Layout 1 INTRODUCTION Blooms of cyanobacteria (blue-green algae/ cyanoprokaryotes) have increased globally in recent decades (Paerl and Otten, 2013; Harke et al., 2016). Due to the ability of toxin production, some species affect live- stocks and high cyanotoxin concentrations were linked to animal deaths and human health hazard through drinking and recreational waters (Codd et al., 1999; Carmichael et al., 2001; Azevedo et al., 2002; Backer et al., 2015). Cyanobacteria can produce different types of toxic com- pounds, which include hepatotoxins, neurotoxins, cyto- toxins, dermatotoxins and irritant toxins (Bláha, 2009; Westrick et al., 2010). The occurence of cyanotoxins have been reported in several cyanobacterial genera such as Mi- crocystis, Nodularia, Aphanizomenon, Planktothrix, An- abaena and Cylindrospermopsis (Sivonen et al., 1990; Merel et. al., 2013; Bernard et al., 2017). The most studied group of cyanobacterial toxins are the hepatotoxic cyclic peptides, which include the micro- cystins and nodularins. Although they are similar in struc- ture, nodularin has been isolated from only one species of cyanobacteria, Nodularia spumigena Mertens ex Bornet & Flahault, whereas microcystin can be produced by mul- tiple cyanobacterial genera, most notably by Microcystis, Planktothrix or Anabaena (Sivonen and Jones, 1999; Bernard et al., 2017). Over 100 microcystin variants and 10 nodularin variants have been identified (Spoof et al., 2001; Bortoli and Volmer, 2014). Cyanobacterial blooms occur in Turkish inland waters, mostly lakes and reservoirs used as supplies of drinking water or recreation. Aphanizomenon sp. was the first cyanobacteria to cause problems in filter system of drinking water treatment plant in Kurtbogazi Dam Lake (Ankara) in 1981 (Guler Aykulu, pers. comm.). During the 1990s many cyanobacterial blooms were detected in the Marmara re- gion. In 1994, blooms of Anabaena spp. resulted in fish mortality in İznik Lake (Albay et al., 2003a). Cyanotoxin research has started at the end of 1990s and increased in re- cent years (Albay et al., 2003a,b; Albay et al., 2005; Akçaalan et al., 2006, 2014a, 2014b, 2016) It is well known that microscopic identification of cyanobacteria is time consuming and it requires taxo- nomic expertise. Due to this limitation, molecular tools have been increasingly applied also to environmental studies (Kurmayer and Christiansen, 2009; Bukowska et al., 2014). Especially, because of the conserved nature of the 16S rRNA gene, it is used to discriminate strains at the species level (Neilan et al., 1997; Moffitt and Neilan, Advances in Oceanography and Limnology, 2017; 8(1): 52-60 ARTICLE DOI: 10.4081/aiol.2017.6394 This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0). Molecular detection of hepatotoxic cyanobacteria in inland water bodies of the Marmara Region, Turkey Latife Köker,1 Reyhan Akçaalan,1 Meriç Albay,1 Brett A. Neilan2 1Istanbul University, Fisheries Faculty, Ordu cad. NO:200 34470, Laleli Istanbul, Turkey; 2School of Biotechnology and Biomolecular Sciences, University of New South Wales, 7 Sydney 2052, Australia *Corresponding author: latifekoker@gmail.com ABSTRACT Blooms of cyanobacteria are an increasingly frequent phenomenon in freshwater ecosystems worldwide as a result of eutrophication. Many species can produce hepatotoxins that cause severe health hazards to humans. The aim of this study was to identify the bloom forming cyanobacteria species by molecular methods and to amplify genes responsible for hepatotoxin biosynthesis from the environmental samples and isolated strains of cyanobacteria from Küçükçekmece Lagoon, Sapanca, İznik, Manyas and Taşkısı Lakes. A total of 10 bloom samples and 11 isolated strains were examined and Microcystis spp., Planktothrix spp., Nodularia spumigena, Anabaenopsis elenkinii, Sphaerosper- mopsis aphanizomenoides, Cylindrospermopsis raciborskii were identified. Hepatotoxin genes were detected in 60% of the bloom samples and 45% of the strains. Two Microcystis strains were obtained from Küçükçekmece Lagoon. While the strain assigned to Microcystis flos- aquae was non-toxic, Microcystis aeruginosa strain produced microcystin. According