Fuyuko Yoshida

Acute oral toxicity of microcystin-LR, a cyanobacterial hepatotoxin, in mice

Microcystin-LR (MCLR) is a hepatotoxic peptide produced by Microcystis aeruginosa, an alga found worldwide in reservoirs for drinking supply; however, acute oral toxicity of purified MCLR remains unknown. Therefore, a single dose of MCLR (more than 95% purity) ranging from 8.0 to 20.0 mg/kg body weight was orally given to female 6-week old BALB/c mice, and lethality and pathological changes were observed. Median lethal dose (LD50) of the orally given MCLR estimated by the up and down method was 10.9 mg/kg, which was 167 times higher than the i.p. LD50 value (65.4 microgram/kg by moving average method). Orally administrated toxin caused primarily hepatocellular injuries with characteristics of hemorrhage and necrosis. In situ end-labeling as well as electron microscopic observation revealed an induction of apoptotic cell death to hepatocytes. These results indicate the lethality of MCLR was much lower in oral dosage than by i.p. administration, but toxic effects are similar. In addition, apoptosis is considered one of major components in MCLR-induced hepatotoxicity.

Survey of microcystins in environmental water by a highly sensitive immunoassay based on monoclonal antibody

By using a highly sensitive enzyme-linked immunosorbent assay (ELISA) based on a monoclonal antibody, microcystin (MC) concentration was analyzed in environmental water samples (total, 134), collected in 1993-1995 from ponds, lakes, reservoirs, and rivers in Japan, Thailand, Germany, and Portugal. MCs detected in the water samples filtered over a glass filter were designated as free MCs, and those samples that were freeze-thawed twice before the filtration were designated as total MCs. MCs (> 50 pg/ml) were detected in 14 of 24 samples collected from the lakes that were used as recreation and water supply in Japan in different regions. In the MC-positive samples, the concentration of free MCs was only a few percentages of the total MCs, indicating that the most part of MCs found in the water samples was present in algal cells. An additional trial on 33 samples collected continuously from Lake Inbanuma, Japan, during June-September 1994-1995 revealed that the total MCs were in a range of 52-52,000 pg/ml. In Chiang Mai, Thailand, 6 of 10 samples were positive, with the mean and highest of 161 and 354 pg/ml, respectively. In the Frankfurt area. Germany, 4 of 10 and 7 of 8 samples collected in the same lakes for recreation in July 1993 and November-December 1994 showed the presence of MCs, with their mean and highest values of 257 and 407 pg/ml, respectively. Another survey of MCs in dense bloomed samples collected with plankton net revealed a contamination of MCs up to 36,000 pg/ml. In Portugal, 28 of 29 samples from 4 lakes, 20 rivers, and 5 reservoirs were positive for MCs, with the respective means of 13,664, 11,048, and 2,278 pg/ml. These data indicated that MCs contaminate environmental water in ponds, rivers, lakes, and reservoirs worldwide. The present ELISA is considered to be a reliable tool for the mass monitoring and risk assessment of MCs in water supplies.

No Chronic oral toxicity of a low dose of microcystin-LR, a cyanobacterial hepatotoxin, in female BALB/c mice

Chronic oral toxicity of a low dose of microcystin‐LR (MCLR) was examined in female BALB/c mice for 18 months. Six‐week‐old female mice received 20 μg/L of the toxin in drinking water, which is about 200‐fold higher than the level in contaminated drinking water. Control mice received water alone. Mortality, clinical signs, body weights, and food and water consumptions were recorded during the study. Examinations on hematology, serum biochemistry, necropsy, organ weights, and histopathology were performed at months, 3, 6, 12, and 18. The immunohistochemical distribution of MCLR was examined in the liver at these time points. Mean cumulative MCLR intake after 18 months was estimated at 35.5 μg per mouse. The present test indicates that administration of a low dose of MCLR in drinking water resulted in neither chronic toxicity nor accumulation of the toxin in the liver. Based on previous epidemiological studies and the present chronic toxicity test, we recommend 0.01 μg/L as an maximum acceptable level for microcystins in drinking water, applying a safety factor of more than 1000. ©1999 John Wiley & Sons, Inc. Environ Toxicol 14: 45–55, 1999

A new type sandwich immunoassay for microcystin: production of monoclonal antibodies specific to the immune complex formed by microcystin and an anti-microcystin monoclonal antibody

To develop an ultrasensitive immunoassay for microcystins (MCs), a group of heptapeptide hepatotoxins produced by cyanobacteria, we produced monoclonal antibodies (MAbs) which specifically recognize the immune complex (IC) formed by an anti-MC MAb (MC MAb) and MCs. The use of the anti-IC MAb (IC MAb) as the secondary antibody made it possible to develop a sandwich type immunoassay, which is theoretically superior to the widely used competitive immunoassay in sensitivity as well as accuracy. A MC MAb mixed with microcystin-LR (MCLR) to form the IC was immunized to mice. Three IC MAbs were obtained, all of which specifically reacted with the IC, but almost never reacted to MC MAb or MCLR in enzyme-linked immunosorbent assays (ELISAs). Binding kinetics study of one of the IC MAbs, 3F7, by a BIAcore biosensor technique revealed that 3F7 IC MAb could associate with free MC MAb as well as the IC, but the binding to free MC MAb was much more easily dissociated than that to the IC, thus resulting in about 300-fold higher affinity of 3F7 for the IC than for MC MAb alone (1.8 x 10(9) M(-1) and 4.6 x 10(6) M(-1) for the IC and MC MAb, respectively). Finally, 3F7 IC MAb was shown to react with the IC formed by the addition of MCLR to MC MAb-coated plates in a dose-dependent manner. Therefore, a new type sandwich immunoassay, anti-immune complex ELISA (IC ELISA) for MCs, was indeed established. The detection limit of the IC ELISA was 2 pg of MCLR ml(-1) (50 fg per assay), making it the most sensitive of all the methods for detecting MCs reported to date.

