi-class cyanobacterial and algal toxins.
J. Hazard. Mater. 323:56-66.

Zhang QT, Warwick RM, McNeill CL, Widdicombe CE, Shee-
han A, Widdicombe S, 2015. An unusually large phytoplank-
ton spring bloom drives rapid changes in benthic diversity
and ecosystem function. Progr. Oceanogr. 137:533-545.

No
n-

co
mm

er
cia

l u
se

 on
ly