BMAA-protein interactions: A possible new mechanism of toxicity.

ß-N-methylamino-L-alanine (BMAA) has been shown to accumulate in organisms by associating with host proteins. It has been proposed that this association is the result of misincorporation of BMAA into the primary structure of proteins, specifically in the place of L-serine, and that this misincorporation causes protein misfolding resulting in the tangle formation typically associated with neurodegenerative diseases. However, more recent studies have questioned the validity of the BMAA misincorporation hypothesis. Furthermore, BMAA association with proteins in the absence of de novo protein synthesis has been demonstrated although the nature of these associations has not yet been characterized. We therefore sought to investigate the effects of these undescribed interactions on protein functioning, and to identify the site(s) of these interactions. We present data here to show that BMAA can inhibit the activity of certain enzymes, interfere with protein folding in the absence of de novo protein synthesis, and associate in vitro with commercial proteins to such an extent that it cannot be removed by protein precipitation or denaturation. Based on the observed effects of these interactions on protein functioning, we suggest that this might constitute an additional mechanism of toxicity that could help to explain the role of BMAA in the development of neurodegenerative diseases.

ß-N-Methylamino-L-Alanine Toxicity in PC12: Excitotoxicity vs. Misincorporation.

The implication of ß-N-methylamino-L-alanine (BMAA) in the development of neurodegenerative diseases worldwide has led to several investigations of the mechanism, or mechanisms, of toxicity of this cyanobacterially produced amino acid. The primary mechanism of toxicity that was identified is excitotoxicity, with a second possible mechanism, the misincorporation of BMAA into the primary protein structure and consequent cell damage, having been more recently reported. However, studies on excitotoxicity and misincorporation have been conducted independently and there are therefore no data available on the relative contribution of each of these mechanisms to the total toxicity of BMAA. The rat pheochromocytoma cell line PC12 is an ideal model for a study of this type, as glutamate receptor expression is modified by cell differentiation, which can be affected by exposure to nerve growth factor. In this study, the PC12 cell line was evaluated as a model to study BMAA toxicity via the two proposed mechanisms: excitotoxicity and protein misincorporation. BMAA and canavanine treatment of cultures of PC12 were evaluated for depolarization of the mitochondrial membrane. In canavanine-treated cultures, this was evident after 9 days of treatment and was attributed to the primary mechanism of canavanine toxicity, protein misincorporation. However, no membrane depolarization was observed for BMAA-treated cultures even after 21 days of continuous treatment at 500 µM. Short-term exposure to both BMAA and canavanine resulted in a slight increase in necrosis in undifferentiated cells that was prevented in canavanine-treated cultures by co-incubation with arginine, but not in BMAA-treated cultures by co-incubation with serine. A slight increase in apoptosis was observed in undifferentiated cells treated with either BMAA or glutamate, and ROS production increased in glutamate-treated cells. However, the excitotoxicity was less pronounced than reported in previous studies with neuronal cells. In contrast, apoptosis was greatly increased in both BMAA- and glutamate-treated cells after differentiation and resulting mGluR1 increase, indicating that excitotoxicity is the main, if not only, mechanism of toxicity in PC12.

Environmental modulation of microcystin and ß-N-methylamino-L-alanine as a function of nitrogen availability.

The most significant modulators of the cyanotoxins microcystin and ß-N-methylamino-L-alanine in laboratory cyanobacterial cultures are the concentration of growth-medium combined nitrogen and nitrogen uptake rate. The lack of field studies that support these observations led us to investigate the cellular content of these cyanotoxins in cyanobacterial bloom material isolated from a freshwater impoundment and to compare these to the combined nitrogen availability. We established that these toxins typically occur in an inverse relationship in nature and that their presence is mainly dependent on the environmental combined nitrogen concentration, with cellular microcystin present at exogenous combined nitrogen concentrations of 29 µM and higher and cellular BMAA correlating negatively with exogenous nitrogen at concentrations below 40 µM. Furthermore, opposing nutrient and light gradients that form in dense cyanobacterial blooms may result in both microcystin and BMAA being present at a single sampling site.

Nitrogen starvation of cyanobacteria results in the production of ß-N-methylamino-L-alanine.

ß-N-Methylamino-L-alanine, an unusual amino acid implicated in neurodegenerative disease, has been detected in cultures of nearly all genera of environmentally ubiquitous cyanobacteria tested. The compound is present within cyanobacterial cells in free and protein-associated forms, with large variations occurring in the concentration of these pools between species as well as within single strains. With a lack of knowledge and supporting data on the regulation of BMAA production and the role of this compound in cyanobacteria, the association between BMAA and cyanobacteria is still subject to debate. In this study we investigated the biosynthesis of BMAA in axenic non-diazotrophic cyanobacterial cultures using the stable isotope ¹5N. Nitrogen starvation of nutritionally replete cells resulted in an increase in free cellular ¹5N BMAA suggesting that BMAA may be the result of catabolism to provide nitrogen or that BMAA is synthesised to serve a functional role in the cell in response to nitrogen deprivation. The addition of NO3⁻ and NH4⁺ to the culture medium following starvation resulted in a decrease of free cellular BMAA without a corresponding increase in the protein-associated fraction. The use of ammonia as a nitrogen source resulted in a more rapid reduction of BMAA when compared to nitrate. This study provides the first data regarding the regulation of intracellular BMAA concentrations in cyanobacteria with results conclusively showing the production of ¹5N BMAA by an axenic cyanobacterial culture.