to PCR results, the M. aeruginosa and Planktothrix agardhii bloom samples of Küçükçekmece Lagoon contained the microcystin synthetase gene E (mcyE) indicative of microcystin production, however, no microcystin was detected by HPLC. The mcyE gene was also found in Microcystis wesenbergii isolated from Taşkısı Lake, and in all Planktothrix rubescens bloom samples from Sapanca Lake. To our knowledge, this is the first detailed study for identifiying different toxic cyanobacteria species and their hepatotoxin production from several waterbodies in Turkey using molecular methods. Key words: 16S rRNA, Aminotransferase, Nodularin, Microcystin, Cyanobacteria, Cyanotoxin. Received: November 2016. Accepted: April 2017. No n- co mm er cia l u se on ly Molecular identification of hepatotoxic cyanobacteria in Turkey 53 2001). Jungblut and Neilan (2006) developed a molecular method to detect both microcystin and nodularin-produc- ing species by amplifying and sequencing of the amino- transferase (AMT) domain of mcyE and ndaF genes in the mcy and nda operons. The reason for choosing AMT do- main was its important role in synthesis of all micro- cystins and nodularins. Due to the increased frequency of algal blooms in Turkish lakes, it is important to understand the distribution of toxin-producing cyanobacteria in this area. The aims of the present study were to determine the bloom-forming cyanobacteria species using the 16S rRNA gene as well as the potential toxicity using the mcyE and ndaF genes indicative of microcystin/nodularin biosynthesis, occur- ring in lakes around the Marmara region (Küçükçekmece, Sapanca, İznik, Manyas and Taşkısı). METHODS Sampling sites Cyanobacterial blooms have been collected from five lakes in Marmara region (Fig. 1). İznik Lake, located in the southeast of Marmara region, is the fifth biggest lake in Turkey. Cyanobacterial blooms occured because of heavy nutrient loading (Albay et al., 2003a; Akçaalan et al., 2006; Tas and Gonulol, 2007). The first bloom was formed by Anabaena sp. in 1994. Planktothrix rubescens (De Candolle ex Gomont) Anagnostidis & Komárek and Nodularia spumigena were also detected (Akçaalan et al., 2006; Akçaalan et al., 2009). Sapanca Lake is an oligo- mesotrophic lake and Planktothrix rubescens blooms have been observed in the metalimnion of the lake since the 1980s (Akçaalan et al., 2006). The other studied area, Küçükçekmece Lagoon (Istanbul, Turkey), has a connec- tion to the Marmara Sea via a narrow channel. The lagoon is in hypereutrophic conditions and Microcystis aerugi- nosa (Kützing) Kützing blooms were observed from late spring to mid-autumn (Albay et al., 2005) Manyas Lake is a eutrophic lake which is an important bird sanctuary, and in 1998 it was listed in the Ramsar Convention (Çelik and Ongun, 2006). Taşkısı Lake is a small, shallow lake situated in the eastern part of the Marmara region (Aykulu et al., 1999) (Tab. 1). Cyanobacteria identification Freshly collected bloom samples were identified by inverted microscopy (Axio Observer Z1, Carl Zeiss GmbH, Jena, Germany). 1-2 drops of fresh sample were Fig. 1. Location of sampling lakes in Marmara Region. No n- co mm er cia l u se on ly L. Köker et al.54 investigated according to taxonomical keys using fila- ment/colony traits, presence and structure of mucilage, cell shape and size, whether having a specialized cell or not. Cyanobacterial identification was done according to Whitton and Potts (2007), Komárek (2013), Komárek and Anagnostidis (1986; 1999; 2005) and Anagnostidis and Komárek (1988). Environmental samples During 2004-2009, ten bloom samples were collected from five lakes of Marmara region (Tab. 2). For cyan- otoxin and molecular analysis, samples were collected using plankton net (20 µm mesh size, Hydro-Bios) and lyophilised and conserved at -20°C. Cyanobacterial strains Cyanobacterial strains used in the present study (Tab. 3) were collected from blooms. Single filaments and colonies of cyanobacteria were isolated by repeated washing with sterile media from a Pasteur pipette and transferred 96-well plates filled with 200 µL BG 11 medium with or without ni- trate according to presence or absence