Stenotrophomonas rhizophila: Difference between revisions

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Class: Gammaproteobacteria
Class: Gammaproteobacteria


Order: ''Xanthomonadales''
Order: Xanthomonadales


Family: ''Xanthomonadaceae''
Family: Xanthomonadaceae


===Species===
===Species===
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==Description and Significance==
==Description and Significance==
Describe the appearance, habitat, etc. of the organism, and why you think it is important.
''Stenotrophomonas rhizophila'' is a Gram negative bacilli[[#References|[1]]].  ''S. rhizophila'' can be found within a range of host-associated locations from stems, leaves, or the rhizosphere.  In tomatoes, for instance, it is more common to find ''S. rhizophila'' within its leaves [[#References|[12]]]. In cotton or sweet pepper, there will be a higher density of ''S. rhizophila'' in its rhizosphere and begin to lower as you go up the plant. For potato tubers, colonization of the endosphere was found to be more common.[[#References|[5]]]
 
Recent agricultural practices have resulted in salinized soils increasing the likelihood of plant life being affected by soil borne diseases. Fortunately the production of osmoprotective substances, trehalose and glucosylglycerol, has allowed for plant-bacteria symbiotic relations to form where the cultivation of biofilms enables plants to tolerate osmotic pressures by fighting off deleterious and pathogenic rhizosphere microorganisms [[#References|[5]]]. For example, in Uzbekistan’s highly salinized soils the presence of ''S. rhizophila'' dramatically increased plant growth by 180%.[[#References|[4]]]
 
[[File:Stenotrophomonas rhizophila.jpg]]
 
Colonies of ''S. rhizophila'' in tomato plant roots[[#References|[6]]]


==Genome Structure==
==Genome Structure==
''Stenotrophomonas rhizophila'' has a single circular genome with a length of 4,648,976 base pairs.[[#References|[1]]]  It shares a high degree of sequence similarity among members of the ''Stenotrophomonas'' genus.  All members of the genus share genes for host invasion, antibiotic resistance, and anti-fungal properties.  While these genes would normally be present in pathogens, ''S. rhizophila'' maintains non-pathogenicity due to its loss of virulence factors and heat shock factors.  Instead, ''S. rhizophila'' maintains genes for spermidine, plant cell-wall degrading enzymes, and high salinity resistance.  ''S. rhizophila'' also maintains a suite of genes needed for forming biofilms, such as flagella production, surface polysaccharides, and adhesion.[[#References|[2]]]
''Stenotrophomonas rhizophila'' has a single circular genome with a length of 4,648,976 base pairs[[#References|[1]]]. It shares a high degree of sequence similarities among members of the ''Stenotrophomonas'' genus.  All members of the genus share genes for host invasion, antibiotic resistance, and anti-fungal properties.  While these genes would normally be present in pathogens, ''S. rhizophila'' maintains non-pathogenicity due to its loss of virulence factors and heat shock factors.  Instead, ''S. rhizophila'' maintains genes for spermidine, plant cell-wall degrading enzymes, and high salinity resistance.  ''S. rhizophila'' also maintains a suite of genes needed for forming biofilms, such as flagella production, surface polysaccharides, and adhesion.[[#References|[2]]]


==Cell Structure, Metabolism and Life Cycle==
==Cell Structure, Metabolism and Life Cycle==
Interesting features of cell structure; how it gains energy; what important molecules it produces.


''S. rhizophila'' has important molecular products which help its symbiosis with plants.  ''S. rhizophila'' produces spermidine which has been shown to increase plant growth as well as provide a molecular base for other polyamines that can protect against drought and salinity.[[#References|[2]]]  ''S. rhizophila'' also excretes glucosylglycerol(GG) and trehalose which have high water retaining capabilities into soil as salinity increases.  This further increases plants' resistance to salinity as GG helps promote cell division and growth, despite conditions that would favor cell shrinkage.[[#References|[3]]]
''S. rhizophila'' may form a monospecies biofilm, but is more likely to form a multispecies biofilm due to synergistic interactions leading to an increased biomass[[#References|[7]]].
 
