Occurrence of Ulva lactuca L. 1753 (Ulvaceae, Chlorophyta) at the Murman Сoast of the Barents Sea


RESEARCH NOTE

Occurrence of Ulva lactuca L. 1753 (Ulvaceae, Chlorophyta) at the Murman
Сoast of the Barents Sea
Svetlana Malavenda a, Mikhail Makarov a, Inna Ryzhik a, Maxim Mityaeva & Sergey Malavendab

aLaboratory of Algology, Murmansk Marine Biological Institute, Murmansk, Russia; bDepartment of Biology, Murmansk State Technical
University, Murmansk, Russia

ABSTRACT
Findings of Ulva lactuca L. on the Murman Сoast of the Barents Sea are described for the
period 2009–2017. This species has not been found in this area for more than 50 years. The
occurrence of U. lactuca on the Murman Coast appears to be related to the recent warming of
waters in the region.

KEYWORDS
Sea lettuce; seaweed;
climate change; global
warming; Arctic;
berealization

Introduction

The present study aims to give an overview on the
distribution of Ulva lactuca Linnaeus 1753: 1163
(Chlorophyta, Ulvaceae) in the Barents Sea. In the
World Ocean, this species is very widespread
(Guiry & Guiry 2018), found almost everywhere
in shallow waters, including estuaries. The tem-
perature and light tolerance of the species are well
studied. Photosynthesis has been observed at tem-
peratures ranging from 0°C to 28°C (Lüning
1984), with the highest growth rate occurring at
10–15°C (Fortes & Lüning 1980). At water tem-
peratures of 7°C and 10°C, U. lactuca can adapt to
low illumination levels (Vermaat & Sand-Jensen
1987; Sand-Jensen 1988). However, it is still
unclear how U. lactuca responds to the combina-
tion of low illumination and low temperature. At
the northern margin of its geographical range, U.
lactuca findings are random and rare: it has been
found on the western, southern and the northern
shores of Svalbard (Vinogradova 1995; Gullikssen
et al. 1999), Novaya Zemlya (Štrik et al. 2000) and
on the coasts of Norway (Brattegard et al. 2001)
and Alaska (Hayden & Waaland 2004; Lindeberg
& Lindstrom 2010). The harsh wintertime condi-
tions of the polar region – low temperature and
lack of light (limiting photosynthesis) – is likely
the reason for the weak expansion of species in
the Arctic seas.

On the Murman Coast, U. lactuca was found in
Olenii Strait (22 September 1930), in Kola Bay (1
June 1932) and in Podpakhta Bay 30 years later (2
July1961) (Vinogradova 1974). Species lists compiled
later do not mention U. lactuca (e.g., Šošina &

Averintseva 1994; Šošina 2003; Zavalko & Šošina
2008) and even question the presence of this species
in the Barents Sea. Analysis of these data indicates the
instability of the presence of U. lactuca on the
Murmansk coast.

In recent decades, temperatures in the Barents Sea
have risen following the increased inflow of Atlantic
water masses during spring (Matishov et al. 2009;
Matishov et al. 2014; MMBI 2017). It is possible
that these water masses also brought spores, gametes
or zygotes of U. lactuca, which developed in
Zelenetskaya Bay under the more favourable
conditions.

Part of the long-term monitoring of the state of
coastal phytocenoses of the Murman Coast and
the Russian archipelagos of the Barents Sea, this
study aims to present the latest findings of
U. lactuca on the Murman Coast and to consider
their possible relationship with the positive tem-
perature anomalies of the coastal water masses in
the Barents Sea.

Materials and methods

A study of the species composition of the phyto-
cenoses of the Murman Coast was carried out each
year from 2009 to 2017, mainly in the summer
(June–September). During this period 12 different
sites from Pechenga Bay in the east (69º 36´ N 31º
21´ E) to Ivanovskaja Bay in the west (68º 17´ N
38º 44´ E) of the Murman Coast were investigated,
spanning a distance of about 300 km (Fig. 1).
Algae were sampled with a standard geobotanic
method, using a frame with an area of

CONTACT Svetlana Malavenda malavenda@yandex.ru Murmansk Marine Biological Institute, Kola Scientific Center, Russian Academy of
Sciences (MMBI KSC RAS), Vladimirskaya St. 17, Murmansk 183010 Russia

Supplementary data for this article can be accessed here.

