Analytical methods for cyanobacterial toxins

Cross, David Michael

January 1997

No description available.

572

Microcystin; Nodularin

The influence of the cyanobacterium Nodularia spumigena on the growth of perch (Perca fluviatilis)

Olofsson, Martin

January 2009

Nodularin (NODLN) is a pentapeptide produced by the filamentous cyanobacterium Nodularia spumigena that is a bloom-forming species in the Baltic Sea. NODLN is an intracellular hepatotoxin, which can have a negative effect on aquatic life including fish. Toxins are released into the water when cells are lysing, e.g. during a decaying bloom. N. spumigena filaments have previously been shown to have a negative effect on perch egg development and perch larval survival. Coastal fish such as perch (Perca fluviatilis) have suffered from recruitment problems in the Baltic Sea the last decades. However, little is known about the impact of toxic cyanobacteria on juvenile perch. In the autumn of 2007, 1+ perch were exposed, during 29 days to either whole live cells (WC) or a crude extract (CE) of broken N. spumigena cells. Chlorophyll a concentrations in the aquaria were 50 µg L -1. Perch were fed chironomidae larvae twice a day. Unexposed perch either fed (CoF) or without food (Co) served as controls. Length and weight of perch were measured at onset and termination of experiment. NODLN content was measured in N. spumigena filaments, crude extract and perch liver samples using liquid chromatography-mass spectrometry (LC-MS). Total lipids (TL) were extracted and quantified from whole-body lyophilised perch excluding livers. No significant differences for length and weight of perch were found between treatments and fed control. NODLN was detected in the crude extract samples, while no NODLN was detected in the perch livers. Moreover TL determination revealed no significant differences between treatments and fed control. Nodularia spumigena did not affect perch in this experiment, probably due to that the critical period of the first year for the perch was exceeded. Therefore, 1+ perch was not as susceptible to the cyanobacterium as eggs, larvae and younger juveniles of fish found in the literature. Perch liver did not contain NODLN, thus either the toxin was detoxicated with no recorded energetic cost or it was not ingested. The variables studied here did not show any effects of NODLN. However, other chemical methods such as enzymatic activity may disclose effects of NODLN.

Cyanobacteria

perch

Nodularin

Baltic Sea

Nodularia spumigena

The influence of the cyanobacterium <em>Nodularia spumigena </em>on the growth of perch (<em>Perca fluviatilis)</em>

Olofsson, Martin

January 2009

<p>Nodularin (NODLN) is a pentapeptide produced by the filamentous cyanobacterium <em>Nodularia spumigena</em> that is a bloom-forming species in the Baltic Sea. NODLN is an intracellular hepatotoxin, which can have a negative effect on aquatic life including fish. Toxins are released into the water when cells are lysing, e.g. during a decaying bloom. <em>N. spumigena </em>filaments have previously been shown to have a negative effect on perch egg development and perch larval survival. Coastal fish such as perch (<em>Perca fluviatilis</em>) have suffered from recruitment problems in the Baltic Sea the last decades. However, little is known about the impact of toxic cyanobacteria on juvenile perch. In the autumn of 2007, 1+ perch were exposed, during 29 days to either whole live cells (WC) or a crude extract (CE) of broken <em>N. spumigena</em> cells. Chlorophyll <em>a </em>concentrations in the aquaria were 50 µg L ^-1. Perch were fed chironomidae larvae twice a day. Unexposed perch either fed (CoF) or without food (Co) served as controls. Length and weight of perch were measured at onset and termination of experiment. NODLN content was measured in <em>N. spumigena </em>filaments,<em> </em>crude extract and perch liver samples using liquid chromatography-mass spectrometry (LC-MS). Total lipids (TL) were extracted and quantified from whole-body lyophilised perch excluding livers. No significant differences for length and weight of perch were found between treatments and fed control. NODLN was detected in the crude extract samples, while no NODLN was detected in the perch livers. Moreover TL determination revealed no significant differences between treatments and fed control. <em>Nodularia spumigena</em> did not affect perch in this experiment, probably due to that the critical period of the first year for the perch was exceeded. Therefore, 1+ perch was not as susceptible to the cyanobacterium as eggs, larvae and younger juveniles of fish found in the literature. Perch liver did not contain NODLN, thus either the toxin was detoxicated with no recorded energetic cost or it was not ingested. The variables studied here did not show any effects of NODLN. However, other chemical methods such as enzymatic activity may disclose effects of NODLN.</p><p> </p>

