Abstract
Microcystis, the dominant species among cyanobacterial blooms, normally forms colonies under natural conditions but exists as single cells or paired cells in axenic laboratory cultures after long-term cultivation. Here, a bloom-forming Microcystis aeruginosa strain CHAOHU 1326 was studied because it presents a colonial morphology and grows on the water surface during axenic laboratory culturing. We first examined the morphological features of strain CHAOHU 1326 and three other unicellular M. aeruginosa strains FACHB-925, FACHB-940, and FACHB-975 cultured under the same conditions by scanning and transmission electron microscopy. Then, we compared the extracellular polysaccharide (EPS)-producing ability of colonial strain CHAOHU 1326 to that of the three unicellular M. aeruginosa strains, and found that strain CHAOHU 1326 produced a higher amount of EPS than the other strains during growth. Moreover, based on genome sequencing, multiple gene clusters implicated in EPS biosynthesis and a cluster of 12 genes predicted to be involved in gas vesicle synthesis in strain CHAOHU 1326 were detected. These predicted genes were all functional and expressed in M. aeruginosa CHAOHU 1326 as determined by reverse transcription PCR. These findings provide a physiological and genetic basis to better understand colony formation and buoyancy control during M. aeruginosa blooming.
Highlights
During cyanobacteria blooming, large colonial aggregates form a scum floating on the surface of water bodies[6]
We found that the bloom-forming M. aeruginosa strain CHAOHU 1326 maintains a colonial morphology and grows on the water surface during laboratory culturing under axenic conditions
The results indicated that strain CHAOHU 1326 produced a significantly higher amount of extracellular polysaccharides (EPS) than other unicellular morphology strains during growth
Summary
Large colonial aggregates form a scum floating on the surface of water bodies[6]. M. aeruginosa tends to form colonial aggregates, i.e., several tens to hundreds of cells aggregate in the mucilage[11]. We found that the bloom-forming M. aeruginosa strain CHAOHU 1326 maintains a colonial morphology and grows on the water surface during laboratory culturing under axenic conditions. Strain CHAOHU 1326 was a suitable target for examining colony formation and buoyancy control. The purpose of the present study was to examine the physiological and genetic basis for colony formation and buoyancy control in strain CHAOHU 1326. We compared the EPS-producing ability of colonial strain CHAOHU 1326 to that of unicellular M. aeruginosa strains. The findings of this study will enhance our understanding of colony formation and buoyancy control during M. aeruginosa blooming
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