POLAR RESEARCH
2018, VOL. 37, 1503912
https://doi.org/10.1080/17518369.2018.1503912

© 2018 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.
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which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

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0.25 × 0.25 m, with three replicas, on the upper,
middle and lower littoral. On the entire accessible
part of the littoral of the bays, qualitative surveys
of species composition were also carried out.

Ulva lactuca was identified using the description of
Vinogradova (1974). We relied on morphological
features because the genetic analysis of Ulva lactuca
and another species of Ulva gathered in other areas
(Malta et al. 1999; Hayden & Waaland 2002; Hayden
et al. 2004) has shown these to characterize the spe-
cies. Ulva lactuca is characterized by a bright green
solid thallus, attached to the substrate by a small
rhizoid part (stems and sack-like base are absent).
The thallus is bilayered, without a cavity. The cells
are arranged chaotically, somewhat elongated in the
transverse section, their size ranging from 12 to 23
μm, in most cases 15–20 μm. The chloroplasts are
lamellar, in mature thallus, granular. There are one to
two (occasionally three) pyrenoids in the cells, but
sometimes they are indistinctly visible.

Differentiation of U. lactuca and U. rigida was not
carried out in this study due to the lack of clear

species criteria. All the found thalli with the described
set of characteristics were considered U. lactuca. Ulva
rigida has not previously been noted in the Barents
Sea, and we do not consider it reasonable to intro-
duce this species into the flora on the basis of this
single sample. Further study is needed in order to
determine whether U. rigida is present in the region.

The material is stored at the Murmansk Biological
Institute (Murmansk, Russia). One of the samples was
given to the Herbarium of the Komarov Botanical
Institute of the Russian Academy of Sciences (St.
Petersburg, Russia).

Results and discussion

Murman’s coastal biocenoses were first systematically
studied in the period from 1912 through the 1930s.
The Barents Sea underwent a warming in the early
1930s (Matishov et al. 2009; Matishov et al. 2014),
when findings of U. lactuca (Vinogradova 1974) on
the Murman Coast were first described. The second
period of intensive algological research was from
1985 to the 1990s, when the list of species of
Yarnyshnaya Bay, in the eastern part of the
Murman Coast, was drawn up (Šošina &
Averintseva 1994). At that time, negative temperature
anomalies were observed (Matishov et al. 2009;
Matishov et al. 2014) and the species was not on the
list.

The most recent period in the study of the algal
communities of the Murman Coast began in 2009.
Thalli of U. lactuca (Fig. 2) were found exclusively
in Zelenetskaya Bay (69.10 N, 36.05 E) in 2009,
2012, 2014, 2016 and 2017 (Table 1). Although
Zelenetskaya Bay had been carefully surveyed in
earlier years, 2009 was the first year in which
signs of U. lactuca were observed there. In 2009,
2012, 2014 and 2016, single specimens of this spe-
cies were encountered in Zelenetskaya Bay, with the
first finding being made in the sublittoral commu-
nity (Fig. 1). In 2017, U. lactuca was noted many
times on the boulders of the lower littoral, pro-
tected from the surf (Supplementary Fig. S1), and
also at the experimental farm of Saccharina latis-
sima (Linnaeus) Lane, Mayes, Druehl & Saunders
2006 and Fucus vesiculosus L. 1753. Attachment of
U. lactuca spores on the ropes of the experimental
plot could only happen by way of self-planting from
the water column since the thalli of S. latissima and
F. vesiculosus, woven into lines, were sampled
directly from the bay. The other seaweeds came
from the bay, so U. lactica must have landed on
the ropes by itself, via the water.

In 2016 and 2017, the size of the cells of U. lactuca
specimens grown on the farm ropes had smaller cells
(7–12 × 12–18 μm, height 14–17 μm), which sepa-
rates these algae from those grown at the bottom

Figure 1. The study area on the Murman Coast. Inset:
Zelenetskaya Bay, indicating where Ulva lactuca was found
in 2009–2017.

2 S. MALAVENDA ET AL.



substrate, although the plants themselves were out-
wardly typical (Supplementary Fig. S2).

