Alcanivorax: Difference between revisions

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[[Image:Lorenzo.gif|thumbnail|200px|Figure 3. Mechanisms for oil degradation and survival encoded by the ''A. borkumensis SK2'' genome. Image from Victor de Lorenzo[http://www.nature.com/nbt/journal/v24/n8/full/nbt0806-952.html]]]
[[Image:Lorenzo.gif|thumbnail|200px|Figure 3. Mechanisms for oil degradation and survival encoded by the ''A. borkumensis SK2'' genome. Image from Victor de Lorenzo[http://www.nature.com/nbt/journal/v24/n8/full/nbt0806-952.html]]]


The ''Alcanivorax borkumensis'' strain SK2, isolated from a seawater sediment sample in the North Sea at a site located near the Isle of Borkum, was the first hydrocarbonoclastic bacterium to be sequenced and was completed by Susanne Schneiker et al. It's genome consists of a single circular chromosome with 3,120,143 base pairs with an average G+C content of 54.7%. The genomic analysis of ''A. borkumensis SK2'' revealed several new insights into the bacterium's role for (i) n-alkane degradation (which includes metabolism, biosurfactant production and biofilm production), (ii) it's system for capturing or scavenging the small amounts of nitrogen, phosphorous, sulfur, and other elements in a nutrient-poor marine environment which allows for more efficient alkane degradation due to their main limitation of nutrient availability, (iii) as well as means for coping with stress factors such as high salt contents and high UV radiation since it thrives mostly in the upper layers in the ocean where UV light is encountered (Figure 3).
The ''Alcanivorax borkumensis'' strain SK2, isolated from a seawater sediment sample in the North Sea at a site located near the Isle of Borkum, was the first hydrocarbonoclastic bacterium to be sequenced and was completed by Susanne Schneiker et al. It's genome consists of a single circular chromosome with 3,120,143 base pairs and an average G+C content of 54.7%. The genomic analysis of ''A. borkumensis SK2'' revealed several new insights into the bacterium's role for (i) n-alkane degradation (which includes metabolism, biosurfactant production and biofilm production), (ii) it's system for capturing or scavenging the small amounts of nitrogen, phosphorous, sulfur, and other elements in a nutrient-poor marine environment which allows for more efficient alkane degradation due to their main limitation of nutrient availability, (iii) as well as means for coping with stress factors such as high salt contents and high UV radiation since it thrives mostly in the upper layers in the ocean where UV light is encountered (Figure 3).


It's genome encodes several systems for the catabolism of hydrocarbons which allow the bacertium to degrade all sorts of alkanes such as AlkB1 alkane hydroxylase which oxidizes medium-chain alkanes in the range of C5-C12, and AlkB2 alkane hydroxylase which oxidizes medium-chain alkanes in the range of C8 to C16. Both these systems are located close to the origin of replication of the chromosome. ''A. borkumensis'' is also able to degrade alkanes up to C32, branched aliphatic hydrocarbons, isoprenoid hydrocarbons such as phytane, as well as alkylarenes and alkylcycloalkanes. Thus, the genome encodes for a broad spectrum of systems for the catabolism of hydrocarbons, giving it a competitive advantage over other oil-degrading marine microbial communities. To deal with the damaging effects of UV light, ''A. borkumensis'' has a number of genes that reduce the damage. These include the full genes for DNA alkylation, recombinational and nucleotide excision repair, base excision repair, as well as the SOS response [4].
It's genome encodes several systems for the catabolism of hydrocarbons which allow the bacertium to degrade all sorts of alkanes such as AlkB1 alkane hydroxylase which oxidizes medium-chain alkanes in the range of C5-C12, and AlkB2 alkane hydroxylase which oxidizes medium-chain alkanes in the range of C8 to C16. Both these systems are located close to the origin of replication of the chromosome. ''A. borkumensis'' is also able to degrade alkanes up to C32, branched aliphatic hydrocarbons, isoprenoid hydrocarbons such as phytane, as well as alkylarenes and alkylcycloalkanes. Thus, the genome encodes for a broad spectrum of systems for the catabolism of hydrocarbons, giving it a competitive advantage over other oil-degrading marine microbial communities. To deal with the damaging effects of UV light, ''A. borkumensis'' has a number of genes that reduce the damage. These include the full genes for DNA alkylation, recombinational and nucleotide excision repair, base excision repair, as well as the SOS response [4].

