Alteration of Cylindrospermopsin Content of  &amp;lt;i&amp;gt;Aphanizomenon ovalisporum&amp;lt;/i&amp;gt; (Cyanobacteria, Nostocales) due to Step-Down from Combined Nitrogen to Dinitrogen

Vasas, Gábor; Surányi, Gyula; Bácsi, István; M-Hamvas, Márta; Máthé, Csaba; Gonda, Sándor; Borbély, György

doi:10.4236/aim.2013.38075

Cited by 9 publications

(5 citation statements)

References 43 publications

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“…Furthermore, intracellular CYN decreased in mixed cultures. These decreases are in accordance with our previous findings about CYN content changes of the used Chrysosporum strain under nutrient limitation [ 44 , 45 ]. The other potential reason of measuring low amount of extracellular CYN could be that due to the rich matrix particulate (but otherwise effective) CYN [ 17 ] occurred, which was not detectable by our capillary electrophoretic method developed for free dissolved CYN measurements.…”

Section: Discussionsupporting

confidence: 93%

“…The effects of abiotic factors on the production of CYN are quite well-known both from field studies [ 40 , 41 , 42 ], and from laboratory experiments (temperature [ 43 ]; phosphate-, sulphate-, and nitrate starvation [ 44 , 45 ]; and temperature and light intensity [ 46 , 47 ]. It seems, that extracellular CYN-content could change in a wide range due to different abiotic factors ( Cylindrospermopsis raciborskii : 39 × 10 −3 μg·mL −1 [ 48 ]; Chrysosporum ( Aphanizomenon ) gracile and C .…”

Section: Discussionmentioning

confidence: 99%

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Effects of Cylindrospermopsin Producing Cyanobacterium and Its Crude Extracts on a Benthic Green Alga—Competition or Allelopathy?

et al. 2015

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Cylindrospermopsin (CYN) is a toxic secondary metabolite produced by filamentous cyanobacteria which could work as an allelopathic substance, although its ecological role in cyanobacterial-algal assemblages is mostly unclear. The competition between the CYN-producing cyanobacterium Chrysosporum (Aphanizomenon) ovalisporum, and the benthic green alga Chlorococcum sp. was investigated in mixed cultures, and the effects of CYN-containing cyanobacterial crude extract on Chlorococcum sp. were tested by treatments with crude extracts containing total cell debris, and with cell debris free crude extracts, modelling the collapse of a cyanobacterial water bloom. The growth inhibition of Chlorococcum sp. increased with the increasing ratio of the cyanobacterium in mixed cultures (inhibition ranged from 26% to 87% compared to control). Interestingly, inhibition of the cyanobacterium growth also occurred in mixed cultures, and it was more pronounced than it was expected. The inhibitory effects of cyanobacterial crude extracts on Chlorococcum cultures were concentration-dependent. The presence of C. ovalisporum in mixed cultures did not cause significant differences in nutrient content compared to Chlorococcum control culture, so the growth inhibition of the green alga could be linked to the presence of CYN and/or other bioactive compounds.

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Section: Discussionsupporting

confidence: 93%

Section: Discussionmentioning

confidence: 99%

Effects of Cylindrospermopsin Producing Cyanobacterium and Its Crude Extracts on a Benthic Green Alga—Competition or Allelopathy?

et al. 2015

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“…While −N and +N cultures produced similar amounts of CYNs during their exponential growth phase, cells in −N cultures contained at least two times higher total CYNs at the end of the experiment. Our results contrast with findings for Aphanizomenon ovalisporum where the CYN content first decreased and then increased during exponential growth in cultures free of nitrogen, but never reached the content of cultures grown under combined nitrogen conditions [ 34 ]. One reason for this discrepancy could be that this study had not considered the extracellular CYN fraction, which can amount to 20%−50% on total CYN depending on strain and growth phase, as shown for Aphanizomenon ovalisporum strains as well as C. raciborskii [ 15 , 35 ].…”

Section: Resultscontrasting

confidence: 99%

“…An impact of nitrogen availability was observed in several Australian C. raciborskii strains with highest intracellular CYN contents in batch cultures free of nitrogen and intracellular CYN contents (per unit dry weight) varying at maximum by a factor of 2 [ 33 ]. In contrast, CYN content in Aphanizomenon ovalisporum was lower in cultures free of nitrogen compared to growth under combined nitrogen supply [ 34 ].…”

Section: Introductionmentioning

confidence: 99%

Nitrogen Limitation Promotes Accumulation and Suppresses Release of Cylindrospermopsins in Cells of Aphanizomenon Sp.