''S. rhizophila'' is a chemoorganoheterotroph and can subsist off of a variety of organic products.  ''S. rhizophila'' is able to oxidize a significant element of plant roots, xylose. Along with xylose, other compounds that can be oxidized consist of D-trehalose, succinamic acid, DL-lactic acid and many others [[#References|[12]]].  ''S. rhizophila'' also participates in degradation of lignocellulose, though it can not directly degrade cellulose as it does not produce B-glucosidase[[#References|[11]]].
 
''S. rhizophila'' has important molecular products which help in its symbiosis with plants.  ''S. rhizophila'' produces spermidine which has been shown to increase plant growth as well as provide a molecular base for other polyamines that can protect against drought and salinity[[#References|[2]]]. ''S. rhizophila'' also excretes glucosylglycerol(GG) and trehalose, which have high water retaining capabilities, into soil as salinity increases.  This further increases plants' resistance to salinity as GG helps promote cell division and growth, despite conditions that would favor cell shrinkage[[#References|[3]]].  In addition, ''S. rhizophila'' produces dodecanal which inhibits fungal mycelial growth as well as chitinases which degrade fungal cell walls[[#References|[6]]].


==Ecology and Pathogenesis==
==Ecology and Pathogenesis==
Habitat; symbiosis; biogeochemical significance; contributions to environment.<br>
''Stenotrophomonas rhizophila'' is an active participant in the rhizosphere, as well as endosphere, and can be found in all of plant phylogeny.  ''S. rhizophila'' produces osmoprotective substances and provides plants with defenses from bacterial and fungal pathogens[[#References|[10]]].  ''S. rhizophila'' also forms the core with a few other soil bacteria which participates in the degradation of lignocellulose[[#References|[11]]].
If relevant, how does this organism cause disease? Human, animal, plant hosts? Virulence factors, as well as patient symptoms.<br><br>
 
With the potential to colonize plants' outer surface and ''S. rhizophila’s'' close relation to ''Stenotrophomonas maltophilia,'' there have been raised concerns over harvesting products whose surface has been colonized [[#References|[5]]]. However, ''S. rhizophila'' does not carry the pathogenic traits essential to ''S. maltophilia's'' harm to humans and is incapable of growing in human body temperatures as it only grows below 37 °C [[#References|[9]]].  Since bacteria that participate in biofilms enjoy increased lateral gene transfer[[#References|[8]]], there is growing concern that the addition of a few new genes could induce a potent pathogen.[[#References|[2]]]


==References==
==References==
[Sample reference] [http://ijs.sgmjournals.org/cgi/reprint/50/2/489 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.]
[1] [https://www.ncbi.nlm.nih.gov/genome/15911?genome_assembly_id=176543 NCBI "''Stenotrophomonas rhizophila''". NCBI Genome Assembly. 2013. Web. 21 Apr 2017.]
[1] [https://www.ncbi.nlm.nih.gov/genome/15911?genome_assembly_id=176543 NCBI "''Stenotrophomonas rhizophila''". NCBI Genome Assembly. 2013. Web. 21 Apr 2017.]


[2] [https://bmcgenomics.biomedcentral.com/articles/10.1186/1471-2164-15-482#CR15 Alavi, P., Starcher, M., Thallinger, G., Zachow, C., Müller, H., and Berg, G. "''Stenotrophomonas'' comparative genomics reveals genes and functions that differentiate beneficial and pathogenic bacteria." ''BMC Genomics''. BioMed Central, 18 June 2014. Web. 21 Apr. 2017.]
[2] [https://bmcgenomics.biomedcentral.com/articles/10.1186/1471-2164-15-482 Alavi, P., Starcher, M., Thallinger, G., Zachow, C., Müller, H., and Berg, G. "''Stenotrophomonas'' comparative genomics reveals genes and functions that differentiate beneficial and pathogenic bacteria." ''BMC Genomics''. BioMed Central, 18 June 2014. Web. 21 Apr. 2017.]


[3] [https://www.ncbi.nlm.nih.gov/genome/15911?genome_assembly_id=176543 Roder, A., Hoffmann, E., Hagemann, M., and Berg, G. "Synthesis of the compatible solutes glucosylglycerol and trehalose by salt-stressed cells of ''Stenotrophomonas'' strains." ''FEMS Microbiology Letters''. Oxford University Press, 09 Jan. 2006. Web. 21 Apr. 2017.]
[3] [https://www.ncbi.nlm.nih.gov/genome/15911?genome_assembly_id=176543 Roder, A., Hoffmann, E., Hagemann, M., and Berg, G. "Synthesis of the compatible solutes glucosylglycerol and trehalose by salt-stressed cells of ''Stenotrophomonas'' strains." ''FEMS Microbiology Letters''. Oxford University Press, 09 Jan. 2006. Web. 21 Apr. 2017.]


