Scott Alper scite author profile

Cell fate is determined by cell-specific activation of transcription factor sigma F after asymmetric division during sporulation by Bacillus subtilis. The activity of sigma F is governed by SpoIIAA, SpoIIAB, and SpoIIE, a membrane protein localized at the polar septum. SpoIIAB binds to and inhibits sigma F, and SpoIIAA inhibits SpoIIAB, which prevents SpoIIAB from binding to sigma F. SpoIIAB is also a serine kinase that inactivates SpoIIAA. Here, it is demonstrated that SpoIIE dephosphorylates SpoIIAA-P and overcomes SpoIIAB-mediated inhibition of sigma F. The finding that SpoIIE is a serine phosphatase links asymmetric division to the pathway governing cell-specific gene transcription.

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Specificity and Complexity of the Caenorhabditis elegans Innate Immune Response

Alper

McBride

Lackford³

et al. 2007

Molecular and Cellular Biology

165

193

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In response to infection, Caenorhabditis elegans produces an array of antimicrobial proteins. To understand the C. elegans immune response, we have investigated the regulation of a large, representative sample of candidate antimicrobial genes. We found that all these putative antimicrobial genes are expressed in tissues exposed to the environment, a position from which they can ward off infection. Using RNA interference to inhibit the function of immune signaling pathways in C. elegans, we found that different immune response pathways regulate expression of distinct but overlapping sets of antimicrobial genes. We also show that different bacterial pathogens regulate distinct but overlapping sets of antimicrobial genes. The patterns of genes induced by pathogens do not coincide with any single immune signaling pathway. Thus, even in this simple model system for innate immunity, striking specificity and complexity exist in the immune response. The unique patterns of antimicrobial gene expression observed when C. elegans is exposed to different pathogens or when different immune signaling pathways are perturbed suggest that a large set of yet to be identified pathogen recognition receptors (PRRs) exist in the nematode. These PRRs must interact in a complicated fashion to induce a unique set of antimicrobial genes. We also propose the existence of an "antimicrobial fingerprint," which will aid in assigning newly identified C. elegans innate immunity genes to known immune signaling pathways.

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Role of Adenosine Nucleotides in the Regulation of a Stress-response Transcription Factor inBacillus subtilis

Alper

Dufour

Garsin

et al. 1996

Journal of Molecular Biology

125

167

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Scott Alper

An adenosine nucleotide switch controlling the activity of a cell type-specific transcription factor in B. subtilis

Activation of Cell-Specific Transcription by a Serine Phosphatase at the Site of Asymmetric Division

Specificity and Complexity of the Caenorhabditis elegans Innate Immune Response

Role of Adenosine Nucleotides in the Regulation of a Stress-response Transcription Factor inBacillus subtilis

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