Revision as of 22:43, 6 April 2008

Figure 1. Alcanivorax borkumensis. Image from Helmholtz Centre for Infection Research[1]

Classification

Bacteria; Phylum: Proteobacteria; Class: Gammaproteobacteria; Order: Oceanospirillales; Family: Alcanivoracaceae

Species

NCBI: Taxonomy

  • Alcanivorax balearicum
  • Alcanivorax borkumensis
  • Alcanivorax dieselolei
  • Alcanivorax indicus
  • Alcanivorax jadensis
  • Alcanivorax venustensis

Description and Significance

Figure 2. Supertanker Exxon Valdez grounded on Bligh Reef which released 11 million gallons of crude oil into the water. This oil-contaminated seawater is the preferred habitat for Alcanivorax. Image from USGS[2]

Alcanivorax, first described in 1998, is a Gram-negative, halophilic, aerobic, rod-shaped, oil-degrading marine bacterium that is found in low abundances in unpolluted environments in the upper layers of the ocean, but quickly becomes the predominant microbe in oil-contaminated open oceans and coastal waters when nitrogen and phosphorus are not limiting [2]. When conditions in these moderately halophilic environments are right, Alcanivorax may make up 80-90% of the oil-degrading microbes present in the area [4]. It is described as a non-motile bactertium which is true for species such as Alcanivorax borkumensis, but other species such as Alcanivorax venustensis were described to be motile by polar flagella [1]. The optimial conditions described for A.borkumensis growth include temperatures in the range of 20-30 degrees celsius, and a NaCl concentration of 3-10%.

As a result of their profound ability to degrade and live predominately on alkanes, as well as to become the dominant microbes in oil-contaminated areas, Alcanivorax plays a huge role in the biological cleanup of oil-contaminated environments. These oil-contaminated environments in the ocean are largely due to anthropogenic sources such as oil spills caused by tankers accidents (Figure 2), and cause serious ecological damage to plants and animals on the coast as well as other inhabitants of the ocean. Microbes such as Alcanivorax provide a major route for the breakdown of these pollutants, and demonstrate how marine bacteria keep the environment in check. Of all the Alcanivorax species and other oil-degrading microbes, Alcanivorax borkumensis is one of the most important worldwide due to the fact it produces a wide variety of very efficient oil-degrading enzymes. With this knowledge, A. borkumensis could provide a useful tool for bioremediation of oil spills.

Genome Structure

Figure 3. Mechanisms for oil degradation and survival encoded by the A. borkumensis SK2 genome. Image from Victor de Lorenzo[3]

The Alcanivorax borkumensis strain SK2, isolated from a seawater sediment sample in the North Sea at a site located near the Isle of Borkum, was the first hydrocarbonoclastic bacterium to be sequenced and was completed by Susanne Schneiker et al. It's genome consists of a single circular chromosome with 3,120,143 base pairs and an average G+C content of 54.7%. The genomic analysis of A. borkumensis SK2 revealed several new insights into the bacterium's role for (i) n-alkane degradation (which includes metabolism, biosurfactant production and biofilm production), (ii) it's system for capturing or scavenging the small amounts of nitrogen, phosphorous, sulfur, and other elements in a nutrient-poor marine environment which allows for more efficient alkane degradation due to their main limitation of nutrient availability, (iii) as well as means for coping with stress factors such as high salt contents and high UV radiation since it thrives mostly in the upper layers in the ocean where UV light is encountered (Figure 3).

