Team:Goettingen/Team/Array

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===Array Team===
===Array Team===
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<p> The genome of the Gram-positive model bacterium <i>Bacillus subtilis</i> contains the <i>disA, cdaA</i>, and </i>cdaS</i> genes encoding enzymatically active adenylate cyclases (Mehne <i>et al.</i> 2013). By using the microarray technique we would like to analyze how many genes are regulated by c-di-AMP in <i>B. subtilis</i>. We are not only interested in the impact of c-di-AMP on the transcriptome, we also hope to identify novel regulatory elements (i.e. riboswitches) that bind to the signaling molecule. In our experiments we use three different <i>B. subtilis</i> strains. The wild-type strain contains all three diadenylatecyclases (DisA, CdaA, and CdaS). The second strain is a <i>disA</i> mutant strain lacking DisA, which was shown to be involved in DNA metabolism (Witte <i>et al.</i> 2008). This strain should produce less c-di-AMP than the isogenic parent strain. The third strain synthesizes a hyperactive CdaS mutant variant, which produces a lot of c-di-AMP. In our microarray experiments we will compare the transcriptomes of each mutant strain with that of the wild-type strain. Moreover, we would like to create a triple knock-out mutant (<i>ΔdisA, ΔcdaA, ΔcdaS</i>) lacking all diadenylate cyclases. We try to construct the triple knock-out mutant by feeding with exogenous c-di-AMP. </p>
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<p> The genome of the Gram-positive model bacterium <i>Bacillus subtilis</i> contains the <i>disA, cdaA</i>, and </i>cdaS</i> genes encoding the three enzymatically active adenylate cyclases DisA, CdaA, and CdaS (Mehne <i>et al.</i> 2013). By using the microarray technique we would like to analyze how many genes are regulated by c-di-AMP in <i>B. subtilis</i>. We are not only interested in the impact of c-di-AMP on the transcriptome, we also hope to identify novel regulatory elements (i.e. riboswitches) that bind to the signaling molecule. In our experiments we use three different <i>B. subtilis</i> strains. The wild-type strain contains all three diadenylatecyclases (DisA, CdaA, and CdaS). The second strain is a <i>disA</i> mutant strain lacking DisA, which was shown to be involved in DNA metabolism (Witte <i>et al.</i> 2008). This strain should produce less c-di-AMP than the isogenic parent strain. The third strain synthesizes a hyperactive CdaS mutant variant, which produces a lot of c-di-AMP. In our microarray experiments we will compare the transcriptomes of each mutant strain with that of the wild-type strain. Moreover, we would like to create a triple knock-out mutant (<i>ΔdisA, ΔcdaA, ΔcdaS</i>) lacking all diadenylate cyclases. We try to construct the triple knock-out mutant by feeding with exogenous c-di-AMP. </p>
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Revision as of 18:23, 29 September 2013





The beast and its Achilles heel:

 A novel target to fight multi-resistant pathogenic bacteria



Array Team

The genome of the Gram-positive model bacterium Bacillus subtilis contains the disA, cdaA, and cdaS genes encoding the three enzymatically active adenylate cyclases DisA, CdaA, and CdaS (Mehne et al. 2013). By using the microarray technique we would like to analyze how many genes are regulated by c-di-AMP in B. subtilis. We are not only interested in the impact of c-di-AMP on the transcriptome, we also hope to identify novel regulatory elements (i.e. riboswitches) that bind to the signaling molecule. In our experiments we use three different B. subtilis strains. The wild-type strain contains all three diadenylatecyclases (DisA, CdaA, and CdaS). The second strain is a disA mutant strain lacking DisA, which was shown to be involved in DNA metabolism (Witte et al. 2008). This strain should produce less c-di-AMP than the isogenic parent strain. The third strain synthesizes a hyperactive CdaS mutant variant, which produces a lot of c-di-AMP. In our microarray experiments we will compare the transcriptomes of each mutant strain with that of the wild-type strain. Moreover, we would like to create a triple knock-out mutant (ΔdisA, ΔcdaA, ΔcdaS) lacking all diadenylate cyclases. We try to construct the triple knock-out mutant by feeding with exogenous c-di-AMP.


Reference:

1. Mehne et al. (2013) Cyclic di-AMP homeostasis in Bacillus subtilis: both lack and high level accumulation of the nucleotide are detrimental for cell growth. J. Biol. Chem. 288:2004-2017.

2. Witte et al. (2008) Structural Biochemistry of a Bacterial Checkpoint Protein Reveals Diadenylate Cyclase Activity Regulated by DNA Recombination Intermediates. Mol. Cell. 30:167-178.

 

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