Cyanobacteria

perch

Nodularin

Baltic Sea

Nodularia spumigena

Transcription regulation of hepatotoxins microcystin and nodularin from cyanobacteria

Root, Hannah Patricia, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2008

The role and function of hepatotoxins microcystin and nodularin produced by M.aeruginosa PCC 7806 and N. spumigena NSORlO respectively have yet to be elucidated. The mode of transcriptional regulation of these toxins, incorporating DNA binding proteins, was investigated, as an attempt to further understand the key control mechanisms acting on the toxins. The DNA binding proteins that control nitrogen and iron responsive transcription, NtcA and Fur, were identified from M. aeruginosa PCC7806 and N. spumigena NSOR10. Cloning and over-expression in E. coli was followed by mobility shift assays to determine binding characteristics of NtcA and Fur to the promoters, mcyA/D and ndaA/C, those regions that control the toxin encoding gene clusters in M. aeruginosa PCC 7806 and N. spumigena NSOR10, respectively. The results from these studies suggested a role for iron and nitrogen in the transcriptional control of microcystin and nodularin. biosynthesis. As NtcA and Fur classically act to regulate nitrogen and iron dependent genes, a link may be made to the putative function and control of microcystin and nodularin. By identifying the transcription factors NtcA and Fur in these genera, a greater understanding of the link between nutrient levels in the environment and hepatotoxin production in cyanobacteria may be possible.

Microcystin.

Hepatotoxins.

DNA binding proteins.

Nodularin.

Cyanobacteria.

Uptake and depuration of cyanotoxins in the common blue mussel Mytilus edulis

Waack, Julia

January 2017

Cyanobacteria produce a variety of secondary metabolites which possess amongst others antifungal, antibacterial, and antiviral properties. Being primary producers they are also a vital component within the food web. However, certain strains also produce toxic metabolites such as the hepatotoxins microcystin (MC) and nodularin (NOD). Their toxicity in combination with the increasing global occurrence has resulted in a drinking water guideline limit of 1 μg L-1 being issued by the World Health Organisation (WHO). However, these toxins are not only present in water, but can be accumulated by fish and shellfish. Currently, no regulations regarding cyanotoxin contaminated seafood has been established despite similar toxicity to routinely monitored marine toxins such as domoic acid (DA). To facilitate regular monitoring, a high performance liquid chromatography photo diode array (HPLC-PDA) analysis method for the detection of DA was optimised to enable the simultaneous detection of DA and nine cyanotoxins. This method was then utilised to determine cyanotoxin concentration in laboratory cyanobacteria strains. To assess the accumulation and depuration of cyanotoxins in the common blue mussel Mytilus edulis, three feeding trials were performed. During these, mussels were exposed to two cyanobacteria strains, Nodularia spumigena KAC66, Microcystis aeruginosa PCC 7813, both individually and simultaneously. A rapid dose dependent accumulation of cyanotoxins was observed with maximum concentration of 3.4 -17 μg g-1 ww accumulated by M. edulis, which was followed by a much slower depuration observed. During the final feeding trial, with N. spumigena KAC 66 and M. aeruginosa PCC7813, cyanotoxins were still detectable following 27 days of depuration. Mortality in all studies was 7% or less indicating that most mussels were unaffected by the maximum dose of 480 μg L-1 NOD (feeding study 1), 390 μg L-1 MC (feeding study 2), or 130 μg L-1 total cyanotoxins (feeding trial 3), respectively. Mortality in negative control tanks was lower throughout all three feeding trials ( < 1 - 2.6%). Consumption of a typical portion size (20 mussels) would result in ingestion of cyanotoxins at levels significantly higher than the WHO recommended tolerable daily intake (TDI) of 2.4 μg NOD and/or MCs for a 60 kg adult. This value was exceeded not only during the exposure period (maximum levels 270 - 1370 μg cyanotoxins per 20 mussels), but also at the end of the depuration period 39-600 μg cyanotoxins per 20 mussels. These results illustrated that cyanotoxin monitoring of seafood should be considered not only during, but also following bloom events. In an attempt to investigate the cyanotoxin budget of the experimental system, not only mussels, but cyanobacteria cultures, the tank water, and the mussel faeces were also analysed for their cyanotoxin content. Results showed that large quantities of MCs and NOD were unaccounted for during all exposure trials. The combined effect of cyanotoxin metabolism in M. edulis, biotic and/or abiotic degradation, protein binding, and losses during the extraction and analysis were thought to have contributed to the unaccounted cyanotoxin fraction. Mussel flesh was analysed for the presence of glutathione or cysteine conjugates, however, there was no evidence of their occurrence in the samples tested. Due to these discrepancies in the toxin budget of the system, the introduction of correction factors for the analysis of cyanotoxins in M. edulis was suggested in order to protect the general public.