Finding U. lactuca in Zelenetskaya Bay confirms
the presence of the species on the Murman Coast,
and adds to observations of the occurence of the
species on other Barents Sea coasts. It also raises a
number of questions, since, of all the areas of the
Murman Coast that were surveyed in recent years,
U. lactuca was found only in Zelenetskaya Bay.

Zelenetskaya Bay (in some publications,
Dal’nezelenetskaya) is protected from the direct
action of the surf by a group of islands to the north.
The bay shape is square, about 2 km across. Depths
do not exceed 18 m. The substrate in the protected
part of the bay is silty−sandy, with a small amount of
medium-sized and small stones, and in the straits and
along the edge of the shore there are boulders. There
are two inlets in the bay: the south-western inlet
(Oscar Inlet) and a much larger south-eastern inlet.
The average annual temperature of the surface waters
is 3.8 ± 0.1°C (Mitjaev 2014). There are two indepen-
dent currents in the bay: the waters enter and exit
through the western and eastern straits, moving in
the inlets counter-clockwise (Mitjaev 2014). The
hydrological regime of Zelenetskaya Bay differs even
from the adjacent Yarnyshnaya Bay on account of

different physical and geographical conditions
(Gromov et al. 2010; Mitjaev 2014).

In 1983–84, the water temperature in the 0–15 m
layer of Zelenetskaya Bay dropped to −1.5°C in
January, and a steady rise in the water temperature
was observed only from the end of April. In June-
July, the temperature of the water was less than 7°C,
and only at the end of August and September was
there an increase to 9°C (Bardan & Širokolobov
1988). Since 1998, coastal waters have warmed
(Matishov et al. 2009; Matishov et al. 2014). In
2002–2012, the average annual temperature of the
surface water layer in Zelenetskaya Bay was 3.8°C,
and the average monthly temperature in July-
September exceeded 7°C. In winter, it did not drop
below 0.7°C (Il’in et al. 2016). Oceanographic studies
have revealed continuing positive thermohaline
anomalies in the spring and summer in 2016 and
2017, indicating the increased inflow of waters of
Atlantic origin into the Barents Sea (Moiseev &
Žičkin 2017).

Observations of a sharp increase in U. lactuca
occurrences in Zelenetskaya Bay in 2017 suggest a
relationship with the warming of the bay. It is likely
that warmer conditions in the spring and in the first
half of summer contribute to the survival and growth

Figure 2. (a) The appearance of the Ulva lactuca thallus found in Zelenetskaya Bay, July 2017; (b) the transverse section of the
thallus, viewed through a microscope.

Table 1. Brief description of the sites in Zelenetskaya Bay where Ulva lactuca was found and the morphological parameters of
the specimens. Sporangia were present only in the specimen found on 3 August 2016 (marked in boldface).

Date
(dd/mm/yy) Site description T (°C)

Number
of

specimens Thallus size (cm) Cell size (μm)

26/08/09 Sublittoral, 2 m, bottom community of Saccharina latissima 7.2 2 15 × 20 7 × 10 15–20
03/07/12 Littoral, bottom community of Fucus distichus + F. vesiculosus 7.7 2 3 × 4 4 × 5 15–20
10/08/14 Littoral, bottom community of Fucus distichus + F. vesiculosus 6.7 1 17 × 15 15–18
03/08/16 Seaweed farm (S. latissima), on the rope, near the surface 9.2 1 18 × 25 10–15
13/08/17 Lower littoral, an area protected from the violent churning

along coastline, between Monostroma grevillei at the
bottom substrate

7.5 1 1 × 2 15–20

14/08/17 Seaweed farm (S. latissima), on the rope, near the surface 8.7 1 6 × 7 12–15
21/08/17 Lower littoral of Zhiloi Island, at the margin of the rockweeds

and kelp
9.3 > 20 0.2 × 1–2 × 5 15–20

05/09/17 Lower littoral of Zhiloi Island, at the margin of the rockweeds
and kelp

2 2 × 3 and 3 × 4 15–20

POLAR RESEARCH 3



of U. lactuca. The ability of this species to reproduce
vegetatively in extreme environmental conditions, as
well as the viability of zygotes for several months,
allows them to spread over long distances
(Vinogradova 1974). It is probable that U. lactuca
zygotes are transported to the study area by the
currents coming from the coast of the Scandinavian
Peninsula, and in warmer periods they can germinate
and develop. Adult plants demonstrate a high toler-
ance to low temperature (Fortes & Lüning 1980;
Lüning 1984; Vermaat & Sand-Jensen 1987; Sand-
Jensen 1988); however, the temperature sensitivity
of spores, gametes and zygotes of this species has
not been investigated. Unicellular stages may be
more sensitive to stress and are probably unlikely to
survive high-latitude wintertime conditions of low
temperatures and little light.