It's genome encodes several systems for the catabolism of hydrocarbons which allow the bacertium to degrade all sorts of alkanes such as AlkB1 alkane hydroxylase which oxidizes medium-chain alkanes in the range of C5-C12, and AlkB2 alkane hydroxylase which oxidizes medium-chain alkanes in the range of C8 to C16. Both these systems are located close to the origin of replication of the chromosome. A. borkumensis is also able to degrade alkanes up to C32, branched aliphatic hydrocarbons, isoprenoid hydrocarbons such as phytane, as well as alkylarenes and alkylcycloalkanes. Thus, the genome encodes for a broad spectrum of systems for the catabolism of hydrocarbons, giving it a competitive advantage over other oil-degrading marine microbial communities. To deal with the damaging effects of UV light, A. borkumensis has a number of genes that reduce the damage. These include the full genes for DNA alkylation, recombinational and nucleotide excision repair, base excision repair, as well as the SOS response [4].

Cell Structure, Metabolism and Life Cycle

Alcanivorax borkumensis, a Gram-negative, rod-shaped chemoorganotroph, is able to use n-alkanes as its principle carbon and energy source by use of the broad spectrum of oil-degrading enzymes it possesses, but they can also use a limited number of organic compounds such as aliphatic hydrocarbons, volatile fatty acids, and pyruvate. However, it cannot utilize carbon sources such as sugars or amino acids. Cells grown with pyruvate were observed to be 2.0-3.0 micrometers in length and 0.4-07 micrometers in diameter, however, cells were shorter (1.0-1.5 micrometers in length) when cells were grown with n-alkanes as the carbon source [5]. When the slow growing A. borkumensis uses n-alkanes exclusively, the microbes produce extracellular and membrane-bound surface-active glucose lipids called biosurfactants. These biosurfactants reduce the surface tension of water from 72 to 29 mN m-1 and act as natural emulsifiers which enhances the break up of oil-in-water emulsions which prevent degradation of alkanes [4,5]. Due to the low solubility of oil in water, most oil degradation takes place at the oil-water interface where A. borkumensis attaches and forms a biofilm around the oil droplets as depicted in Figure 3.

Ecology and Pathogenesis

Habitat; symbiosis; biogeochemical significance; contributions to environment.

References

[1] Fernandez-Martinez, Javier, Maria J. Pujalte, Jesus Garcia-Martinez, Manuel Mata, Esperanza Garay, and Francisco Rodriguez-Valera. "Description of Alcanivorax Venustensis sp. nov. and Reclassification of Fundibacter Jadensis DSM 12178T (Bruns and Berthe-Corti 1999) As Alcanivorax Jadensis comb. nov., Members of the Emended Genus Alcanivorax." International Journal of Systematic and Evolutionary Microbiology 53 (2003): 331-338.

[2] Hara, Akihiro, Kazuaki Syutsubo, and Shigeaki Harayama. "Alcanivorax Which Prevails In Oil-contaminated Seawater Exhibits Broad Substrate Specificity For Alkane Degradation." Environmental Microbiology 5.9 (2003): 746-753.

[3] Lorenzo, Víctor De. "Blueprint of an Oil-eating Bacterium." Nature Biotechnology 24 (2006): 952-953.

[4] Schneiker, S. et al. "Genome Sequence of the Ubiquitous Hydrocarbon-degrading Marine Bacterium Alcanivorax Borkumensis." Nature Biotechnology 24 (2006): 997-1004.

[5] Yakimov, Michail M., Peter N. Golyshin, Siegmund Lang, Edward R. B. Moore, Wolf-Rainer Abraham, Heinrich Lunsdorf, and Kenneth N. Timmis. "Alcanivorax Borkumensis gen. nov., sp. nov., A New, Hydrocarbon-degrading And Surfactant-producing Marine Bacterium." International Journal of Systematic Bacteriology 48 (1998): 339-348.

Author

Page authored by Andrew Buss, student of Prof. Jay Lennon at Michigan State University.