Growth inhibition of bloom-forming cyanobacterium Microcystis aeruginosa by rice straw extract

AIMS: To inhibit the growth of the bloom-forming cyanobacterium Microcystis aeruginosa using a rice straw extract. METHODS AND RESULTS: The cell numbers of the algal strain M. aeruginosa UTEX 2388 significantly decreased after treatment with different concentrations (0.01, 0.1, 1 and 10 mg l(-1)) of a rice straw extract for an 8-day cultivation period. Among seven tested allelochemicals from rice straw, salicylic acid at 0.1 mg l(1) exhibited the highest allelopathic activity (26%) on day 8. A synergistic effect on algal growth inhibition was found when adding two or three phenolic compounds from the rice straw. CONCLUSIONS: The growth of M. aeruginosa was inhibited by rice straw extract concentrations ranging from 0.01 to 10 mg l(1). This activity was due to the synergistic effects of various phenolic compounds in the rice straw. SIGNIFICANCE AND IMPACT OF THE STUDY: The identification of rice straw as an effective material for the growth inhibition of M. aeruginosa implies it may have the potential to be used as an environment-friendly biomaterial for controlling the algal bloom of M. aeruginosa in eutrophic water.     

Intraspecific variation in growth and morphology of the bloom-forming cyanobacterium Microcystis aeruginosa

In the laboratory, we documented large variation in the morphology, toxicity, and maximum population growth rates for 32 Microcystis aeruginosa strains isolated from 12 lakes. Growth rates and mean colony sizes varied significantly across strains and were positively correlated. However, growth rates were unrelated to toxin production.     

Comparative protein expression in different strains of the bloom-forming cyanobacterium Microcystis aeruginosa

Toxin production in algal blooms presents a significant problem for the water industry. Of particular concern is microcystin, a potent hepatotoxin produced by the unicellular freshwater species Microcystis aeruginosa. In this study, the proteomes of six toxic and nontoxic strains of M. aeruginosa were analyzed to gain further knowledge in elucidating the role of microcystin production in this microorganism. This represents the first comparative proteomic study in a cyanobacterial species. A large diversity in the protein expression profiles of each strain was observed, with a significant proportion of the identified proteins appearing to be strain-specific. In total, 475 proteins were identified reproducibly and of these, 82 comprised the core proteome of M. aeruginosa. The expression of several hypothetical and unknown proteins, including four possible operons was confirmed. Surprisingly, no proteins were found to be produced only by toxic or nontoxic strains. Quantitative proteome analysis using the label-free normalized spectrum abundance factor approach revealed nine proteins that were differentially expressed between toxic and nontoxic strains. These proteins participate in carbon-nitrogen metabolism and redox balance maintenance and point to an involvement of the global nitrogen regulator NtcA in toxicity. In addition, the switching of a previously inactive toxin-producing strain to microcystin synthesis is reported.     

Colony formation in the cyanobacterium Microcystis

Morphological evolution from a unicellular to multicellular state provides greater opportunities for organisms to attain larger and more complex living forms. As the most common freshwater cyanobacterial genus, Microcystis is a unicellular microorganism, with high phenotypic plasticity, which forms colonies and blooms in lakes and reservoirs worldwide. We conducted a systematic review of field studies from the 1990s to 2017 where Microcystis was dominant. Microcystis was detected as the dominant genus in waterbodies from temperate to subtropical and tropical zones. Unicellular Microcystis spp. can be induced to form colonies by adjusting biotic and abiotic factors in laboratory. Colony formation by cell division has been induced by zooplankton filtrate, high Pb²⁺ concentration, the presence of another cyanobacterium (Cylindrospermopsis raciborskii), heterotrophic bacteria, and by low temperature and light intensity. Colony formation by cell adhesion can be induced by zooplankton grazing, high Ca²⁺ concentration, and microcystins. We hypothesise that single cells of all Microcystis morphospecies initially form colonies with a similar morphology to those found in the early spring. These colonies gradually change their morphology to that of M. ichthyoblabe, M. wesenbergii and M. aeruginosa with changing environmental conditions. Colony formation provides Microcystis with many ecological advantages, including adaption to varying light, sustained growth under poor nutrient supply, protection from chemical stressors and protection from grazing. These benefits represent passive tactics responding to environmental stress. Microcystis colonies form at the cost of decreased specific growth rates compared with a unicellular habit. Large colony size allows Microcystis to attain rapid floating velocities (maximum recorded for a single colony, ∼ 10.08 m h⁻¹) that enable them to develop and maintain a large biomass near the surface of eutrophic lakes, where they may shade and inhibit the growth of less‐buoyant species in deeper layers. Over time, accompanying species may fail to maintain viable populations, allowing Microcystis to dominate. Microcystis blooms can be controlled by artificial mixing. Microcystis colonies and non‐buoyant phytoplankton will be exposed to identical light conditions if they are evenly distributed over the water column. In that case, green algae and diatoms, which generally have a higher growth rate than Microcystis, will be more successful. Under such mixing conditions, other phytoplankton taxa could recover and the dominance of Microcystis would be reduced. This review advances our understanding of the factors and mechanisms affecting Microcystis colony formation and size in the field and laboratory through synthesis of current knowledge. The main transition pathways of morphological changes in Microcystis provide an example of the phenotypic plasticity of organisms during morphological evolution from a unicellular to multicellular state. We emphasise that the mechanisms and factors influencing competition among various close morphospecies are sometimes paradoxical because these morphospecies are potentially a single species. Further work is required to clarify the colony‐forming process in different Microcystis morphospecies and the seasonal variation in this process. This will allow researchers to grow laboratory cultures that more closely reflect field morphologies and to optimise artificial mixing to manage blooms more effectively.     