A similar pattern in the distribution of the spe-
cies at the northern margin of the geographical
range was noted in Spitsbergen: studies conducted
in 1988 in the southern part of the archipelago –
Hornsund fjord, Sørkappland – did not find this
species; but in 2007–08 it was noted (Weslawski
et al. 2010). The authors attribute the appearance
of U. lactuca with the increase in the mean water
temperature: the average temperature in Hornsund
in summer also exceeds 7°C. In the Novaya Zemlya
Archipelago, U. lactuca was identified in the collec-
tions made in 1994–95 in the Yugorsky Shar Strait,
in Chernaya Bay and at Mestnyi Island, and in
Ivanova Bay in 1995 (Štrik et al. 2000), although
the species was not found earlier in this region
(Gemp & Byzova 1976). These findings may be
associated with the warming period of the south-
eastern Barents Sea in 1990–95 (Griŝenko 2010).
The findings of U. lactuca in Olenii Strait and in
Kola Bay in the 1930s and in Podpakhta Bay in the
1960s (Vinogradova 1974) may also be related to
climatic conditions of those times (Matishov et al.
2009; Matishov et al. 2014; Mitjaev 2014).

Thus, the analysis of the periodicity of the findings
of U. lactuca in various areas of the Barents Sea
suggests a connection of its recent poleward expan-
sion with an increase of the water temperature.

Acknowledgements

The authors are grateful to T.A. Mikhailova for help in trans-
ferring material to the Komarov Botanical Institute Herbarium

Disclosure statement

No potential conflict of interest was reported by the
authors.

Funding

This work was financially supported by project no.
RFMEFI61616X0073 (MEMO-PRO) funded by the
Ministry of Education and Science of the Russian
Federation.

ORCID

Svetlana Malavenda http://orcid.org/0000-0002-8314-
3255
Mikhail Makarov http://orcid.org/0000-0001-9277-6292
Inna Ryzhik http://orcid.org/0000-0003-3874-2379

References

Bardan S.I. & Širokolobov V.N. 1988. Gidrologo–
gidrohimičeskie issledovanija. (Hydrological–hydrochemi-
cal research.) In V.G. Averincev et al. (eds.): Kontrol’
e’kologicheskoj situacii v rajone opy’tno-promy ’shlennoj
plantacii v gube Dal’nezeleneczkaya (operativny’j informa-
cionny’j material). (Control of the environmental situa-
tion in the area of the experimental seaweed farm in
Dalnezelenetskaya Bay. Operational and information
material.) Pp. 7–23. Apatity: Kola Scientific Center of
the Russian Academy of Sciences.

Brattegard T. & Holthe T. (eds.) 2001. Distribution of
marine, benthic macro-organisms in Norway. A tabulated
catalogue. Research Report 2001-3. (Updated version of
report DN 1997-1.) Trondheim: Directorate for Nature
Management.

Fortes M.D. & Lüning K. 1980. Growth rates on North Sea
macroalgae in relation to temperature, irradiance and
photoperiod. Helgoländer Meeresuntersuchungen 34, 15–29.

Gemp K.P. & Byzova L.N. 1976. Vodorosli proliva Karskie
Vorota (južnoe poberež’e Novoj Zemli). (The algae of the
Kara Strait, south coast of Novaya Zemlya.) Materialy
Rybohozaistvennih Issledovaniy Severnogo Bassejna
(Fisheries Research in the Northern Basin) 12, 102–110.