615.9

Effects of the Cyanobacterium Nodularia spumigena on Selected Estuarine Fauna

Davies, Warren Raymond, warren.davies@optusnet.com.au

January 2007

Nodularia spumigena is an estuarine cyanobacteria that produces the toxin nodularin. This toxic cyanobacteria is known to have caused death to domestic and wild animals and is recognised as dangerous to human health. N. spumigena causes harmful algal blooms in many parts of the world including Australia. The toxic solutes of N. spumigena are potentially dangerous when contact is made to contaminated water bodies or is ingested by primary consumers. In Australia blooms of N. spumigena are common in the Gippsland Lakes in South-eastern Victoria and cause socio - economic hardships to the local communities. This PhD investigates the toxic effects of N. spumigena and its solutes to a range of aquatic life. A method known as SPME - HPLC showed promise in environmental monitoring of N. spumigena toxins by measuring nodularin from water samples. Other research presented study into the lethal and sublethal effects of on an extract from N. spumigena to aquatic fauna. Resu lts showed the N. spumigena extract was not lethal to many aquatic fauna although zooplankton from the Gippsland Lakes showed mortality at environmental relevant levels. Biochemical studies focusing on animal detoxification and antioxidation enzymes and DNA integrity showed sublethal effects to the N. spumigena extract. Results presented in this thesis show that an extract of N. spumigena elicited detoxification and antioxidation responses in animals tested. Furthermore, the use of the COMET assay showed increased damage to DNA of animals tested. Results also showed that different organs in animals tested responded differently to the aqueous extract, suggesting mode of uptake maybe important in toxicosis. Further, feeding studies with N. spumigena help elucidate mode of uptake using enzyme response biomarkers. The overall results of this research provided an assessment of the toxic affects of N. spumigena on aquatic fauna with special reference to the Gippsland Lakes, Victoria, Australia.

