Chris Rhodes Week 11: Difference between revisions

Revision as of 17:30, 9 November 2011

Article

The article we will be working with is Unique Flexibility in Energy Metabolism Allows Mycobacteria to Combat Starvation and Hypoxia Berney et al. 2010

The data sets for the article can be found here M. smeg DNA Arrays

Citation: Berney, Michael, and Gregory M. Cook. "Unique Flexibility in Energy Metabolism Allows Mycobacteria to Combat Starvation and Hypoxia." Ed. David M. Ojcius. PLoS ONE 5.1 (2010): E8614. Print.

10 Terms

Obligate aerobes:
Hypoxia:
Exogenus:
Real Time PCR:
Chemostat:
Colony forming unit:

Outline

Introduction

Mycobacteria have an extraordinary ability to adapt and survive in extreme conditions, but the exact mechanisms behind these adaptations is still fairly under-researched.
Previous experiments have studied mycobacteria under conditions of low oxygen, nutrient starvation, and extended stationary phase but the accuracy and scope of their results have been limited by their methods of experimentation.
This experiment hopes to better study the effects of extreme environments on mycobacteria by performing experiments using continuous cultures of Mycobacterium smegmatis
The use of continuous cultures allows this experiment to study various environmental conditions while still being able to control and maintain the growth rate of the cultured bacteria.
Previous studies by Beste et al. 2007 and Bacon et al. 2004 have implemented continuous cultures as a means of studying environmental effects on mycobacteria gene expression, but these experiments only studied the effects of a singular limiting factor i.e. low oxygen.
There is yet to be a study that observes the effects that simultaneous conditions of low oxygen and carbon starvation have on the gene expressions of mycobacteria.
The goal of this experiment is to study the effects that decreasing oxygen level has on the transcriptional response of a carbon-limited continuous culture of Mycobacterium smegmatis at varying growth rates.

Methods

Results

Figure 1
- A: Shows a graph of OD₆₀₀ representing bacterial growth and the level of glycerol in culture versus time. This shows that the rate at which glycerol levels decline (consumed by the cells) is proportional to the rate of cell growth in the culture. Glycerol is used as the carbon limiting agent meaning that glycerol levels represent the remaining the food supply of the culture. During steady state shown in the graph there is no longer cellular growth because the glycerol has been depleted.
- B and C: Shows the fluorescent microscopy of the fast growing M. smeg (B) and the slow growing M. smeg (C). In the fast growing sample, the M. smeg cells are significantly longer (7X) and are fewer in number than the slow growing sample cells.
Table 1: Shows a comparison of various conditions of each of the two culture growth rates including dilution rates, steady state OD₆₀₀, concentration of viable cells in culture, steady state glycerol concentrations, membrane potential, and proton motive force. The fast growing culture is represented by the dilution rate of 0.15 and the slow growing culture by the dilution rate of 0.01. The OD₆₀₀ and CFU respectively indicate the fast growing culture produces a larger amount of cells than does the slow growing culture, but the fast growing culture contains a smaller percentage of viable cells. The membrane potential and proton motive force indicate that despite the differences in cell viability and cell size between the two cultures, the resulting cells are energetically comparable.
From the DNA Microarray data collected it was found that there were 1294 genes that were differentially expressed in the low dilution rate culture when compared to the high dilution rate culture. Of these genes, 691 were induced and 603 were repressed.
There was also differential expression of genes between different oxygen levels of low dilution rate cultures. At 2.5% oxygen the culture contained 68 induced and 91 repressed genes compared to the low dilution rate culture at 50% oxygen. At 0.6% oxygen the culture contained 429 induced and 441 repressed genes compared to the 50% oxygen culture.
Figure 2: Shows a pictorial representation of the proposed scheme of enzymes preferentially used by M. smeg for metabolism under energy-limited and oxygen-limited conditions. Each enzyme included in each scheme was shown to be up-regulated during the experiment by a certain numerical factor which is shown in red next to each enzyme. The up-regulation of each of the enzymes indicates the increased usage of the cellular pathways that utilize those enzymes. This means that up-regulation of an enzyme can be considered as the up-regulation of the pathway the enzyme is involved with.
Table 2:

Disscussion

@@ Line 1: / Line 1: @@
+==Article==
+The article we will be working with is [http://www.plosone.org/article/info%3Adoi%2F10.1371%2Fjournal.pone.0008614#pone.0008614.s002 ''Unique Flexibility in Energy Metabolism Allows Mycobacteria to Combat Starvation and Hypoxia''] Berney et al. 2010
+The data sets for the article can be found here [http://www.ebi.ac.uk/arrayexpress/experiments/E-GEOD-17520 M. smeg DNA Arrays]
+Citation: Berney, Michael, and Gregory M. Cook. "Unique Flexibility in Energy Metabolism Allows Mycobacteria to Combat Starvation and Hypoxia." Ed. David M. Ojcius. PLoS ONE 5.1 (2010): E8614. Print.
 ==10 Terms==
 #Obligate aerobes:
@@ Line 29: / Line 35: @@
 **B and C: Shows the fluorescent microscopy of the fast growing M. smeg (B) and the slow growing M. smeg (C). In the fast growing sample, the M. smeg cells are significantly longer (7X) and are fewer in number than the slow growing sample cells.
 *Table 1: Shows a comparison of various conditions of each of the two culture growth rates including dilution rates, steady state OD<sub>600</sub>, concentration of viable cells in culture, steady state glycerol concentrations, membrane potential, and proton motive force. The fast growing culture is represented by the dilution rate of 0.15 and the slow growing culture by the dilution rate of 0.01. The  OD<sub>600</sub> and CFU respectively indicate the fast growing culture produces a larger amount of cells than does the slow growing culture, but the fast growing culture contains a smaller percentage of viable cells. The membrane potential and proton motive force indicate that despite the differences in cell viability and cell size between the two cultures, the resulting cells are energetically comparable.
-*Figure 2:
+*From the DNA Microarray data collected it was found that there were 1294 genes that were differentially expressed in the low dilution rate culture when compared to the high dilution rate culture. Of these genes, 691 were induced and 603 were repressed.
+*There was also differential expression of genes between different oxygen levels of low dilution rate cultures. At 2.5% oxygen the culture contained 68 induced and 91 repressed genes compared to the low dilution rate culture at 50% oxygen. At 0.6% oxygen the culture contained 429 induced and 441 repressed genes compared to the 50% oxygen culture.
+*Figure 2: Shows a pictorial representation of the proposed scheme of enzymes preferentially used by M. smeg for metabolism under energy-limited and oxygen-limited conditions. Each enzyme included in each scheme was shown to be up-regulated during the experiment by a certain numerical factor which is shown in red next to each enzyme. The up-regulation of each of the enzymes indicates the increased usage of the cellular pathways that utilize those enzymes. This means that up-regulation of an enzyme can be considered as the up-regulation of the pathway the enzyme is involved with.
+*Table 2:
 '''Disscussion'''

Chris Rhodes Week 11: Difference between revisions

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