of heterocytes (Rippka et al., 1979). DNA extraction DNA extraction from fresh cell pellets and lyophilized bloom samples was performed using XS extraction buffer containing 1% potassium-methylxanthogenate (800 mM ammonium acetate; 20 mM EDTA; 1% SDS; 100 mM Tris-HCI, pH 7.4) (Tillett and Neilan, 2000). DNA was dissolved in Tris-EDTA buffer (10:1). Concentrations of DNA were determined using a Nanodrop® ND-1000 spec- trophotometer and DNA extracts were stored at -20°C. PCR amplification and sequencing All PCR reactions were performed in 20 µL reac- tion volume containing PCR buffer (Bioline, London, UK), 2.5 mM MgCI2, 0.2 mM dNTPs (Bioline), 10 pmol each of the forward and reverse primers and 0.2 U Taq polymerase (Bioline). The PCR amplification products were visualized using gel electrophoresis on 2% agarose, and staining with 0.5 µg mL–1 ethidium bromide for 10 min and documented with a Gel Doc XR camera using quantity one 4.6.1 software (Bio-Rad, Hercules, CA, USA). 16S rDNA amplification was performed using primers 27F and 809R (Jungblut et al., 2005) with an initial denat- uration step at 92 oC for 2 min followed by 35 cycles of 94°C for 10 s, 60°C for 20 s and 72°C for 1 min and a final extension step at 72°C for 5 min (Jungblut et al., 2005). M. aeruginosa PCC7806 was used as positive control. Hepatotoxin (HEP) PCR reactions were performed using primers HEPF and HEPR targeting mcyE/ndaF gene (Jungblut and Neilan, 2006). An initial denaturation step at 92°C for 2 min was followed by 35 cycles of 92°C for 20 s, 52°C for 30 s, and 72°C for 1 min, with a final extension step at 72°C for 5 min. The PCR products were sent to Ramaciotti Centre for Genomics (University of New South Wales, Sydney Aus- tralia) and sequencing was performed using the Illumina MiSeq platform (Illumina, San Diego, CA, USA). Using a PANDAseq (ver. 2.4) nucleotide sequence were recon- structed (Masella et al, 2012). Overlapping regions were Tab. 1. Features of the studied lakes. Waterbody Surface area Common use Dominant cyanobacteria Max. depth İznik Lake 300 km2 Recreation irrigation Nodularia spumigena 65 m Planktothrix rubescens Cylindrospermopsis raciborskii Dolichospermum sp. Anabaenopsis sp. Sapanca Lake 46.8 km2 Drinking water 55 m Recreation Planktothrix rubescens Küçükçekmece Lagoon 15.22 km2 Recreation Microcystis aeruginosa 20 m Planktothrix agardhii Microcystis wesenbergii Manyas Lake 159 km2 Fisheries activities Microcystis aeruginosa 3.4 m Recreation Microcystis wesenbergii Irrigation Sphaerospermopsis sp. Dolichospermum flos-aquae Cuspidothrix issatschenkoi Taşkısı Lake 0.75 km2 Fisheries activities Microcystis spp. 4.5 m Dolichospermum sp. No n- co mm er cia l u se on ly Molecular identification of hepatotoxic cyanobacteria in Turkey 55 aligned and scored. Sequences were identified using the BLASTn search program (NCBI). Hepatotoxin analysis Microcystin/Nodularin production of environmental blooms and isolated strains were measured by high per- formance liquid chromatography (HPLC) with photodiode array (PDA) detector (Perkin Elmer, USA) according to Lawton (1994). Lyophilized samples (10-50 mg) were ex- tracted in 70% (v/v) aqueous methanol with ultrasonication and centrifuged at 14,000 x g for 5 min. Clear supernatants were injected into the HPLC column (Waters Symmetry C18, 3.9 × 150 mm, 5 μm particle size). Elution mode was used: injection volume 25 µL, flow rate 1 mL min–1 and col- umn temperature 40°C. Mobile phases were Milli-Q water and acetonitrile both containing 0.1% (v/v) TFA. Eluent ab- sorbance was monitored from 200 to 300 nm and micro- cystins were detected at 238 nm. The limit of detection was 0.4 ng per injection corresponding to 0.001 µg mg−1 dw. RESULTS Cyanobacteria species Species identification was done by microscopy. Since all blooms were mainly dominated by a single species,16S rDNA results are very well correlated with microscopical examination. Cyanobacteria that belong to three orders, Chroococcales, Nostocales and Oscillatoriales, were de- tected. A total of nine species, Anabaenopsis elenkinii V.V. Miller, Cylindrospermopsis raciborskii (Woloszynska) Seenayya & Subba Raju, Sphaerospermopsis