[4] [http://journal.frontiersin.org/article/10.3389/fpls.2013.00141/full Alavi, P., Starcher, M., Zachow, C., Berg, G., and Müller, H. "''Root-microbe Systems: The Effect and Mode of Interaction of Stress Protecting Agent (SPA) ''Stenotrophomonas'' Rhizophila''  DSM14405T."'' "Frontiers in Plant Science 4 (2013)". Frontiers in Plant Science. Web. 21 Apr. 2017.
[4] [http://journal.frontiersin.org/article/10.3389/fpls.2013.00141/full Alavi, P., Starcher, M., Zachow, C.S., Berg, G., and Müller, H. "Root-microbe systems: The effect and mode of interaction of Stress Protecting Agent (SPA) ''Stenotrophomonas rhizophila''  DSM14405T." ''Frontiers in Plant Science''. Frontiers in Plant Science, 14 May 2013. Web. 21 Apr. 2017.]
 
[5] [https://link-springer-com.proxyiub.uits.iu.edu/article/10.1007/s00374-012-0688-z Schmidt, C., Alavi, M., Cardinale, M., Müller, H., and Berg, G. "''Stenotrophomonas rhizophila'' DSM14405T promotes plant growth probably by altering fungal communities in the rhizosphere." ''SpringerLink''. Springer-Verlag, 03 May 2012. Web. 20 Apr. 2017.]
 
[6] [http://www.nature.com.proxyiub.uits.iu.edu/nrmicro/journal/v7/n7/full/nrmicro2163.html Ryan, R., Monchy, S., Cardinale, M., Taghavi, S., Crossman, L., Avison, M., Berg, G., Lelie, D., and Dow, J. "The versatility and adaptation of bacteria from the genus ''Stenotrophomonas''." ''Nature Reviews Microbiology'' 7.7 (2009): 514-25. Web.]
 
[7] [https://link-springer-com.proxyiub.uits.iu.edu/article/10.1007/s00248-013-0315-z Ren, D., Madsen, J.S., de la Cruz-Perera, C.I. et al. "High-Throughput Screening of Multispecies Biofilm Formation and Quantitative PCR-Based Assessment of Individual Species Proportions, Useful for Exploring Interspecific Bacterial Interactions" ''Microbial Ecology'' 68.1 (2014): 146-54. Web.]
 
[8] [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4274433/#bib4 Ren, D., Madsen, J., Sorensen, S., Burmolle, M. “High Prevalence of Biofilm Synergy among Bacterial Soil Isolates in Cocultures Indicates Bacterial Interspecific Cooperation.” ''The ISME Journal'' 9.1 (2015): 81–89. PMC. Web. 21 Apr. 2017.]
 
[9] [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4379930/ Berg, G., and Martinez, J. "Friends or Foes: Can We Make a Distinction between Beneficial and Harmful Strains of the Stenotrophomonas Maltophilia Complex?" ''Frontiers in Microbiology'' 6 (2015): 241. PMC. Web. 24 Apr. 2017.]
 
[10] [https://link-springer-com.proxyiub.uits.iu.edu/chapter/10.1007/978-90-481-9449-0_22/fulltext.html Berg, G., Egamberdieva, D., Lugtenberg, B., Hagemann, M. “Symbiotic Plant–Microbe Interactions: Stress Protection, Plant Growth Promotion, and Biocontrol by ''Stenotrophomonas''.” ''Cellular Origin, Life in Extreme Habitats and Astrobiology'' 17 (2010): 445–60. Web. 21 Apr. 2017.]
 
[11] [https://link-springer-com.proxyiub.uits.iu.edu/article/10.1007/s00248-015-0683-7 de Lima Brossi, M.J., Jiménez, D.J., Cortes-Tolalpa, L., van Elsas, J. “Soil-Derived Microbial Consortia Enriched with Different Plant Biomass Reveal Distinct Players Acting in Lignocellulose Degradation.” ''Microbial Ecology'' 71.3 (2016): 616–27. Web. 21 Apr. 2017.]
 