Nodularia spumigena

nodularin

Gippsland Lakes

cyanotoxin

SPME

GST

GSH

DNA

detoxification enzymes

antioxidant enzymes

COMET assay

Baltic Sea phytoplankton in a changing environment

Bertos-Fortis, Mireia

January 2016

Future climate scenarios in the Baltic Sea project increasing sea surface temperature, as well as increasing precipitation and river runoff resulting in decreased salinity. These changes can severely impact the dynamics and function of brackish water communities, specifically phytoplankton. Phytoplankton are a significant source of organic matter to other trophic levels, and some species can be toxic. Their response to future climate conditions is of great relevance for the health of humans and aquatic ecosystems. The aim of this thesis was to assess the potential for climate-induced changes, such as decreasing salinity, to affect phytoplankton dynamics, physiology and chemical profiles in the Baltic Sea.      Phytoplankton successional patterns in the Baltic Proper consist of a spring bloom where diatoms and dinoflagellates co-occur and a summer bloom dominated by filamentous/colonial cyanobacteria. The consensus is that future warmer conditions will promote filamentous/colonial cyanobacteria blooms. This thesis shows that phytoplankton biomass in the spring bloom was lower in years with milder winters compared with cold winters. This suggests that in terms of annual carbon export to higher trophic levels, loss of biomass from the spring bloom is unlikely to be compensated by summer cyanobacteria. High frequency sampling of phytoplankton performed in this thesis revealed a strong relationship between the dynamics of pico- and filamentous cyanobacteria. Large genetic diversity was found in cyanobacterial populations with high niche differentiation among the same species. At community level, high temperature and low salinity were the main factors shaping the summer cyanobacterial composition. These conditions may promote the predominance of opportunistic filamentous cyanobacteria, e.g. Nodularia spumigena. This species produces various bioactive compounds, including non-ribosomal peptides such as the hepatotoxin nodularin. In this work, N. spumigena subpopulations evolved different physiological strategies, including chemical profiles, to cope with salinity stress. This high phenotypic plasticity ensures survival in future climate conditions. Under salinity stress, some subpopulations displayed shorter filaments as a trade-off. This indicates that the future freshening of the Baltic Sea may promote grazing on filamentous cyanobacteria and modify carbon flows in the ecosystem. In this thesis, Baltic N. spumigena chemotypes and genotypes grouped into two main clusters without influence of geographical origin. Thus, chemical profiling can be used to explore conspecific diversity in closely genetically related N. spumigena subpopulations.      Overall, this thesis has significantly expanded the knowledge on phytoplankton community and population responses to short- and long-term environmental changes, relevant to project the impacts of future climate conditions in the Baltic Sea.

phytoplankton ecology

cyanobacteria

dynamics

environmental factors

successional patterns

interactions

life strategies

non-ribosomal peptides

diversity

nodularin

N. spumigena

Desenvolvimento de técnicas de imunoensaio para detecção de microcistina em amostras ambientais / Development of immunoassay techniques to detect microcystin in environmental samples