aphani- zomenoides (previously denominated Aphanizomenon aphanizomenoides Forti), N. spumigena, M. aeruginosa, Microcystis flos-aquae (Wittrock) Kirchner, Microcystis wesenbergii (Komárek) Komárek ex Komárek, P. rubescens, and Planktothrix agardhii (Gomont) Anagnos- tidis & Komárek were identified. The 16S rDNA gene se- quences obtained from both strains and environmental samples were assigned using BLASTn search of the Na- Tab. 2. HPLC and HEP PCR results for environmental bloom samples. Code Dominant species* Place of collection Date of collection HPLC results HEP PCR GenBank accession (µg mg–1 d.w) results numbers E1 Planktothrix agardhii Küçükçekmece Lagoon 27/10/2004 ND - KY091680 E2 Planktothrix agardhii Küçükçekmece Lagoon 03/11/2004 ND + KY091681 E3 Planktothrix agardhii Küçükçekmece Lagoon 11/11/2004 ND - KY091682 E4 Microcystis aeruginosa Küçükçekmece Lagoon 04/10/2006 2.9 + KY091683 E5 Planktothrix rubescens Sapanca Lake 06/02/2007 6.0 + KY091684 E6 Planktothrix rubescens Sapanca Lake 21/02/2007 4.7 + KY091685 E7 Microcystis aeruginosa Küçükçekmece Lagoon 28/09/2007 ND + KY091686 E8 Planktothrix rubescens Sapanca Lake 23/01/2008 0.3 + KY091687 E9 Anabaenopsis elenkinii İznik Lake 16/05/2008 ND - KY091688 E10 Planktothrix rubescens Sapanca Lake 28/01/2009 1.1 + KY091689 *Species: according to microscopic identification; ND, not detected. Tab. 3. HPLC and HEP PCR results for cyanobacterial cultures. Code Cyanobacterial species* Origin Strain HPLC results HEP PCR GenBank accession (µg mg–1 d.w) results numbers S1 Microcystis aeruginosa Küçükçekmece Lagoon IFCC-MA03 6.8 + KY077257 S2 Microcystis flos-aquae Küçükçekmece Lagoon IFCC-MF01 ND - KY077258 S3 Microcystis wesenbergii Taşkısı Lake IFCC-MW01 2.4 + KY077259 S4 Anabaenopsis elenkinii İznik Lake IFCC-AE01 ND - KY077260 S5 Sphaerospermopsis aphanizomenoides İznik Lake IFCC-AA05 ND - KY077261 S6 Sphaerospermopsis aphanizomenoides İznik Lake IFCC-AA01 ND - KY077262 S7 Cylindrospermopsis raciborskii Manyas Lake IFCC-CR01 ND - KY077263 S8 Nodularia spumigena İznik Lake IFCC-NS01 3.2 + KY077264 S9 Nodularia spumigena İznik Lake IFCC-NS03 3.0 + KY077265 S10 Planktothrix agardhii Küçükçekmece Lagoon IFCC-PA01 ND - KY077266 S11 Planktothrix rubescens Sapanca Lake IFCC-PR04 4.3 + KY077267 *Species: according to microscopic identification; ND, not detected. No n- co mm er cia l u se on ly L. Köker et al.56 tional Biotechnology Information (NCBI) database (http://ncbi.nlm.nih.gov/blast/) (Tabs. 2 and 3). The BLAST search showed 98-100% similarities. Detection of hepatotoxin genes The HEP PCR reaction resulted in amplification of a fragment in the expected size from two of three Micro- cystis sp. strains, P. rubescens and two N. spumigena strains. No PCR product was obtained from strains as- signed to P. agardhii, C. raciborskii, A. elenkinii and S. aphanizomenoides (Tab. 3). The HEP fragment was suc- cessfully amplified from five of seven Planktothrix sp., one of two M. aeruginosa dominated environmental bloom samples. In culture samples, M. aeruginosa (S1) and M. flos- aquae (S2) strains were isolated from same bloom recorded in Küçükçekmece Lagoon. While M. aeruginosa strain showed a HEP-PCR product, M. flos-aquae was found negative (Tab. 3). The other Microcystis morphos- pecies, M. wesenbergii gave a positive result and showed HEP-PCR product. The Nostocalen species; S. aphani- zomenoides and A. elenkinii did not give positive result as well as C. raciborskii strain. In environmental samples, the HEP PCR reactions re- sulted in amplification of a 472-bp fragments for eight of ten samples. The mcyE products were obtained from one of three P. agardhii bloom sample (E2), while no PCR products were obtained from P. agardhii (E1-E3) bloom samples. PCR-amplification of the AMT domain was succes- fully attained from all P. rubescens samples. To verify that the resulting amplicons, all PCR–am- plified products from various lakes were sequenced. BLAST searches were used to identify similar sequences from GenBank. Detection of hepatotoxins Cyanobacterial hepatotoxins were detected by HPLC- PDA. Total microcystin concentrations varied from 0.3 to 6.8 microcystin-LR equivalents