Cultivation and characterization of the MaMV-DC cyanophage that infects bloom-forming cyanobacterium Microcystis aeruginosa

The MaMV-DC cyanophage, which infects the bloom-forming cyanobacterium Microcystis aeruginosa, was isolated from Lake Dianchi, Kunming, China. Twenty-one cyanobacterial strains were used to detect the host range of MaMV-DC. Microcystic aeruginosa FACHB-524 and plaque purification were used to isolate individual cyanophages, and culturing MaMV-DC with cyanobacteria allowed us to prepare purified cyanophages for further analysis. Electron microscopy demonstrated that the negatively stained viral particles are tadpole-shaped with an icosahedral head approximately 70 nm in diameter and a contractile tail approximately 160 nm in length. Using one-step growth experiments, the latent period and burst size of MaMV-DC were estimated to be 24–48 hours and approximately 80 infectious units per cell, respectively. Restriction endonuclease digestion and agarose gel electrophoresis were performed using purified MaMV-DC genomic DNA, and the genome size was estimated to be approximately 160 kb. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) analysis revealed four major structural proteins. These results support the growing interest in using freshwater cyanophages to control bloom-forming cyanobacterium.     

Local expansion of a panmictic lineage of water bloom-forming cyanobacterium Microcystis aeruginosa

In previous studies, we have demonstrated that the population structure of the bloom-forming cyanobacterium Microcystis aeruginosa is clonal. Expanded multilocus sequence typing analysis of M. aeruginosa using 412 isolates identified five intraspecific lineages suggested to be panmictic while maintaining overall clonal structure probably due to a reduced recombination rate between lineages. Interestingly, since 2005 most strains belonging to one of these panmictic clusters (group G) have been found in a particular locality (Lake Kasumigaura Basin) in Japan. In this locality, multiple, similar but distinct genotypes of this lineage predominated in the bloom, a pattern that is unprecedented for M. aeruginosa. The population structure underlying blooms associated with this lineage is comparable to epidemics of pathogens. Our results may reveal an expansion of the possible adaptive lineage in a localized aquatic environment, providing us with a unique opportunity to investigate its ecological and biogeographical consequences.     

Ecological dynamics of the toxic bloom-forming cyanobacterium Microcystis aeruginosa and its cyanophages in freshwater

The abundance of potentially Microcystis aeruginosa-infectious cyanophages in freshwater was studied using g91 real-time PCR. A clear increase in cyanophage abundance was observed when M. aeruginosa numbers declined, showing that these factors were significantly negatively correlated. Furthermore, our data suggested that cyanophage dynamics may also affect shifts in microcystin-producing and non-microcystin-producing populations.     

PCR primers for selective detection of intra-species variations in the bloom-forming cyanobacterium,Microcystis