Anjos, Fabyana Maria dos

15 December 2009

A contaminação da água para consumo humano por toxinas produzidas por cianobactérias é um problema de saúde pública e das autoridades em todo o mundo. Microcistina-LR (MCLR) é uma cianotoxina heptapeptídica cíclica que inibe as proteínas fosfatases PP1 E PP2A nos hepatócitos. Microcistinas são produzidas por diversos gêneros de cianobactérias e mais de 70 variações estruturais têm sido caracterizadas em florações naturais. Por serem haptenos, as microcistinas são incapazes de induzir uma resposta imune em animais. Conseqüentemente, foi necessário aplicar métodos de conjugação envolvendo a adição de uma proteína carreadora, mcKLH (cationized Keyhole Limpet Hemocyanin). Portanto, o objetivo inicial desta tese foi o de obter anticorpos monoclonal (em camundongos) e policlonal (em coelho) anti- MCLR. Com relação ao anticorpo monoclonal foram obtidos 9 hibridomas (k29, k210, k317, k248, k284, k290, k2161, k2226, k2232), sendo que apenas 5 se mostraram estáveis (k29, k317, k248, k284, k2232). Estes foram selecionados para serem isotipados, expandidos em líquido ascítico, purificados em coluna cromatográfica de proteína-A e titulados. Dentre estes cinco hibridomas secretores de anticorpos, o clone k317 foi o que melhor reconheceu (mais específico) a toxina MCLR. Os anticorpos do sobrenadante de meio de cultura do hibridoma e o fluido ascítico purificado foram identificados pelo ensaio ELISA (Enzyme Linked Immunosorbent Assay) previamente padronizado. Mesmo sensibilizando a placa de ELISA com diferentes antígenos, tais como MCLR-cBSA, MCLR, MCLR, MCRR, MCYR e MCLA, o clone 17 foi o que apresentou melhor linearidade frente às variantes de microcistina. Portanto, o clone 17 (isótipo IgG1) obtido é muito promissor e será usado para detecção de MCLR na água para consumo humano através do desenvolvimento de um kit de ELISA competição. Com relação ao anticorpo policlonal, o antígeno de imunização foi MCLR-mcKLH, enquanto que o antígeno de sensibilização foi MCLR-cBSA para o ensaio de titulação de anticorpos de classe IgG por ELISA indireto. Na seqüencia, foi padronizado um ensaio ELISA competição utilizando somente a toxina MCLR como antígeno de sensibilização. Este método Caseína foi padronizado, validado e comparado com o kit comercial Abraxis®. O kit ELISA competição que utiliza anticorpo policlonal, nomeado como método Caseína, foi avaliado quanto Limite Inferior de Quantificação, Especificidade, Seletividade, influência do metanol no ensaio, Recuperação, Linearidade, Precisão, Exatidão e Robustez. Este método de triagem apresentou excelente resultado quando comparado ao kit comercial Abraxis®, pois foi capaz de detectar tanto variantes de microcistinas como nodularinas no ambiente aquático. O ensaio ELISA competição utilizando anticorpo policlonal anti-MCLR foi submetido à patente pela Agência USP de Inovação (I.N.P.I. 018090046230). / The contamination of drinking water by cyanobacterial toxins is a public health issue and a concern for water authorities throughout the world. Microcystin-LR (MCLR) is a hazardous cyclic heptapeptide cyanotoxin, which inhibits protein phosphatase PP1 and PP2A in hepatocytes. Microcystins are produced by several genera of cyanobacteria and presents more than 70 structural variations characterized in natural blooms. As haptens, microcystins are unable to invoke an immune response in animals. Consequently, the application of conjugation methods with an additional carrier protein, the KLH (Keyhole Limpet Hemocyanin) was necessary. The main objective of this study was to obtain monoclonal (in mice) and polyclonal (in rabbits) antibodies for reacting against MCLR. In what refers to monoclonal antibodies, 9 hybridomas (k29, k210, k317, k248, k284, k290, k2161, k2226, k2232) were obtained; however only 5 were stables (k29, k317, k248, k284, k2232). These were selected to be isotyped, expanded in ascitic fluid, purified by protein-A column chromatography and then, they were titrated. Out of these five antibody-secretor hybridomas, clone k317 was the best to recognize (more specific) the MCLR toxins. Antibodies in hybridoma cell culture supernatant and purified ascites fluid were identified by ELISA assay (Enzyme Linked Immunosorbent Assay) as prior standardized. Even when sensitizing ELISA plate with different antigens, as MCLR-cBSA, MCLR, MCLR, MCRR, MCYR and MCLA, clone 17 presented the best linearity against microcystin variants. Therefore, the obtained clone 17 (isotype IgG1) is a promising clone and shall be used for detecting MCLR in drinking water through the development of a competitive ELISA immunoassay kit. In what refers to the polyclonal antibody, MCLR-mcKLH was used as immunization antigen, while MCLR-cBSA was used as sensitizing antigen for the IgG titration assay by indirect ELISA. In the sequence, a competition ELISA assay was standardized using the MCLR toxin as sensitizing antigen. This Casein method was standardized, validated and compared to the commercial kit Abraxis®. The competition ELISA kit using polyclonal antibody, known as Casein method, was analyzed concerning its Quantification Inferior Limit, Specificity, Selectivity, methanol influence of the assay, Recuperation, Linearity, Precision, Accuracy and Robustness. This screening method reached excellent results if compared to the commercial kit Abraxis®, for being able to detect both the microcystins variants and the nodularins in aquatic environmental. The competition ELISA assay using anti-MCLR polyclonal antibody was submitted to the grant of a patent by USP Innovation Agency (INPI 018090046230).

Anticorpo monoclonal

Anticorpo policlonal

Conjugação de peptídeos

ELISA

ELISA

Hibridoma

Hybridoma

Microcistina

Microcystin

Monoclonal antibody

Nodularin

Nodularina

Peptide conjugation

Polyclonal antibody

Investigating Cyanotoxin Production by Benthic Freshwater Cyanobacteria in New Zealand