Survey of microcystins in water between 1995 and 1996 in Paraná, Brazil using ELISA.

An enzyme-linked immunosorbent assay (ELISA) based on a monoclonal antibody was used to determine microcystin (MC) concentrations in water supplies and water plant samples collected between November 1995 and October 1996, from five regions of Paraná, Brazil. In addition, the presence of Microcystis sp. was monitored. Of the 50 samples obtained, 12 were from an urban lake, 8 from human water supplies, 10 from recreational lakes, 13 from farm waters used for animal pasture and 7 from aquaculture facilities. M. aeruginosa was positive in all locations. MCs were positive (>50 pg ml(-1)) in 9 samples (2 samples from human water supplies, 5 from recreational lakes and 2 from animal pasture). Heavy contamination with MCs was observed in water samples collected in May 1996 from 2 recreation (swimming-fishing sites at Itaipu dam, 6380 and 10,000 pg ml(-1)) and human supplies (6627 pg ml(-1)) samples. At these sites, a large bloom of Microcystis sp. was detected. Treatment with 1 ppm Cl- reduced MCs levels, although 267 pg ml(-1) remained in the water plant samples. Our data showed frequent occurrence of Microcystis sp., which may be a hazard to humans and animals in the state of Paraná. More detailed investigations are required to evaluate the risk of natural MC contamination in the water supplied in this region.

Anti-idiotype monoclonal antibodies against anti-microcystin antibody and their use in enzyme immunoassay

Microcystins (MCs), a group of heptapeptide hepatotoxins produced by cyanobacteria, are suspected as tumor-promoter contaminants of environmental water. We have previously developed an enzyme-linked immunosorbent assay (ELISA) for MCs based on an anti-MC MAb (MAb-mc). We describe here the production of anti-idiotype MAbs (MAb-ids) which react with MAb-mc and their use in a new ELISA for MCs. For the production of MAb-id, hybridoma cells were generated from mice immunized with MAb-mc. Two MAbs were selected for their ability to inhibit the binding of MAb-mc to microcystin-LR (MCLR)-bovine serum albumin conjugate in ELISA. The one with the higher inhibitory activity, designated Id7 (IgG1, kappa), was further characterized. ELISA and immunoprecipitation analysis revealed that Id7 specifically bound to MAb-mc but not to control IgG1, and the binding was inhibited by free MCLR. Therefore, Id7 is a MAb-id to MAb-mc and potentially possesses the structural image of MCLR. To establish MAb-id based ELISA, Id7 was tested for use in three types of competitive ELISA for MCs. The best format enabled reliable measurements of MCLR in the range of 100-1000 pg/ml with a coefficient of variation of less than 3%. In addition, microcystin-RR and microcystin-YR, principal MCs found in environmental water, were cross-reacted well (67-111% of MCLR) in the ELISA although 6(Z)-MCLR, a minor component, was less reactive (7% of MCLR). A comparative study of the MAb-id based ELISA with previously established MAb-mc based ELISA revealed good correlation (n = 14, r = 0.97) between the two methods for measurements of MCs content in freshwater samples. Thus, developed MAb-id based ELISA is an useful alternative for environmental monitoring of MCs.

Development and Application of Highly Sensitive Anti-immune Complex ELISAs for Microcystins in Tap Water

We developed an anti-immune complex (IC) ELISA applicable to direct determination of trace amounts of microcystins (MCs) in tap water. Comparison of two assay formats revealed that the use of anti-immune complex monoclonal antibody (MAB) in the coating step to trap anti-MC MABMC complexes improved the sensitivity as well as precision. The detection limit and quantitative range of the IC ELISA was 2 pg ml−1 and 2100 pg ml−1 of microcystinLR (MCLR), respectively, indicating the most sensitive of all the methods for detecting MCs reported to date. Additionally, the IC ELISA maintained good reliability through its quantitative range, as evidenced by low coefficients of variation (5.010.8 and 4.910.2% for intra- and interassay, respectively). The IC ELISA showed good cross-reactivity to microcystin-RR and microcystin-YR, suggesting major MCs found in the environment can be detected by this method. Recovery tests in which quantitative range of MCLR were added to tap water resulted in a mean recovery of 99%, with a mean standard deviation of 5.7%; therefore the IC ELISA performed well in the analysis of tap water samples. ELISA analysis of tap water samples collected in China and Japan revealed that, among 17 samples tested, two samples collected in China were positive for MCs at 4.914 pg ml−1. These results suggest that the newly developed IC ELISA can be used to monitor trace amounts of MCs in tap water.