Members of the cyanobacterial genus Microcystis commonly form blooms in eutrophic freshwater systems, and some produce cyclic heptapeptide hepatotoxins called microcystins, thereby often causing serious water management problems. Microcystis species were unified into the single Microcystis aeruginosa classification based on 16S rRNA gene sequences and DNA–DNA re-association experiments; however, the morphological features of the organisms differ in different culturing conditions. Here, we describe a new real-time quantitative PCR (qPCR) method of determining Microcystis intradiversity using the SYBR Green I assay. We analyzed 71 Microcystis 16S-23S rDNA internal transcribed spacer region (16S-23S ITS) sequences, designed three group-specific PCR primers that successfully selected a morphologically M. wesenbergii-like non-toxic group (Group-3), and differentiated between M. viridis-like toxic group (Group-4) and M. aeruginosa-like Group-1 organisms including toxic and non-toxic Microcystis strains. The primers covered 76% of the Microcystis 16S-23S ITS regions from all over the world (six continents) included in GenBank. We constructed a mixed culture with representative Microcystis strains from each group, and estimated their cell densities by qPCR over 7 weeks. Group-1 and Group-3 grew exponentially for 4 weeks; however, the growth of Group-4 declined after 2 weeks, revealing different growth properties for the Microcystis groups in the mixed culture. Finally, we applied this method to natural Microcystis blooms at four freshwater sites, and found the dominance of Group-1 in three blooms and of Group-3 in one bloom, thereby showing the geographically uneven distribution of Microcystis genotypes. The developed qPCR technique targeting the 16S-23S ITS region is both rapid and simple and is useful for selective quantification of group variations among sympatric Microcystis genotypes, such as in mixed cultures and the natural environment.     

Occurrence of mycosporine-like amino acids (MAAs) in the bloom-forming cyanobacterium Microcystis aeruginosa

Here we report the finding of two mycosporine-like amino acids(shinorine and Porphyra-334) in both a culture of the cyanobacteriumMicrocystis aeruginosa isolated from Lake Taihu (China) anda natural phytoplankton sample collected from this lake whichincluded Microcystis spp. Our results are the first to clearlydocument the occurrence of these UV-sunscreen compounds in afreshwater bloom-forming cyanobacterium.     

The importance of morphological versus chemical defences for the bloom-forming cyanobacterium Microcystis against amoebae grazing

Amoebae grazing can be an important loss factor for blooms of the common cyanobacterium Microcystis. Some Microcystis strains seem to be protected against amoebae grazing, but it is unclear whether this is achieved by their colony morphology or biochemically. These factors were investigated in grazing experiments using two Microcystis-grazing amoebae (Korotnevella sp. and Vannella sp.) and two Microcystis strains with differing colony morphology (aeruginosa and viridis morphotype) and different sensitivity to amoebae grazing. Amoebae did not increase in density and failed to reduce the growth rate of cultures of the amoebae insensitive viridis strain, irrespective of whether the Microcystis strain was colonial or unicellular. This suggests that the extended mucilage matrix surrounding viridis colonies is not the main defence mechanism against amoebae grazing. At the same time, the growth rate of both unicellular and colonial cultures of the amoebae-sensitive aeruginosa strain was heavily reduced by the growing amoebae. The addition of filtered viridis-conditioned medium to aeruginosa cultures significantly decreased both amoebae growth and its effect on aeruginosa growth rates, which indicates that extracellular compounds constitutively produced by viridis are at least partially responsible for their insensitivity to amoebae grazing. These results demonstrate the potential importance of chemical interactions between lower trophic levels (protists) for Microcystis bloom dynamics.     

Membrane-like protein involved in phage adsorption associated with phage-sensitivity in the bloom-forming cyanobacterium Microcystis aeruginosa

The cyanobacterium, Microcystis aeruginosa, contains a large number of defense genes (Makarova et al., 2011); thus, it is a good model to study the co-evolution of phage and bacteria. Here, we isolated and characterized two phage-resistant M. aeruginosa mutants that came from a phage intermediate-sensitive culture. To determine the mutation conferring resistance, a protein expression pattern analysis was performed comparing phage-sensitive and -resistant sub-strains using SDS-PAGE. There were no apparent differences in expression patterns in the soluble fraction; however, a ∼90 kDa protein in the hydrophobic fraction from the phage-sensitive sub-strain was observed. Using a successive thermal asymmetric interlaced-PCR, the entire sequence encoding the protein, assigned ISP90, as well as its neighboring regions (ca. 7.8 kb) was determined. ISP90 contained no conserved domains and was predicted to be a membrane-associated protein. No mutations were detected in the nucleotide sequences coding ISP90 and diversification of ISP90 regions within this species were observed. Diversification of ISP90 regions within this species suggests a possible genomic island that may be subjected to selective pressures from phages. The ISP90 sequence involving phage resistance/sensitivity contributes to the understanding of co-evolution between M. aeruginosa and phages.     