Smith, Francine Mary Jorna

January 2012

Cyanobacteria can form nuisance proliferations and produce large concentrations of toxins that pose a health hazard. This thesis investigates cyanotoxin production by New Zealand benthic cyanobacteria. Cyanobacteria were sampled from lakes, reservoirs, streams, and rivers. Thirty-five strains were isolated into culture and screened for genes involved in the biosynthesis of common cyanotoxins. Positive results were confirmed and cyanotoxin concentrations quantified using analytical chemistry techniques. Genes involved in anatoxin a/homoanatoxin a biosynthesis were detected in nine out of ten Phormidium cf. uncinatum strains isolated from a single mat. Anatoxin a was confirmed in these strains by LC–MS/MS at concentrations from 0.3 to 6.4 mg kg⁻¹. One strain also produced homoanatoxin-a. Anatoxin-a variation between strains may explain the wide range in anatoxin a concentrations previously observed in New Zealand. The sxtA gene involved in saxitoxin biosynthesis was identified in Scytonema cf. crispum strains. Saxitoxin was confirmed in strains and environmental samples by Jellett PSP Rapid Test and HPLC–FD. Gonyautoxins, neosaxitoxin, and decarbamoyl derivatives were also detected. This study is the first identification of these compounds in Scytonema and in New Zealand cyanobacterial strains. These strains were isolated from recreational and pre-treatment drinking water reservoirs, highlighting the risk benthic cyanobacteria pose to human and animal health. Experiments were undertaken using cultures of Phormidium and Scytonema to determine how growth influences cyanotoxin production. The effects of iron and copper stress on P. autumnale were also investigated. High iron concentrations disrupted attachment mechanisms. Iron and copper had a significant effect on growth, without significantly affecting anatoxin a production. However, the maximum anatoxin a quota was consistently observed during early exponential growth. Scytonema cf. crispum produced higher saxitoxin quota throughout exponential growth than during the stationary phase. Both the Phormidium and Scytonema growth experiments indicate that high toxin quota can be expected early in benthic mat development, making early detection of these proliferations important.

cyanobacteria

cyanotoxins

anatoxin-a

cylindrospermopsin

microcystin

nodularin

saxitoxin

Phormidium

Scytonema

South Island

New Zealand

growth studies

periphyton

metaphyton

benthic algae.

Desenvolvimento de técnicas de imunoensaio para detecção de microcistina em amostras ambientais / Development of immunoassay techniques to detect microcystin in environmental samples

