Pseudomonas syringae: Bioprecipitation Mechanisms and Implications: Difference between revisions

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<br>By Brandon Byrd <br>
<br>By Brandon Byrd <br>
 
Pseudomonas syringae have a significant impact on weather systems and ecosystems worldwide. This bacteria has previously been studied in depth as a plant pathogen, and it has recently been studied as a major contributor to bioprecipitation. P.syringae are rod shaped, gram-negative bacteria with polar flagella that is a plant pathogen to a wide variety of plant species at cold temperatures (Morris et al 2008). This bacteria is found in agricultural locations as well as non-agricultural locations such as clouds (Morris et al 2008). The fact that it has the capability to grow in a wide range of environments and ecosystems gives this bacteria the potential to drastically impact biogeographical systems. P.syringae also has an extraordinary ice nucleation activity which allows this bacteria to catalyze freezing water at warm temperatures which sparked interest in its role in the water cycle (Maki et al 1974). This is a major key for P.syringae’s effect on biogeographical systems. It is also important to further analyze their ice nucleation ability to understand the mechanisms in which they influence major weather systems such as the water cycle. Furthermore, how P.syringae can impact humans and biodiversity based on their influence on ecosystems and the environment.
<br>Introduce the topic of your paper.  What is your research question? What experiments have addressed your question?  Applications for medicine and/or environment?<br>
<br>Introduce the topic of your paper.  What is your research question? What experiments have addressed your question?  Applications for medicine and/or environment?<br>
<ref>[http://onlinelibrary.wiley.com/doi/10.1111/gcb.12447/epdf Morris, C.E. et al. “Bioprecipitation: a feedback cycle linking earth history, ecosystem dynamics and land use through biological ice nucleators in the atmosphere.” 2014. Global Change Biology 20: 341–351.]</ref>
<ref>[http://onlinelibrary.wiley.com/doi/10.1111/gcb.12447/epdf Morris, C.E. et al. “Bioprecipitation: a feedback cycle linking earth history, ecosystem dynamics and land use through biological ice nucleators in the atmosphere.” 2014. Global Change Biology 20: 341–351.]</ref>

Revision as of 22:02, 28 April 2016

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Overview


By Brandon Byrd
Pseudomonas syringae have a significant impact on weather systems and ecosystems worldwide. This bacteria has previously been studied in depth as a plant pathogen, and it has recently been studied as a major contributor to bioprecipitation. P.syringae are rod shaped, gram-negative bacteria with polar flagella that is a plant pathogen to a wide variety of plant species at cold temperatures (Morris et al 2008). This bacteria is found in agricultural locations as well as non-agricultural locations such as clouds (Morris et al 2008). The fact that it has the capability to grow in a wide range of environments and ecosystems gives this bacteria the potential to drastically impact biogeographical systems. P.syringae also has an extraordinary ice nucleation activity which allows this bacteria to catalyze freezing water at warm temperatures which sparked interest in its role in the water cycle (Maki et al 1974). This is a major key for P.syringae’s effect on biogeographical systems. It is also important to further analyze their ice nucleation ability to understand the mechanisms in which they influence major weather systems such as the water cycle. Furthermore, how P.syringae can impact humans and biodiversity based on their influence on ecosystems and the environment.
Introduce the topic of your paper. What is your research question? What experiments have addressed your question? Applications for medicine and/or environment?
[1]



A citation code consists of a hyperlinked reference within "ref" begin and end codes.

History

Fig 1. Scanning Electron Microscopy of Pseudomonas syringae on an ovary of a tomato plant. P.syringae is rod shaped, gram-negative, and has polar flagella. http://www.apsnet.org/publications/phytopathology/backissues/Documents/1983Articles/Phyto73n01_39.PDF.

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Bioprecipitation and P.syringae’s Role in Bioprecipitation

Fig.2 The bioprecipitation cycle diagram with two key factors that highlight the system. First, micro-organisms such as P.syringae that conduct the ice nucleation process. Second, the water vapor from plants, oceans, and aquatic environments that these micro-organism use in the atmosphere. http://onlinelibrary.wiley.com/doi/10.1111/gcb.12447/epdf.

Include some current research, with at least one figure showing data.

Mechanisms for Ice Nucleation

Fig.3 Ice nucleation activity of P.synerigae cells in the inner and outer membrane at varying temperatures. Different shapes indicate different treatments with varying concentrations of InaZ protein and InaZ protein enhanced E.coli membranes. http://www.pnas.org/content/83/19/7256.full.pdf.

Include some current research, with at least one figure showing data.

Ecological Implications of
P.syringae Bioprecipitation


Fig 4. The “Nitrogen Triangle” breaking down the three major parts of the nitrogen cycle. Also the important molecules at each step are included. http://slideplayer.com/slide/7448073/.

Include some current research, with at least one figure showing data.

Conclusion

References



Authored for BIOL 238 Microbiology, taught by Joan Slonczewski, 2016, Kenyon College.