µg mg–1 d.w. (Tabs. 2 and 3). Nodularin concentrations in IFCC-NS01 (S8) and IFCC-NS03 (S9) were 3.2 and 3.0 µg mg–1, respectively. The highest amount of microcystin (6.8 µg mg–1 d.w.) was found in M. aeruginosa (S1) strain. Microcystin content of M. wesenbergii (S3) was found to be 2.4 µg mg–1. HPLC analyses confirmed no microcystin presence in M. flos-aquae (S2), A. elenkinii (S4), S. aphanizomenoides (S5, S6), C. raciborskii (S7) and P. agardhii (S10) strains. In environmental samples, microcystins were not de- tected in P. agardhii (E1, E3) and A. elenkinii (E9) bloom samples. While mcyE products were obtained from P. agardhii (E2) and M. aeruginosa (E7), microcystin was not detected by HPLC. Microcystin content of P. rubescens samples varied between 0.3-6 µg mg–1. DISCUSSION Cyanobacteria species were shown to be the main component of phytoplankton community in lakes and reservoirs. Earlier records on the algal flora of Turkish waterbodies reported taxonomic lists, which were based on the microscopical monitoring and showed a diverse cyanobacteria community (Aykulu and Obalı, 1981; Fakıoğlu et al., 2011). However, polyphasic approaches in classification of organisms are essential, since morpho- logical characters are often unstable and incongruent with molecular tools. For example, the genus Microcystis has several morphospecies sharing rather similar characteris- tics and discussions on the taxonomic assignment of these morphotypes is ongoing (Bittencourt-Oliveira, 2003). Within the genus Microcystis, typically two morphos- pecies (M. aeruginosa and M. flos-aquae) are found in the same population. According to the results of molecular methods used in this study, the mcyE gene occurred in M. aeruginosa (S1) strain, but not in M. flos-aquae isolated from the same bloom. Tillett et al. (2001) also did not find mcyA gene occurrence among M. flos-aquae strains. However, mcyA and B genes were detected in half of the colonies assigned to M. flos-aquae (total number was 8) isolated from lakes in Europe. Correspondingly, M. aeruginosa (n=149) had a higher proportion of colonies containing the mcyA/B gene (Via-Ordorika et al., 2004). In this study, the third strain of Microcystis isolated from Taşkısı Lake was assigned to M. wesenbergii (S3) and not only it contained the mcyE gene but also produced micro- cystin (2.4 µg mg–1 d.w.). According to the study of Via- Ordorika et al. (2004) this morphospecies was found non-toxic in all colonies (n=21) from European lakes. Maršálek et al. (2001) showed that in Czech Republic M. wesenbergii contains little or no microcystin, similarly no microcystin was detected in colonies isolated from a Czech reservoir (Welker et al., 2007). Also, molecular and chemical analysis did not show microcystin production in 250 individual colonies and 21 strains of M. wesenbergii isolated from Chinese lakes (Xu et al., 2008). However, Otsuka et al (1999) found that M. wesenbergii has toxic and nontoxic strains. Yosuno et al. (1998) also found that all M. wesenbergii (n=8) strains examined contained mi- crocystin. Likewise, in Lake Kastoria (Greece), M. we- senbergii dominant bloom containing toxin producing genes such as mcyA and mcyB was reported (Gkelis et al., 2014). Pavlova et al. (2014; 2015) found toxic bloom dominated by M. wesenbergii in Lake Dourankoulak, and highlighted that toxicity may vary between clones of the same strain. Because of these contradictory results, it is necessary to analyse higher number of Microcystis mor- No n- co mm er cia l u se on ly Molecular identification of hepatotoxic cyanobacteria in Turkey 57 phospecies to determine the relationship between toxi- genicity and morphological characters. It is known that P. agardhii and P. rubescens have spe- cific ecological niches. While P. rubescens occurs in oligo- to mesotrophic physically stratified lakes (Akçaalan et al., 2014a), P. agardhii become dominant in shallow, eutrophic and polymictic water bodies (Kur- mayer et al., 2004). In this study, P. rubescens was iso- lated from Sapanca Lake, which is a moderately deep, oligo-mesotrophic lake. In contrast, P. agardhii formed a bloom in a hypereutrophic lake in late autumn