[12] [http://www.microbiologyresearch.org/docserver/fulltext/ijsem/52/6/0521937a.pdf?expires=1493002345&id=id&accname=guest&checksum=A8F3AA4B191D622A0B28182E8735DDAB Wolf, A., Fritze, A., Hagemann, M., Berg, G. “''Stenotrophomonas rhizophila'' sp. nov., a novel plant-associated bacterium with antifungal properties.” ''International Journal of Systematic and Evolutionary Microbiology'' 52 (2002): 1937-44. Web. 21 Apr. 2017.]


==Author==
==Author==

Latest revision as of 05:21, 24 April 2017

This student page has not been curated.

Classification

Domain: Bacteria

Phylum: Proteobacteria

Class: Gammaproteobacteria

Order: Xanthomonadales

Family: Xanthomonadaceae

Species

NCBI: Taxonomy

Stenotrophomonas rhizophila

Description and Significance

Stenotrophomonas rhizophila is a Gram negative bacilli[1]. S. rhizophila can be found within a range of host-associated locations from stems, leaves, or the rhizosphere. In tomatoes, for instance, it is more common to find S. rhizophila within its leaves [12]. In cotton or sweet pepper, there will be a higher density of S. rhizophila in its rhizosphere and begin to lower as you go up the plant. For potato tubers, colonization of the endosphere was found to be more common.[5]

Recent agricultural practices have resulted in salinized soils increasing the likelihood of plant life being affected by soil borne diseases. Fortunately the production of osmoprotective substances, trehalose and glucosylglycerol, has allowed for plant-bacteria symbiotic relations to form where the cultivation of biofilms enables plants to tolerate osmotic pressures by fighting off deleterious and pathogenic rhizosphere microorganisms [5]. For example, in Uzbekistan’s highly salinized soils the presence of S. rhizophila dramatically increased plant growth by 180%.[4]

Stenotrophomonas rhizophila.jpg

Colonies of S. rhizophila in tomato plant roots[6]

Genome Structure

Stenotrophomonas rhizophila has a single circular genome with a length of 4,648,976 base pairs[1]. It shares a high degree of sequence similarities among members of the Stenotrophomonas genus. All members of the genus share genes for host invasion, antibiotic resistance, and anti-fungal properties. While these genes would normally be present in pathogens, S. rhizophila maintains non-pathogenicity due to its loss of virulence factors and heat shock factors. Instead, S. rhizophila maintains genes for spermidine, plant cell-wall degrading enzymes, and high salinity resistance. S. rhizophila also maintains a suite of genes needed for forming biofilms, such as flagella production, surface polysaccharides, and adhesion.[2]

Cell Structure, Metabolism and Life Cycle

S. rhizophila may form a monospecies biofilm, but is more likely to form a multispecies biofilm due to synergistic interactions leading to an increased biomass[7].

S. rhizophila is a chemoorganoheterotroph and can subsist off of a variety of organic products. S. rhizophila is able to oxidize a significant element of plant roots, xylose. Along with xylose, other compounds that can be oxidized consist of D-trehalose, succinamic acid, DL-lactic acid and many others [12]. S. rhizophila also participates in degradation of lignocellulose, though it can not directly degrade cellulose as it does not produce B-glucosidase[11].

S. rhizophila has important molecular products which help in its symbiosis with plants. S. rhizophila produces spermidine which has been shown to increase plant growth as well as provide a molecular base for other polyamines that can protect against drought and salinity[2]. S. rhizophila also excretes glucosylglycerol(GG) and trehalose, which have high water retaining capabilities, into soil as salinity increases. This further increases plants' resistance to salinity as GG helps promote cell division and growth, despite conditions that would favor cell shrinkage[3]. In addition, S. rhizophila produces dodecanal which inhibits fungal mycelial growth as well as chitinases which degrade fungal cell walls[6].

Ecology and Pathogenesis

Stenotrophomonas rhizophila is an active participant in the rhizosphere, as well as endosphere, and can be found in all of plant phylogeny. S. rhizophila produces osmoprotective substances and provides plants with defenses from bacterial and fungal pathogens[10]. S. rhizophila also forms the core with a few other soil bacteria which participates in the degradation of lignocellulose[11].