Distinguishing the cyanobacterial neurotoxin ß-N-methylamino-L-alanine (BMAA) from other diamino acids.

ß-N-methylamino-L-alanine (BMAA) is produced by diverse taxa of cyanobacteria, and has been detected by many investigators who have searched for it in cyanobacterial blooms, cultures and collections. Although BMAA is distinguishable from proteinogenic amino acids and its isomer 2,4-DAB using standard chromatographic and mass spectroscopy techniques routinely used for the analysis of amino acids, we studied whether BMAA could be reliably distinguished from other diamino acids, particularly 2,6-diaminopimelic acid which has been isolated from the cell walls of many bacterial species. We used HPLC-FD, UHPLC-UV, UHPLC-MS, and triple quadrupole tandem mass spectrometry (UHPLC-MS/MS) to differentiate BMAA from the diamino acids 2,6-diaminopimelic acid, N-2(amino)ethylglycine, lysine, ornithine, 2,4-diaminosuccinic acid, homocystine, cystine, tryptophan, as well as other amino acids including asparagine, glutamine, and methionine methylsulfonium.

The effect of ß-N-methylamino-L-alanine (BMAA) on oxidative stress response enzymes of the macrophyte Ceratophyllum demersum.

Cyanobacteria are known to produce bioactive secondary metabolites such as hepatotoxins, cytotoxins and neurotoxins. The newly recognized neurotoxin ß-N-methylamino-L-alanine (BMAA) is a naturally occurring non-protein amino acid found in the majority of cyanobacterial genera tested. Evidence that exists for implication of BMAA in neurodegenerative disorders relies on bioaccumulation and biomagnification from symbiotic cyanobacteria. Uptake and accumulation of free BMAA by various non-symbiotic organisms, including aquatic macrophytes, has been documented but to date limited evidence of ecotoxicology exists. We therefore investigated the effect of BMAA on the oxidative stress responses of the macrophyte, Ceratophyllum demersum. Markers for oxidative stress in this study are the antioxidative enzymes superoxide dismutase, catalase, guaiacol peroxidase, glutathione peroxidase and glutathione reductase. We found that BMAA had an inhibitory effect on all the oxidative stress response enzymes tested in plants exposed to BMAA. However enzymes not related to oxidative stress response were not affected by BMAA in in vitro experiments. Binding studies in the presence of BMAA showed reduced enzyme specific activity over time compared to the control. This study shows that BMAA causes oxidative stress indirectly as it inhibits antioxidant enzymes required to combat reactive oxygen species that cause damage to cells. Further investigations are required to fully understand the inhibitory effect of BMAA on these enzymes.

ß-N-Methylamino-L-alanine (BMAA) uptake by the aquatic macrophyte Ceratophyllum demersum.

Free-living freshwater cyanobacteria contain BMAA in both free cellular and protein-associated forms. Free BMAA released on bloom collapse or during cellular turnover creates a potential source of the non-proteinogenic amino acid for bioaccumulation and biomagnification in aquatic ecosystems. Uptake of free amino acids is well documented in macrophytes and the potential for aquatic macrophytes to bioaccumulate BMAA therefore poses a potential threat where such macrophytes constitute a food source in an ecosystem. BMAA uptake and accumulation by the aquatic macrophyte Ceratophyllum demersum was therefore investigated. Rapid uptake of significant amounts of BMAA was observed in C. demersum. Both free and protein-associated BMAA were observed with protein association following accumulation of free BMAA. The protein association suggests potential biomaccumulation by aquatic macrophytes and offers a possibility of phytoremediation for BMAA removal.

Distinguishing the cyanobacterial neurotoxin beta-N-methylamino-L-alanine (BMAA) from its structural isomer 2,4-diaminobutyric acid (2,4-DAB).

The cyanobacterial neurotoxin beta-N-methylamino-L-alanine (BMAA) has been associated with certain forms of progressive neurodegenerative disease, including sporadic Amyotrophic Lateral Sclerosis and Alzheimer's disease. Reports of BMAA in cyanobacterial blooms from lakes, reservoirs, and other water resources continue to be made by investigators in a variety of laboratories. Recently it was suggested that during analysis BMAA may be confused with its structural isomer 2,4-diaminobutyric acid (2,4-DAB), or that current detection methods may mistake other compounds for BMAA. We here review the evidence that BMAA can be consistently and reliably separated from 2,4-DAB during reversed-phase HPLC, and that BMAA can be confidently distinguished from 2,4-DAB during triple quadrupole LC-MS/MS analysis by i) different retention times, ii) diagnostic product ions resulting from collision-induced dissociation, and iii) consistent ratios between selected reaction monitoring (SRM) transitions. Furthermore, underivatized BMAA can be separated from 2,4-DAB with an amino acid analyzer with post-column visualization using ninhydrin. Other compounds that may be theoretically confused with BMAA during chloroformate derivatization during GC analysis are distinguished due to their different retention times.