and polymictic conditions. Similar to Microcystis both toxic and nontoxic strains can be found in the same population of P. agardhii and P. rubescens (Kurmayer et al., 2004; Akçaalan et al., 2006). In general, the share of strains con- taining the mcyA/B gene is highest in P. rubescens popu- lations in contrast to P. agardhii. Accordingly, our results showed that P. rubescens has active microcystin genes, while the strain isolated from P. agardhii bloom was found nontoxic. The strain of A. elenkinii was isolated from a bloom sample of İznik Lake which was dominated by this species. Both the bloom sample and isolated strain were found negative for the mcy genes as well as no micro- cystin was detected by HPLC. This species generally co- occurs with other Nostocalen cyanobacteria and toxicity is attained to all of them (Maršálek et al., 2000; Papadim- itriou et al., 2013). However, there is no record of micro- cystin production of a isolated strain of A. elenkinii. C. raciborskii has been shown to produce hepatotoxic cylindrospermopsin and neurotoxic saxitoxins (Wood and Stirling, 2003; Molica et al., 2005). This species origi- nates from tropical regions and currently expands its dis- tribution in temperate regions, therefore it may be considered an invasive species in European waterbodies (Padisák, 1997; Moreira et al., 2015). In this study C. raciborskii was isolated from shallow hypereutrophic Manyas Lake but did not contain the mcyE gene. Also, no cylindrospermopsin was detected according to molecular and analytical analysis (data not shown). There are some contradictory results between molecular and analytical methods. M. aeruginosa (E5) and P. agardhii (E2) contained the mcyE gene, but did not produce micro- cystin as revealed by HPLC. Studies showed that cyanobacteria strains with mcy genes lacked detectable mi- crocystins as a result of inactivation of the genes (Neilan et al., 1999; Nishizawa et al.,1999; Kaebernick et al., 2001; Tillett et al., 2001; Mikalsen et al., 2003). Samples used in this study were collected from water- bodies with different morphological and physicochemical characteristics. Some cyanobacteria species have been found in both shallow and moderately deep lakes, some others prefer deep waterbodies. However, the distribution of species is governed mainly by trophic situation of the lakes. Microcystis species together with P. agardhii formed blooms in eutrophic environment, such as Manyas, Küçükçekmece and Taşkısı Lake. Nostocalen Cyanobacteria species, on the other hand, prefer alkaline, meso-eutrophic waters of İznik Lake (Akçaalan et al., 2009, 2014b). Especially Nodularia spumigena is an eu- ryhaline species living in hyposaline to brackish waters in Turkey (Kocasari et al., 2015; Kızılkaya et al., 2016). Similarly, A. elenkinii is also known as a hyposaline species (Kemp, 2009; Kotut and Krienitz, 2011). The growth of these species might have been supported by high conductivity of the lake water. On the other hand, in typical freshwater Sapanca Lake, which is used for drink- ing water and has low nutrient concentration, toxic P. rubescens form massive blooms. The most important fac- tors are the high water transparency, thermal stratification, a long water residence time and low nutrient availability, which have negative effect on other phytoplankton species in the lake (Legnani et al., 2005; Akçaalan et al., 2014a) CONCLUSIONS In conclusion, applications of molecular and DNA am- plification methods provide a great advantage for moni- toring toxic cyanobacterial blooms in the aquatic environments. It has a potential to identify the organisms and to detect their cyanotoxin production. This study, using different methods collaboratively, shows that toxic cyanobacteria blooms are very common in Turkish inland waterbodies with different trophic levels. To our knowl- edge, this is the first detailed study identifying different toxic cyanobacteria species and their hepatotoxin produc- tion in Turkey using molecular methods. ACKNOWLEDGMENTS This work was supported by Scientific Research Proj- ects Coordination Unit of Istanbul University. 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