Prochloron didemni

A Microbial Biorealm page on the genus Prochloron didemni

Classification

Higher order taxa

Cellular Organisms; Bacteria; Cyanobacteria; Prochlorales; Prochloraceae; Prochloron

Species

Prochloron Didemni

Description and significance

Cross Section of L. Patella. The green portion are the P. didemni cells

P.didemni Cells.

Prochloron Didemni is a unicellular cyanobacteria that is photosynthetic and oxygenic. It is an obligate symbiont that lives in the ascidian Lissoclinum patella and can be found in marine environments.

The study of Prochloron didemni and its genome can provide us with valuable information. The genome of P. didemni is currently incomplete. However, when completed, P. didemni's genome can be used for analysis to elucidate other genes responsible for symbiosis between bacteria and chordates, such as humans. Also, as a oxygenic, photosynthetic cyanobacteria, P. didemni is a significant player in global carbon fixation. The study of its metabolic pathways and unique photosynthetic processes would yield information beneficial to biotechnology.

R.A. Lewin first discovered Prochloron didemni in 1975, but identified it as Synechocystis didemni. In 1977, the presence of chlorophyll a/b and the lack of phycobilins caused it to be transfered to a new genus, Prochloron, and named Prochloron didemni.(4)

Genome structure

Describe the size and content of the genome. How many chromosomes? Circular or linear? Other interesting features? What is known about its sequence? Does it have any plasmids? Are they important to the organism's lifestyle?

Cell structure and metabolism

Describe any interesting features and/or cell structures; how it gains energy; what important molecules it produces.

Ecology

Lissoclinum patella Colony

Prochloron didemni is an obligate symbiont that lives in the ascidian Lissoclinum patella. L. patella along with P. didemni can be found in tropical waters, such as the reefs in Hawaii and the Great Barrier Reef in Australia.(2,7)

Exchange of nutrients is the main reason for the symbiotic relationship between L. patella and P. didemni. Photosynthesis by P. didemni provides 60-100% of the organic carbon needed by L. patella. There is also evidence that suggests there is nitrogen cycling between the host and symbiont as well as nitrogen fixation. In exchange for the organic carbons and nitrogen cycling, L. patella provides optimal growth conditions by moving to areas with proper sunlight and a tunic covering.(1)

Patellamides, a product of P.didemni, also play in role in the symbiosis. The cytotoxic characteristic of patellamides may be used as feeding deterrents and patellamides' ability to chelate metals, such as copper and zinc, may be used in detoxification.(1)

Application to Biotechnology

One of the major problems with treating cancer is multi drug resistance. A recent study on Prochloron didemni revealed that it produces Patellamides A and C, which can be used to reverse multi drug resistance in cancer cells.(1)

Patellamides are psuedosymmetrical, cyclic dimers. Each substructure of patellamide contains the specific sequence thiazole-nonpolar amino acid-oxazoline-nonpolar amino acid. Study show that patellamides A and C are ribosomally synthesized and encoded on a single ORF. Genes patA - patG are responsible for the biosynthesis of patellamides. It is currently known that patA codes for a Subtilisin-like protease, patD for an adenylating enzyme-hydrolase hybrid, patE the precursor peptide, and patG a oxidoreductase-protease hybrid. Functions of patB,C,& F are still unknown.(1)

Current Research

Enter summaries of the most recent research here--at least three required

References

(1) Schmidt, E., Nelson, J., Rasko, D., Sudek, S., Eisen, J., Haygood, M., and Ravel, J. "Patellamide A and C biosynthesis by a microcin-like pathway in Prochloron didemni, the cyanobacterial symbiont of Lissoclinum patella". PNAS. May, 17, 2005. Volume 102. No. 20 p. 7315-7320.

(2) Bibby, T., Nield, J., Chen, M., Larkum, A., and Barber, J. "Structure of a photosystem II supercomplex isolated from Prochloron didemni retaining its chlorophyll a/b light-harvesting system". PNAS. July, 22, 2003. Volume 100. No. 15 p. 9050-9054.

(3) Lockhart, P., Beanland, T., Howe, C., and Larkum, A. "Sequence of Prochloron didemni atpBE and the inference of chloroplast origins". Proc. Natl. Acad. Sci. USA: Evolution. April, 1992. Volume 89. p. 2742-2746.]

(4) Hoffman, L., and Greuter, W. "Validation of Prochloron didemni (Cyanophyta and Nomenclatural Discussion of Correlated Names at the Higher Ranks". Taxon. August, 1993. Volume 42. No. 3 p. 641-645.

(5) Christen, G., Stevens, G., Lukins, P., Renger, G., and Larkum, A. "Isolation and characterisation of oxygen evolving thylakoids from the marine prokaryote Prochloron didemni". FEBS. March, 1999. Letters 449 p. 264-268.

(6) Figge, R., Schubert, M., Brinkmann, H., and Cerff, R. "Glyceraldehyde-3-Phosphate Dehydrogenase Gene Diversity in Eubacteria and Eukaryotes: Evidence for Intra- and Inter-Kingdom Gene Transfer". Mol. Biol. Evol.. 1999. p. 429-440.

(7) Giddings Jr., T., Withers, N., and Staehelin, L. A. "Supramolecular structure of stacked and unstacked regions of the photosynthetic membranes of Prochloron sp., a prokaryote". Proc. Natl. Acad. Sci. USA: Botany. January, 1980. Volume 77. No. 1 p. 352-356.

(8) Herdman, M. "Deoxyribonucleic Acid Base Composition and Genome Size of Prochloron". Arch Microbiol. 1981. Volume 129. p. 314-316.

(9) Jurgens, U., Burger-Wiersma, T. "Peptidoglycan=Polysaccharide Complex in the Cell Wall of the Filamentous Prochlorophyte Prochlorothrix hollandica". Journal of Bacteriology. January, 1989. Volume 171. No. 1 p. 498-502.

(10) Delcher, A., Bratke, K., Powers, E., and Salzberg, S. "Identifying bacterial genes and endosymbiont DNA with Glimmer" Bioinformatics. January, 2007. Volume 23. No. 6 p. 673-679.

Edited by Edward Lee Eddie Lee, a student of Rachel Larsen Rachel Larsen