Griŝenko V.I. 2010. Izmenenija klimata na akvatorii ûgo-
vostočnoj časti barenceva morja. (Climate change in the
waters of the south-east Barents Sea.) In G.G. Matišov &
G.A. Tarasov (eds.): Priroda šel’fa i arhipelagov evropejs-
koj Arktiki. Kompleksnye issledovanija prirody
Špicbergen. (Proceedings of the International Scientific
Conference Nature of the Shelf and Archipelagos of the
European Arctic. Complex Investigations of the Svalbard
Archipelago Nature. Murmansk, Russia, 27-30 October
2010.) Pp. 68–72. Moscow: GEOS.

Gromov M.S., Moiseev D.V. & Ŝirokolobov D.V. 2010 The
hydrometeorological conditions in the Yarnyshnaya and
Zelenetskaya bays of the Barents Sea in the summer of
2009. In G.G. Matišov & G.A. Tarasov (eds.): Priroda
šel’fa i arhipelagov evropejskoj Arktiki. Kompleksnye issle-
dovanija prirody Špicbergen. (Proceedings of the
International Scientific Conference Nature of the Shelf
and Archipelagos of the European Arctic. Complex
Investigations of the Svalbard Archipelago Nature.
Murmansk, Russia, 27-30 October 2010.) Pp. 72–79.
Moscow: GEOS.

Guiry M.D. & Guiry G.M. 2018. AlgaeBase. Database
maintained by National University of Ireland, Galway.
Accessed on the internet at http://www.algaebase.org 1
March 2018.

4 S. MALAVENDA ET AL.

http://www.algaebase.org


Gulikssen B., Palerud R., Brattegard T. & Sneli J. (eds.)
1999. Distribution of marine benthic macro-organisms at
Svalbard (including Bear Island) and Jan Mayen.
Research Report DN 1999-4. Trondheim: Directorate
for Nature Management.

Hayden H.S. & Waaland J.R. 2002. Phylogenetic systema-
tics of the Ulvaceae (Ulvales, Ulvophyceae) using chlor-
oplast and nuclear DNA sequences. Journal of Phycology
38, 1200–1212.

Hayden H.S. & Waaland J.R. 2004. A molecular systematic
study of Ulva (Ulvaceae, Ulvales) from the northeast
Pacific. Phycologia 43, 364–382.

Il’in G.V., Moiseev D.V., Širokolobov D.V., Derjabin A.A.
& Pavlova L.G. 2016. Gidrologičeskij režim guby
Zeleneckaja, Vostočnyj Murman. (Long-term dynamics
of the hydrological conditions of Zelenetskaya Bay, east
Murman.) Vestnik MSTU 19, 268–277.

Lindeberg M.R. & Lindstrom S.C. 2010. Field guide to the
seaweeds of Alaska. Fairbanks: Alaska Sea Grant College
Program.

Lüning K. 1984. Temperature tolerance and biogeography
of seaweeds: the marine algal flora of Helgoland (North
Sea) as an example. Helgoländer Meeresuntersuchungen
38, 305–317.

Malta E.J., Draisma S.G.A. & Kamermans P. 1999. Free-
floating Ulva in the southwest Netherlands: species or
morphotypes? A morphological, molecular and ecological
comparison. European Journal of Phycology 34, 443–454.

Matishov G.G., Berdnikov S.V., Zhichkin A.P., Dzhenyuk
S.L., Smolyar I.V., Kulygin V.V., Yaitskaya N.A.,
Povazhniy V.V., Sheverdyaev I.V., Kumpan S.V.,
Tretyakova I.A., Tsygankova A.E., D’yakov N.N.,
Fomin V.V., Klochkov D.N., Shatohin B.M., Plotnikov
V.V., Vakulskaya N.M., Luchin V.A. & Kruts A.A. 2014.
Atlas of climatic changes in nine large marine ecosystems
of the Northern Hemisphere (1827-2013). International
Ocean Atlas and Information Series 14. NOAA Atlas
NESDIS 78. Silver Spring, MD: National Environmental
Satellit. Data, and Information Service, National Oceanic
and Atmospheric Administration, US Dept. of
Commerce. Doi: 10.7289/V5Q52MK5.

Matishov G.G., Matishov D.G. & Moiseev D.V. 2009.
Inflow of Atlantic-origin waters to the Barents Sea
along glacial troughs. Oceanologia 51, 321–340.