Fabyana Maria dos Anjos

15 December 2009

A contaminação da água para consumo humano por toxinas produzidas por cianobactérias é um problema de saúde pública e das autoridades em todo o mundo. Microcistina-LR (MCLR) é uma cianotoxina heptapeptídica cíclica que inibe as proteínas fosfatases PP1 E PP2A nos hepatócitos. Microcistinas são produzidas por diversos gêneros de cianobactérias e mais de 70 variações estruturais têm sido caracterizadas em florações naturais. Por serem haptenos, as microcistinas são incapazes de induzir uma resposta imune em animais. Conseqüentemente, foi necessário aplicar métodos de conjugação envolvendo a adição de uma proteína carreadora, mcKLH (cationized Keyhole Limpet Hemocyanin). Portanto, o objetivo inicial desta tese foi o de obter anticorpos monoclonal (em camundongos) e policlonal (em coelho) anti- MCLR. Com relação ao anticorpo monoclonal foram obtidos 9 hibridomas (k29, k210, k317, k248, k284, k290, k2161, k2226, k2232), sendo que apenas 5 se mostraram estáveis (k29, k317, k248, k284, k2232). Estes foram selecionados para serem isotipados, expandidos em líquido ascítico, purificados em coluna cromatográfica de proteína-A e titulados. Dentre estes cinco hibridomas secretores de anticorpos, o clone k317 foi o que melhor reconheceu (mais específico) a toxina MCLR. Os anticorpos do sobrenadante de meio de cultura do hibridoma e o fluido ascítico purificado foram identificados pelo ensaio ELISA (Enzyme Linked Immunosorbent Assay) previamente padronizado. Mesmo sensibilizando a placa de ELISA com diferentes antígenos, tais como MCLR-cBSA, MCLR, MCLR, MCRR, MCYR e MCLA, o clone 17 foi o que apresentou melhor linearidade frente às variantes de microcistina. Portanto, o clone 17 (isótipo IgG1) obtido é muito promissor e será usado para detecção de MCLR na água para consumo humano através do desenvolvimento de um kit de ELISA competição. Com relação ao anticorpo policlonal, o antígeno de imunização foi MCLR-mcKLH, enquanto que o antígeno de sensibilização foi MCLR-cBSA para o ensaio de titulação de anticorpos de classe IgG por ELISA indireto. Na seqüencia, foi padronizado um ensaio ELISA competição utilizando somente a toxina MCLR como antígeno de sensibilização. Este método Caseína foi padronizado, validado e comparado com o kit comercial Abraxis®. O kit ELISA competição que utiliza anticorpo policlonal, nomeado como método Caseína, foi avaliado quanto Limite Inferior de Quantificação, Especificidade, Seletividade, influência do metanol no ensaio, Recuperação, Linearidade, Precisão, Exatidão e Robustez. Este método de triagem apresentou excelente resultado quando comparado ao kit comercial Abraxis®, pois foi capaz de detectar tanto variantes de microcistinas como nodularinas no ambiente aquático. O ensaio ELISA competição utilizando anticorpo policlonal anti-MCLR foi submetido à patente pela Agência USP de Inovação (I.N.P.I. 018090046230). / The contamination of drinking water by cyanobacterial toxins is a public health issue and a concern for water authorities throughout the world. Microcystin-LR (MCLR) is a hazardous cyclic heptapeptide cyanotoxin, which inhibits protein phosphatase PP1 and PP2A in hepatocytes. Microcystins are produced by several genera of cyanobacteria and presents more than 70 structural variations characterized in natural blooms. As haptens, microcystins are unable to invoke an immune response in animals. Consequently, the application of conjugation methods with an additional carrier protein, the KLH (Keyhole Limpet Hemocyanin) was necessary. The main objective of this study was to obtain monoclonal (in mice) and polyclonal (in rabbits) antibodies for reacting against MCLR. In what refers to monoclonal antibodies, 9 hybridomas (k29, k210, k317, k248, k284, k290, k2161, k2226, k2232) were obtained; however only 5 were stables (k29, k317, k248, k284, k2232). These were selected to be isotyped, expanded in ascitic fluid, purified by protein-A column chromatography and then, they were titrated. Out of these five antibody-secretor hybridomas, clone k317 was the best to recognize (more specific) the MCLR toxins. Antibodies in hybridoma cell culture supernatant and purified ascites fluid were identified by ELISA assay (Enzyme Linked Immunosorbent Assay) as prior standardized. Even when sensitizing ELISA plate with different antigens, as MCLR-cBSA, MCLR, MCLR, MCRR, MCYR and MCLA, clone 17 presented the best linearity against microcystin variants. Therefore, the obtained clone 17 (isotype IgG1) is a promising clone and shall be used for detecting MCLR in drinking water through the development of a competitive ELISA immunoassay kit. In what refers to the polyclonal antibody, MCLR-mcKLH was used as immunization antigen, while MCLR-cBSA was used as sensitizing antigen for the IgG titration assay by indirect ELISA. In the sequence, a competition ELISA assay was standardized using the MCLR toxin as sensitizing antigen. This Casein method was standardized, validated and compared to the commercial kit Abraxis®. The competition ELISA kit using polyclonal antibody, known as Casein method, was analyzed concerning its Quantification Inferior Limit, Specificity, Selectivity, methanol influence of the assay, Recuperation, Linearity, Precision, Accuracy and Robustness. This screening method reached excellent results if compared to the commercial kit Abraxis®, for being able to detect both the microcystins variants and the nodularins in aquatic environmental. The competition ELISA assay using anti-MCLR polyclonal antibody was submitted to the grant of a patent by USP Innovation Agency (INPI 018090046230).

Anticorpo monoclonal

Anticorpo policlonal

Conjugação de peptídeos

ELISA

Hibridoma

Microcistina

Nodularina

ELISA

Hybridoma

Microcystin

Monoclonal antibody

Nodularin

Peptide conjugation

Polyclonal antibody