Prochlorococcus marinus 2012: Difference between revisions

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==Genome structure==
==Genome structure==


Because of its small size, Prochlorococcus marinus usually has a small genome1. It actually maintains the smallest genome of all cyanobacteria, with only 1.7 Mb [1]. This may be considered an adaptation because in the ocean (environment of this organism) there is not an excess nitrogen or phosphorus, which are essential in the production of nucleotides. There are generally two strains of this bacteria found in the ocean. The low-light adapted and high- light adapted strains are a result of the difference of light levels at different depths in the ocean. The low- light adapted strains have extra genes for the antenna complex protein, which is where the chlorophyll gets its energy from light [1]. These low-light adapted strains genetically produce chlorophyll b as opposed to chlorophyll a (high-light adapted strain) because chlorophyll b can be more helpful at a with a wider spectrum of light, which is essential when light is scarce. By having genes for more chlorophyll b and antenna protein complex, these bacteria are able to thrive even at depths of up to 200m [1]. These low-light adapted strains have a lot more variation when it comes to their genome, most likely as an adaptation for the tougher environment that the deeper ocean poses. The ocean is a very stable environment, thus these microbes have seen a decrease in the amount of stress- related and housekeeping genes, as compared to the genome of other cyanobacteria [1]. The genes for antenna protein are increased, as we discussed their characteristics that are essential to this bacteria. The genome of these bacteria are essential in the studying of photosynthetic bacteria, and their response to changing environments because of their unique and decreased genome [1].
Because of its small size, Prochlorococcus marinus usually has a small genome[1]. It actually maintains the smallest genome of all cyanobacteria, with only 1.7 Mb [1]. This may be considered an adaptation because in the ocean (environment of this organism) there is not an excess nitrogen or phosphorus, which are essential in the production of nucleotides. There are generally two strains of this bacteria found in the ocean. The low-light adapted and high- light adapted strains are a result of the difference of light levels at different depths in the ocean. The low- light adapted strains have extra genes for the antenna complex protein, which is where the chlorophyll gets its energy from light [1]. These low-light adapted strains genetically produce chlorophyll b as opposed to chlorophyll a (high-light adapted strain) because chlorophyll b can be more helpful at a with a wider spectrum of light, which is essential when light is scarce. By having genes for more chlorophyll b and antenna protein complex, these bacteria are able to thrive even at depths of up to 200m [1]. These low-light adapted strains have a lot more variation when it comes to their genome, most likely as an adaptation for the tougher environment that the deeper ocean poses. The ocean is a very stable environment, thus these microbes have seen a decrease in the amount of stress- related and housekeeping genes, as compared to the genome of other cyanobacteria [1]. The genes for antenna protein are increased, as we discussed their characteristics that are essential to this bacteria. The genome of these bacteria are essential in the studying of photosynthetic bacteria, and their response to changing environments because of their unique and decreased genome [1].


==Cell structure and metabolism==
==Cell structure and metabolism==

Revision as of 20:43, 23 February 2012

This student page has not been curated.

A Microbial Biorealm page on the genus Prochlorococcus marinus 2012 Prochlorococcus


Prochlorococcus

Classification

Higher order taxa

Bacteria;Cyanobacteria; Prochlorales; Prochlorococcaceae; Prochlorococcus

NCBI: Taxonomy

Species

NCBI: Genome

Prochlorococcus marinus

Description and significance

Prochlorococcus is a photosynthetic prokaryote. It is revealed by transmission election microscopy to have the same structure as a typical cyanacobacteria[3]. The cytoplasm holds DNA fibrils, carboxyzomes, and glycogen granules, which can be found near or between thylakoids. There is commonly two to four thylakoids in a Prochlorococcus cell, although sometimes there can be up to six thylakoids. Thylakoids can be found running parallel to the cell membrane [4].

Many methods used to find cell sizes tend to be biased towards tiny things, including Prochlorococcus cells. It is estimated that Prochlorococcus cells sizes vary from 0.5 to 0.8 μm in length, and 0.4 to 0.6 μm in width. A Prochlorococcus cell's size van vary depending on its environment. For example, its size was shown to increase by 0.45 to 0.75 μm between the surface and at a depth of 150 meters in the Sargasso Sea [4]. Studies show that Prochlorococcus can grow quite quickly in nutrient-poor habitats. The small size allows these picoplankton to take up dissolved nutrients more efficiently than larger organisms [5].

Prochlorococcus are important due to their contribution to oxygen production. Their production is found to contribute up to 39% of primary production in the eastern and western equatorial Pacific, and up to 82% in the North Pacific Ocean at Station ALOHA.