With the potential to colonize plants' outer surface and S. rhizophila’s close relation to Stenotrophomonas maltophilia, there have been raised concerns over harvesting products whose surface has been colonized [5]. However, S. rhizophila does not carry the pathogenic traits essential to S. maltophilia's harm to humans and is incapable of growing in human body temperatures as it only grows below 37 °C [9]. Since bacteria that participate in biofilms enjoy increased lateral gene transfer[8], there is growing concern that the addition of a few new genes could induce a potent pathogen.[2]

References

[1] NCBI "Stenotrophomonas rhizophila". NCBI Genome Assembly. 2013. Web. 21 Apr 2017.

[2] Alavi, P., Starcher, M., Thallinger, G., Zachow, C., Müller, H., and Berg, G. "Stenotrophomonas comparative genomics reveals genes and functions that differentiate beneficial and pathogenic bacteria." BMC Genomics. BioMed Central, 18 June 2014. Web. 21 Apr. 2017.

[3] Roder, A., Hoffmann, E., Hagemann, M., and Berg, G. "Synthesis of the compatible solutes glucosylglycerol and trehalose by salt-stressed cells of Stenotrophomonas strains." FEMS Microbiology Letters. Oxford University Press, 09 Jan. 2006. Web. 21 Apr. 2017.

[4] Alavi, P., Starcher, M., Zachow, C.S., Berg, G., and Müller, H. "Root-microbe systems: The effect and mode of interaction of Stress Protecting Agent (SPA) Stenotrophomonas rhizophila DSM14405T." Frontiers in Plant Science. Frontiers in Plant Science, 14 May 2013. Web. 21 Apr. 2017.

[5] Schmidt, C., Alavi, M., Cardinale, M., Müller, H., and Berg, G. "Stenotrophomonas rhizophila DSM14405T promotes plant growth probably by altering fungal communities in the rhizosphere." SpringerLink. Springer-Verlag, 03 May 2012. Web. 20 Apr. 2017.

[6] Ryan, R., Monchy, S., Cardinale, M., Taghavi, S., Crossman, L., Avison, M., Berg, G., Lelie, D., and Dow, J. "The versatility and adaptation of bacteria from the genus Stenotrophomonas." Nature Reviews Microbiology 7.7 (2009): 514-25. Web.

[7] Ren, D., Madsen, J.S., de la Cruz-Perera, C.I. et al. "High-Throughput Screening of Multispecies Biofilm Formation and Quantitative PCR-Based Assessment of Individual Species Proportions, Useful for Exploring Interspecific Bacterial Interactions" Microbial Ecology 68.1 (2014): 146-54. Web.

[8] Ren, D., Madsen, J., Sorensen, S., Burmolle, M. “High Prevalence of Biofilm Synergy among Bacterial Soil Isolates in Cocultures Indicates Bacterial Interspecific Cooperation.” The ISME Journal 9.1 (2015): 81–89. PMC. Web. 21 Apr. 2017.

[9] Berg, G., and Martinez, J. "Friends or Foes: Can We Make a Distinction between Beneficial and Harmful Strains of the Stenotrophomonas Maltophilia Complex?" Frontiers in Microbiology 6 (2015): 241. PMC. Web. 24 Apr. 2017.

[10] Berg, G., Egamberdieva, D., Lugtenberg, B., Hagemann, M. “Symbiotic Plant–Microbe Interactions: Stress Protection, Plant Growth Promotion, and Biocontrol by Stenotrophomonas.” Cellular Origin, Life in Extreme Habitats and Astrobiology 17 (2010): 445–60. Web. 21 Apr. 2017.

[11] de Lima Brossi, M.J., Jiménez, D.J., Cortes-Tolalpa, L., van Elsas, J. “Soil-Derived Microbial Consortia Enriched with Different Plant Biomass Reveal Distinct Players Acting in Lignocellulose Degradation.” Microbial Ecology 71.3 (2016): 616–27. Web. 21 Apr. 2017.

[12] Wolf, A., Fritze, A., Hagemann, M., Berg, G. “Stenotrophomonas rhizophila sp. nov., a novel plant-associated bacterium with antifungal properties.” International Journal of Systematic and Evolutionary Microbiology 52 (2002): 1937-44. Web. 21 Apr. 2017.

Author

Page authored by Esmeralda Martinez and Micah Maassen, students of Prof. Jay Lennon at Indiana University.