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Morphogenesis and differentiation in Rhodomicrobium

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France, Andrew D. (1978) Morphogenesis and differentiation in Rhodomicrobium. PhD thesis, University of Warwick.

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Official URL: http://webcat.warwick.ac.uk/record=b1750163~S15

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Abstract

Differentiation and morphogenesis in the budding photosynthetic bacterium Rhodomicrobium vannielii (Rm5) was investigated using batch and continuous culture techniques. A previously undocumented 'simplified' vegetative cell cycle was identified. 'Simplified' Rm 5 cells (with a developmental cycle resembling that of the prosthecate Hyphomicrobium, were isolated from the late exponential growth phase of batch cultures, or from continuous cultures grown under high CO₂ tensions. Expression of this cell type appears to be under environmental control although the possibility that such cells may be mutants has not been overlooked. Previous studies have associated swarm cell production with mother cells comprising multicellular arrays, but the existence of 'simplified' cells suggests that microcolony formation is not a prerequisite for swarm cell synthesis. The characteristics of this unusual cell type and the morphology and physiology were compared with cells of Rhodomicrobium expressing the ’normal’ developmental cycle. Soluble protein extracts of ’simplified’ Rm 5 cells were compared with those of the other cell types by polyacrylamide gel electrophoresis.

Since reproducibility of results was difficult to achieve under batch culture conditions, the possibility of using a chemostat to perform simple physiological studies and optimise growth conditions was investigated. Experiments were performed in order to try and elucidate whether or not 'simplified' Rm 5 cells were mutations, or a form of cellular expression in response to particular environmental conditions. Although growth of Rm 5 is accompanied by obligate differentiation, life cycle variations such as exospore production and swarm cell formation are almost certainly environmentally induced. Preliminary investigations were made as to the effect of different environmental conditions on cellular expression in Rm 5. Light intensity, pH and CO₂ tension were involved with swarm cell production and development, whereas the presence of trace elements was a probable requirement for successful exospore formation.

Item Type: Thesis or Dissertation (PhD)
Subjects: Q Science > QH Natural history
Q Science > QR Microbiology
Library of Congress Subject Headings (LCSH): Photosynthetic bacteria, Gram-negative bacteria, Morphogenesis, Cell cycle
Official Date: January 1978
Dates:
DateEvent
January 1978Submitted
Institution: University of Warwick
Theses Department: Department of Biological Sciences
Thesis Type: PhD
Publication Status: Unpublished
Supervisor(s)/Advisor: Dow, Crawford S.
Sponsors: Science Research Council (Great Britain)
Extent: 237 leaves : illustrations, charts
Language: eng

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