Beta-N-methylamino-L-alanine (BMAA) in novel South African cyanobacterial isolates.

Beta-N-methylamino-L-alanine (BMAA) is a neurotoxic non-proteinogenic amino acid reportedly produced by the majority of cyanobacterial isolates. A novel method was developed for the detection of BMAA in biological samples. Cultures representing the taxonomic diversity and geographic distribution in Southern Africa were collected and made uni-algal by standard methods before analysis for the presence of both free and protein-associated BMAA. Protein-associated BMAA was released by acid hydrolysis in an inert atmosphere. Samples were analyzed by gas chromatography-mass spectrometry (GC-MS) with pre-derivatization of amino acids using Phenomonex EZ:faast of the tested cultures, 96% were positive for BMAA although several were below the limit for quantification. BMAA presence was not related to the geographic origin or taxonomy of isolates and no correlation between free and bound BMAA concentrations was observed within or between taxonomic groups. These data offer the first confirmation of the taxonomic and geographic ubiquity of BMAA in freshwater cyanobacteria.

Medium N:P ratios and specific growth rate comodulate microcystin and protein content in Microcystis aeruginosa PCC7806 and M. aeruginosa UV027.

Hepatotoxin production in cyanobacteria has been shown to correlate to external stimuli such as light and nutrient concentrations and ratios, although conflicting results have been reported. Specific growth rates and protein and microcystin content of M. aeruginosa PCC7806 and M. aeruginosa UV027 were determined under nonlimiting batch culture conditions for a range of medium nitrogen and phosphorous atomic ratios. Both strains exhibited a similar optimal medium N:P ratio for increased cellular microcystin levels. Additionally, total cellular protein content and intracellular microcystin content were significantly correlated to each other (r2 = 0.81, p < 0.001). Microcystin and protein content increased considerably as the maximum specific growth rate for the experimental conditions was reached. The significant correlation of cellular protein and microcystin content and their relative increase with increasing specific growth rate, within defined ranges of medium N:P ratios, suggest a close association between microcystin production and N:P ratio-dependent assimilation of nitrogen, and resulting total cellular protein levels, which may be further modulated by specific growth rate.

Microcystin content of Microcystis aeruginosa is modulated by nitrogen uptake rate relative to specific growth rate or carbon fixation rate.

Modulation of microcystin production has been extensively studied in both batch and continuous cultures. Positive correlations with medium nitrogen, medium phosphorous, light intensity, inorganic carbon availability, and growth rate have been reported. Negative correlations have been reported between microcystin content and medium phosphorous. The only reported quantitative relationship between any variable and microcystin production was that of growth rate. Microcystis aeruginosa PCC7806 was therefore cultured under continuous culture conditions in a bubble-lift reactor at a growth rate of 0.01 h(-1) in modified BG11 (constant phosphate concentration of 0.195 mM and varying nitrate from 0.125 to 18 mM) and sampled at steady states for analysis of cell number, microcystin content, cellular N and P, residual medium nutrient concentration, and carbon fixation rate. Cellular microcystin quotas showed significant positive correlation with both nitrate uptake and cellular nitrogen content and were negatively correlated with carbon fixation rate, phosphate uptake, and cellular phosphorous. Thus, the ratio of nitrate uptake to phosphate uptake, cellular N to cellular P, and nitrate uptake to carbon fixation were positively correlated to cellular microcystin. Microcystin quotas increased 10-fold from the lowest to the highest steady-state values. Cellular microcystin content therefore is controlled to a significant extent by variables other than growth rate, as was previously reported, with nitrogen the most significant modulator. Batch culture in BG11 under identical conditions yielded increased microcystin when nitrogen uptake exceeded relative growth rate, confirming the importance of nitrogen uptake in the modulation of microcystin content for a specific growth rate.

An alternative PCR assay for quantifying mitochondrial DNA in crude preparations.

A method is described for the quantification of mitochondrial DNA present in crude biological preparations. A known copy number of a standard is amplified in the presence of inactivated target DNA so as to determine the overall efficiency of the PCR process in a particular sample. In this way any inhibitory and/or stimulatory substances present in sample preparations can be taken into account. To reduce tube-to-tube variations product DNA quantification is limited to small cycle numbers. Using this method quantitations of DNA amounts in different crude preparations can be compared.

A role for mitochondrial DNA in the pathogenesis of radiation-induced myelodysplasia and secondary leukemia.

The onset of acute myeloid leukemia following ionizing radiation or alkylating agent exposure is antedated months to years by the development of 'preleukemia', or secondary myelodysplastic syndrome (sMDS). Mitochondrial abnormalities induced by chloramphenicol and clonal deletions of mitochondrial DNA (mt DNA) in the bone marrow create hematological defects similar to sMDS, and abnormal dimers of mt DNA are observed in acute leukemia. This suggests a role for mt DNA in the pathogenesis of sMDS and secondary leukemia. We outline disparate experimental evidence to support this concept and suggest a role for select protease inhibitors in the clinical management of this disorder.