Preußel

Chorus

Fastner

2014

Toxins

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As the biosynthesis of cylindrospermopsin (CYN) is assumed to depend on nitrogen availability, this study investigated the impact of nitrogen availability on intra- and extracellular CYN and deoxy-CYN (D-CYN) contents in three Aphanizomenon strains from temperate waters. Nitrogen deficient (−N) cultures showed a prolonged growth phase and intracellular toxin accumulation by a factor of 2–6. In contrast, cultures with additional nitrate supply (+N) did not accumulate CYN within the cells. Instead, the maximum conceivable CYN release estimated for dead cells (identified by SYTOX® Green staining) was much lower than the concentrations of dissolved CYN actually observed, suggesting these cultures actively release CYN from intact cells. Furthermore, we found remarkably altered proportions of CYN to D-CYN: as batch cultures grew, the proportion of D-CYN increased by up to 40% in +N medium, whereas D-CYN remained constant or decreased slightly in −N medium. Since +N cultures showed similar toxin patterns as −P cultures with increased extracellular CYNs and higher proportion of D-CYN we conclude that nitrogen limitation may affect the way the cells economize resources, especially the yield from phosphorus pools, and that this has an impact on CYN production and release. For water management, these result imply that nutrient availability not only determines the abundance of potentially CYN-producing cyanobacteria, but also the amount of extracellular CYNs (challenging drinking-water treatment) as well as the ratio of D-CYN to CYN (affecting toxicity).

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“…We know that heterocyst frequency differs among species (perhaps because of differences in cell size as discussed above) and among strains grown under controlled conditions (this study and Nayak et al, 2007;Ahad et al, 2015). Frequency also varies with environmental factors such as incubation time (Vasas et al, 2013;Zulkefli and Hwang, 2020), calcium (Smith et al, 1987;Torecilla et al, 2004), Fe (Aly and Andrews, 2016), Ni (Rai and Raizada, 1986), inorganic N (Fogg, 1949;Ogawa and Carr, 1969;Rother and Fay 1979;Brown and Rutenberg, 2012;Mohlin et al, 2012;Zulkefli and Hwang, 2020), CO2 (Kulasooriya et al,1972;Kang et al, 2004;Masukawa et al, 2017), O2 (Kangatharalingam et al, 1992), light (Fogg, 1949) and temperature (Zakrisson and Larsson, 2014). This large number of known confounding variables (there may be others) makes it very difficult to assign relative importance to variables known to affect heterocyst frequencies.…”

Section: Potential For Co Limitation Of Heterocyst Frequency In Canad...mentioning

confidence: 99%

Low cobalt limits cyanobacteria heterocyst frequency in culture but potential for cobalt limitation of frequency in nitrogen-limited surface waters is unclear

Shah,

Venkiteswaran,

Molot

et al. 2023

Preprint

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1. Impacts of three cobalt (Co) concentrations were examined on heterocyst frequency and growth rate in four diazotrophic cyanobacteria species in nitrogen (N)-depleted culture and growth rate in one non-diazotrophic species in N-replete culture. After 11 days in batch culture, heterocyst frequency (HF, % of all cells that are heterocysts) increased from 4.1-5.7% to 5.4-7.4% to 5.9-9.3% at 0.17, 17 and 170 nmol L -1 Co, implicating Co in heterocyst differentiation. Growth rate was not significantly affected by Co in any of the species suggesting that the impact of low Co on other metabolic pathways was minimized.2. Stoichiometric extrapolation of culture results to N-limited natural systems with lower nutrient concentrations infers that HF could be limited by sub-nanomolar Co concentrations.3. In experimentally fertilized N-limited Lake 227, mean summer HF in 2000-2020 was 3.4% (epilimnion) and 4.0% (metalimnion). However, in 2017 (the only year for which Co data are available) dissolved Co increased from 0.7 to 2.0 nmol L -1 during the bloom simultaneously with increasing HF and cyanobacteria biomass, hence, Co probably did not limit HF and biomass. HF was significantly higher after 2015 following a shift in dominant bloom species from Aphanizomenon schindlerii to smaller A. skujae. The smaller cell size may have required a higher HF in order to maintain a relatively constant supply rate of fixed N per unit biomass.4. Surveys of ambient Co in over 280 aquatic systems across Canada and elsewhere indicate that Co is sometimes low enough to theoretically limit HF in N-limited waters. However, numerous variables influence HF so a clear understanding of relationships between Co and HF in natural systems remains elusive.

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Alteration of Cylindrospermopsin Content of <i>Aphanizomenon ovalisporum</i> (Cyanobacteria, Nostocales) due to Step-Down from Combined Nitrogen to Dinitrogen

Cited by 9 publications

References 43 publications

Effects of Cylindrospermopsin Producing Cyanobacterium and Its Crude Extracts on a Benthic Green Alga—Competition or Allelopathy?

Effects of Cylindrospermopsin Producing Cyanobacterium and Its Crude Extracts on a Benthic Green Alga—Competition or Allelopathy?

Nitrogen Limitation Promotes Accumulation and Suppresses Release of Cylindrospermopsins in Cells of Aphanizomenon Sp.

Low cobalt limits cyanobacteria heterocyst frequency in culture but potential for cobalt limitation of frequency in nitrogen-limited surface waters is unclear

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