Mitjaev M.V. 2014. Murmanskoe poberež’e (geologo-
geomorfologičeskie i klimatičeskie osobennosti, sovremen-
nye geologičeskie processy). (Murman Coast. Geological,
geomorphological and climatic features, current geological
processes.) Apatity: Kola Scientific Center, Russian
Academy of Sciences.

MMBI 2017. Biologičeskie resursy arktičeskih morej Rossii:
sovremennoe sostojanie, vlijanie prirodnyh izmenenij i
antropogennogo vozdejstvija, naučnaja osnova i perspek-
tivy ispol’zovanija. (Biological resources of Russia’s Arctic
seas: current state, the influence of natural changes and

anthropogenic effects, the scientific basis and perspectives
of use for the period 2014-17.) Murmansk: Murmansk
Marine Biological Institute, Kola Scientific Center,
Russian Academy of Sciences.

Moiseev D.V. & Žičkin A.P. 2017. Termohalinnye uslovija
v prikromočnoj zone na severe Barenceva morja v aprele
2016 goda. (Thermohaline conditions of the ice edge
area in the northern Barents Sea in April 2016.) Trudy
Kol’skogo Naučnogo Centra RAN 8, 10–25.

Sand-Jensen K. 1988. Photosynthetic responses of Ulva
lactuca at very low light. Marine Ecology Progress Series
50, 195–201.

Šošina E.V. 2003. Makrofity. (Macrophytes.) In L.L.
Kuznecov & E.V. Šošina (eds.): Fitocenozy Barenceva
morâ (fiziologičeskie i strukturnye harakteristiki).
(Phytocenoses of the Barents Sea. Physiological and struc-
tural characteristics.) Pp. 177–304. Apatity: Kola
Scientific Center, Russian Academy of Sciences.

Šošina E.V. & Averinceva S.G. 1994. Raspredelenie associa-
cij vodoroslej, vidovoj sostav i biomassa v gube jarnyšnoj
Barenceva morja. (Distribution of the algal community,
their species diversity and biomass in Yarnyshnaia Bay of
the Barents Sea.) In G.G. Matišov (ed.):
Gidrobiologičeskie issledovanija v gubah i zalivah sever-
nyh morej Rossii. (Hydrobiological research in the bays
and coves of Russia’s northern seas.) Pp. 38–61. Apatity:
Kola Scientific Center, Russian Academy of Sciences.

Štrik V.A., Vozžinskaja B.V. & Vehov N.V. 2000. Morskie
vodorosli poberež’ja Novoj Zemli i proliva jugorskij šar.
(Marine algae of the coast of Novaya Zemlya and the
Jugorskiy Shar Strait.) In A.A. Nejman & M.I.
Tarverdijeva (eds.): Morskie gidrobiologičeskie issledova-
nija. (Marine hydrobiological studies.) Pp. 88–98.
Moscow: Russian Research Institute of Fisheries and
Oceanography.

Vermaat J.E. & Sand-Jensen K. 1987. Survival, metabolism
and growth of Ulva lactuca under winter conditions: a
laboratory study of bottlenecks in the life cycle. Marine
Biology 95, 55–61.

Vinogradova K.L. 1974. Ul’vovye vodorosli
(Chlorophyta) morej SSSR. (Ulvaceous algae
[Chlorophyta] of the seas of the USSR.) Leningrad
(St. Petersburg): Nauka.

Vinogradova K.L. 1995. The checklist of the marine algae
from Spitsbergen. Botaničeskij Žurnal 80, 50–61.

Weslawski J.M., Wiktor J. Jr & Kotwicki L. 2010. Increase
in biodiversity in the Arctic rocky littoral, Sorkappland,
Svalbard, after 20 years of climate warming. Marine
Biodiversity 40, 123–130.

Zavalko S.E. & Šošina E.V. 2008. Mnogourovnevaja
morfofiziologičeskaja ocenka sostojanija fukusovyh
vodoroslej v uslovijah antropogennogo zagrjaznenija
(Kol’skij zaliv, Barencevo more). (Multilevel morpho-
physiological investigation of brown algae, Kola Bay,
Barents Sea.) Vestnik MGTU 11, 423–431.

POLAR RESEARCH 5


	Abstract
	Introduction
	Materials and methods
	Results and discussion
	Acknowledgements
	Disclosure statement
	Funding
	References