Genome structure

Because of its small size, Prochlorococcus marinus usually has a small genome[1]. It actually maintains the smallest genome of all cyanobacteria, with only 1.7 Mb [1]. This may be considered an adaptation because in the ocean (environment of this organism) there is not an excess nitrogen or phosphorus, which are essential in the production of nucleotides. There are generally two strains of this bacteria found in the ocean. The low-light adapted and high- light adapted strains are a result of the difference of light levels at different depths in the ocean. The low- light adapted strains have extra genes for the antenna complex protein, which is where the chlorophyll gets its energy from light [1]. These low-light adapted strains genetically produce chlorophyll b as opposed to chlorophyll a (high-light adapted strain) because chlorophyll b can be more helpful at a with a wider spectrum of light, which is essential when light is scarce. By having genes for more chlorophyll b and antenna protein complex, these bacteria are able to thrive even at depths of up to 200m [1]. These low-light adapted strains have a lot more variation when it comes to their genome, most likely as an adaptation for the tougher environment that the deeper ocean poses. The ocean is a very stable environment, thus these microbes have seen a decrease in the amount of stress- related and housekeeping genes, as compared to the genome of other cyanobacteria [1]. The genes for antenna protein are increased, as we discussed their characteristics that are essential to this bacteria. The genome of these bacteria are essential in the studying of photosynthetic bacteria, and their response to changing environments because of their unique and decreased genome [1].

Cell structure and metabolism

Interesting features of cell structure; how it gains energy; what important molecules it produces.

Prochlorococcus marinus has been established as one of the smallest living cyanobacteriumAll photosyntheic organisms must adapt to light levels in their environment in order to survive. Since it is know that prochlorococcus marinus are oxyphotobacteria that thrive in the ocean between 40 degrees north and 40 degrees south, their cellular strutres should reflect survival components of this environment. Indeed, survival in a oligotrophic environment requires adaptations such as low cellular nutrient requirement and highly efficient nutrient transport systems. The mechanisms that prochlorococcus uses to acquire and metabolize nitrogen, phosphorus, and other elements in its environment are central to its ecology [6].

For example, prochlorococcus marinus is a photosyntheitic organism, whos cellular strucutre lacks phycobiliproteins. Phycobiliproteins are water-soluable proteins that are present in most cyanobacteria and act to capture light energy which can then be used during photosynthesis. Instead of these proteins, prochlorococcus uses divinyl-chlorophyll a and b as their primary syntheitc pigments used during the photosyntheic process to gain energy [7]. This specialized pigment apparatus used to capture light is specific to prochlorococcus marinus which results in a unique light absorption spectrum, and sets it apart from other marine bacteria such as other plants and alge [8].

Ecology

Habitat; symbiosis; contributions to the environment.

Prochlorococcus marinus is a photosynthetic organism capable of living in nutrient-poor environments. It is frequently found in the oligotrophic ocean in tropical and subtropical regions. In an area exposed to UV light, Prochlorococcus marinus undergo a shifted cell cycle in order to maximize cell replication.

Pathology

Prochlorococcus marinus is a free-floating cyanobacteria, which means it uses the sun's rays for energy [9]. Because of this lifestyle, Prochlorococcus marinus is not a known pathogen of any kind.

Current Research

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

Cool Factor

Describe something you fing "cool" about this microbe.

References

1. Unknown Authors. "One of the Smallest Photosynthetic Organisms Known." Site Du Genoscope. Genoscope, 16 Jan. 2008. Web. 02 Feb. 2012. <http://www.cns.fr/spip/Prochlorococcus-marinus-smallest.html>.

2. Takai, K., Sugai, A., Itoh, T., and Horikoshi, K. "Palaeococcus ferrophilus gen. nov., sp. nov., a barophilic, hyperthermophilic archaeon from a deep-sea hydrothermal vent chimney". International Journal of Systematic and Evolutionary Microbiology. 2000. Volume 50. p. 489-500.

3. Partensky, F., W. R. Hess, and D. Vaulot. "Prochlorococcus, a Marine Photosynthetic Prokaryote of Global Significance." Microbiology and Molecular Biology Reviews 63.1 (1999): 106-27.

4. Campbell, Lisa, H. A. Nolla, and Daniel Vaulot. "The Importance of Prochlorococcus to Community Structure in the Central North Pacific Ocean." Limnology and Oceanography 39.4 (1994): 954-61.

5. Liu, Hongbin, Hector A. Nolla, and Lisa Campbell. "Prochlorococcus Growth Rate and Contribution to Primary Production in the Equatorial and Subtropical North Pacific Ocean." Aquatic Microbial Ecology 12 (1997): 39-47.

    • 6. Tolonen, Andrew Carl. "Prochlorococcus genetic transformation and genomics of nitrogen metabolism". Woods Hole Oceanographic Institution. Massachusetts Institute of Technology. 2005.

7. Chisholm, Sallie W., Sheila L. Frankel, Ralf Goericke et al. "Prochlorococcus marinus nov. gen. nov. sp.: an oxyphototrophic marine prokaryote containing divinyl chlorophyll a and b." Archives of Microbiology 157: 3 (1992): 297-300.

8. Steglich, Caludia., Matthias Futschik, Trent Rectro, Robert Steen, and Sallie W. Chisholm. "Genome-Wide Analysis of Light Sensing ni Prochlorococcus." Journal of Bacteriology 188: 22. (Nov. 2006): 7796-7806.

9.Kolowrat, Christian; Partensky, Frédéric; Mella-Flores, Daniella; Corguillé, Gildas Le; Boutte, Christophe; Blot, Nicolas; Ratin, Morgane; Ferréol, Martial; Lecomte, Xavier; Gourvil, Priscillia; Lennon, Jean-François; Kehoe, David M.; Garczarek, Laurence. "Ultraviolet stress delays chromosome replication in light/dark synchronized cells of the marine cyanobacterium Prochlorococcus marinus." BMC Microbiology, 2010, Vol. 10, p204-227