The common bloom-forming cyanobacterium Microcystis is prone to a wide array of microbial antagonists

Many degraded waterbodies around the world are subject to strong proliferations of cyanobacteria – notorious for their toxicity, high biomass build-up and negative impacts on aquatic food webs – the presence of which puts serious limits on the human use of affected water bodies. Cyanobacterial blooms are largely regarded as trophic dead ends since they are a relatively poor food source for zooplankton. As a consequence, their population dynamics are generally attributed to changes in abiotic conditions (bottom-up control). Blooms however generally contain a vast and diverse community of micro-organisms of which some have shown devastating effects on cyanobacterial biomass. For Microcystis, one of the most common bloom-forming cyanobacteria worldwide, a high number of micro-organisms (about 120 taxa) including viruses, bacteria, microfungi, different groups of heterotrophic protists, other cyanobacteria and several eukaryotic microalgal groups are currently known to negatively affect its growth by infection and predation or by the production of allelopathic compounds. Although many of these specifically target Microcystis, sharp declines of Microcystis biomass in nature are only rarely assigned to these antagonistic microbiota. The commonly found strain specificity of their interactions may largely preclude strong antagonistic effects on Microcystis population levels but may however induce compositional shifts that can change ecological properties such as bloom toxicity. These highly specific interactions may form the basis of a continuous arms race (co-evolution) between Microcystis and its antagonists which potentially limits the possibilities for (micro)biological bloom control.     

Simulation of water-bloom formation in the cyanobacterium Microcystis aeruginosa

A mechanism for buoyancy increases in the cyanobacterium Microcystisaeruginosa and the associated formation of surface water-bloomsis presented. The mechanism is based on considering a responsetime in the rate of carbohydrate accumulation. When irradianceincreases, the Microcystis cells may require time to increasetheir rate of carbohydrate accumulation. If irradiance decreasesbefore adjustment, the maximum rate of carbohydrate accumulationis not reached. Colony buoyancy increases during mixing whenthe time scales of the light fluctuations are shorter than theresponse time. To examine the mechanism, a model of Microcystisbuoyancy that incorporates the response time has been coupledwith a hydrodynamics model that simulates mixing. The modelwas applied to a shallow lake to show that a prolonged episodeof intense mixing caused the simulated Microcystis coloniesto become excessively buoyant. Once the mixing subsided, thecolonies accumulated at the surface. Decreases in carbohydratewere reduced in large colonies as their size afforded buoyancyforces that could readily overcome the entraining forces ofthe mixing.     

Understanding the winning strategies used by the bloom-forming cyanobacterium Cylindrospermopsis raciborskii

The cyanobacterium Cylindrospermopsis raciborskii is a widespread species increasingly being recorded in freshwater systems around the world. It is of particular concern because strains in some geographic areas are capable of producing toxins with implications for human and animal health. Studies of this species have increased rapidly in the last two decades, especially in the southern hemisphere where toxic strains are prevalent. A clearer picture is emerging of the strategies adopted by this species to bloom and out-compete other species. This species has a high level of flexibility with respect to light and nutrients, with higher temperatures and carbon dioxide also promoting growth. There are two types of toxins produced by C. raciborskii: cylindrospermopsins (CYNs) and saxitoxins (STXs). The toxins CYNs are constitutively produced irrespective of environmental conditions and the ecological or physiological role is unclear, while STXs appear to serve as protection against high salinity and/or water hardness. It is also apparent that strains of this species can vary substantially in their physiological responses to environmental conditions, including CYNs production, and this may explain discrepancies in findings from studies in different geographical areas. The combination of a flexible strategy with respect to environmental conditions, and variability in strain response makes it a challenging species to manage. Our ability to improve bloom prediction will rely on a more detailed understanding of the complex physiology of this species.     

Allelopathic growth inhibition by the toxic, bloom-forming cyanobacterium Planktothrix rubescens

Blooms of freshwater cyanobacteria are typically accompanied by an important decrease in phytoplankton biodiversity in the water bodies where they occur. This study examines the potential production of growth-inhibiting substances by the toxic, bloom-forming cyanobacterium Planktothrix rubescens, following the observation of physical segregation between this and another cyanobacterium during previously performed mixed-culture competition experiments. Inhibition assays examining the growth of target strains exposed to donor culture filtrates showed that the growth of Planktothrix agardhii TCC 83-2, P. agardhii PMC 75.02 and Mougeotia gracillima TCC 50-2 was significantly inhibited in the presence of culture filtrate from P. rubescens TCC 29-1, isolated from Lake Bourget, France. Filtrates from P. rubescens TCC 69-6 and P. rubescens TCC 69-7, isolated from Lakes Nantua and Paladru (France), respectively, did not, however, inhibit the growth of P. agardhii TCC 83-2. This brief exploration of the allelopathic activity of P. rubescens suggests that it may potentially inhibit coexisting competitors as well as phytoplankton isolated from other freshwater ecosystems, and that this capacity may vary among different strains of Planktothrix. The potential importance of this phenomenon in pelagic competition dynamics is discussed.     

Lipopolysaccharides of the cyanobacterium Microcystis aeruginosa

Lipopolysaccharides (LPS) of two isolates of Microcystis aeruginosa were extracted with phenol/water and purified. Cesium chloride gradient ultracentrifugation of these preparations yielded only one fraction. The LPS contained significant amounts of 3-deoxy-D-manno-octulosonic acid, glucose, 3-deoxy sugars, glucosamine, fatty acids, fatty acid esters, hexoses, and phosphate. Heptose, a characteristic sugar component of the polysaccharide moiety of LPS of most gram-negative bacteria was absent. Lipopolysaccharides and lipid A hydrolysate of LPS preparations were active in mouse lethality and Limulus lysate gelation. The lipid A moiety was slightly less active in toxicity and Limulus lysate gelation assays than the intact LPS. The LPS and lipid A moiety of the two isolates of M. aeruginosa were less active in toxicity in mice and Limulus test than LPS of Salmonella abortus equi.     

Modelling vertical migration of the cyanobacterium Microcystis

Computer models can be helpful tools to provide abetter understanding of the mechanisms responsible forthe complex movements of cyanobacteria resulting fromchanges in buoyancy and mixing of the water column ina lake. Kromkamp & Walsby (1990) developed a verticalmigration model for Oscillatoria, that wasbased on the experimentally determinedrelationship between the rates of density change andphoton irradiance in this cyanobacterium. To adaptthis model to Microcystis, we determinedrelated changes in carbohydrate content in cultures ofMicrocystis. Samples were incubated at variousconstant values of photon irradiance and then placedin the dark. The changes in carbohydrate content ofthe cells during these incubations were investigated.The relationship between the ratio of carbohydrate toprotein and cell density in Microcystis wasestablished to permit conversion of the rates ofcarbohydrate change to rates of density change. Byplotting the calculated rates of density changeagainst the values of photon irradiance experiencedduring the incubations, an irradiance-response curveof density change was established. The curve showed adistinct maximum at 278 µmol photons m^-2s^-1. At higher values of photon irradiance, therate of density change was strongly inhibited. Apositive linear correlation was found between celldensity and the rates of density decrease in the dark.The validity of the use of rate equations of densitychange, which are based on short-term incubations atconstant values of photon irradiance, to predictdensity changes in Microcystis in fluctuatinglight regimes was tested. This was accomplished bymeasuring the time course of change in carbohydratecontent of two continuous cultures of Microcystis, which were submitted to fluctuatinglight regimes, and comparing the results with thechanges in the carbohydrate contents of these culturespredicted by the rate equations of carbohydratechange. The results showed good agreement: the rateequations of density change were therefore introducedinto the model to simulate vertical migration of Microcystis. The model predicts that the maximummigration depth of Microcystis will increasewith colony size up to a maximum of 200 µm radius.The effect of colony size on the net increase in celldensity during the light period was also investigatedwith the model. It predicts that small colonies havea higher net increase in cell density than largecolonies, but are inhibited at high photon irradiancesat the surface.     

Inhibition of Chlorella growth by the lipids of cyanobacterium Microcystis aeruginosa

The total lipids of the cyanobacterium Microcystis aeruginosa have been isolated and fractionated into its components. Of these lipid components, only the fatty acid-containing fraction inhibited the growth of the green alga Chlorella pyrenoidosa. The inhibitory activity appears to be due to linoleic and linolenic acids, which are both present in significants quantities. These acids may be the substances responsible for the reported toxicity of Microcystis aeruginosa to Chlorella.     

Photoinhibition of photosynthesis in the cyanobacterium Microcystis aeruginosa

We have examined characteristics of the photoinhibition of photosynthesis which occur in the unicellular cyanobacterium Microcystis aeruginosa, following exposure to photon fluence rates in excess of those required for growth. Photoinhibition occurs following exposure of cells to a photon fluence rate of 1,000 μmol m^-2 s^-1, which is manifested as a decrease in either light-limited CO₂ fixation or light-saturated CO₂-dependent O₂ evolution. The extent and rapidity of this photoinhibition is greatly enhanced under CO₂-depleted conditions. Experiments in which cultures were sparged with different gases indicate that photoinhibition is not an obvious consequence of elevated O₂ tensions, unlike the photooxidative bleaching of photosynthetic pigments. Comparative studies on the photoinactivation of CO₂-dependent O₂ evolution and of the methyl viologen-dependent Mehler reaction, in whole cells, indicate that a primary site of light damage is within the photosynthetic electron-transport reactions and that carbon fixation is initially unaffected.