Pxr sRNA

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Pxr sRNA
Pxr.png
Secondary structure of Pxr sRNA.
Identifiers
SymbolPxr
Rfam RF01812
Other data
RNA typesRNA
Domain(s) Myxococcus xanthus, Stigmatella aurantiaca
PDB structures PDBe

Pxr sRNA is a regulatory RNA which downregulates genes responsible for the formation of fruiting bodies in Myxococcus xanthus . [1] Fruiting bodies are aggregations of myxobacteria formed when nutrients are scarce, [2] the fruiting bodies permit a small number of the aggregated colony to transform into stress-resistant spores. [3]

Contents

Pxr exists in two forms: Pxr-L (a long form) and Pxr-S which is shorter. The short form was found to be expressed in cells during growth but is rapidly repressed during starvation. This finding implies that Pxr-S is specifically responsible for inhibiting the fruiting body development during cell growth when nutrients are abundant. [1]

Pxr homologs have only been found in one other taxon, namely Stigmatella aurantiaca . Homologs were not found in any other myxobacteria (such as Sorangium cellulosum [4] or Anaeromyxobacter dehalogenans [5] ) which suggests the Pxr RNA gene may have a recent evolutionary origin in the sub-clade Myxococcales. [1]

PxR sRNA folds into 3 steam loops. SL1 and SL 2 are highly conserved across mycobacteria and SL1 is necessary for the regulatory function. However, a conserved eight-base-pair segment of the variable SL3 is necessary for PxR accumulation and multicellular development. [6]

M. xanthus obligate cheat and phoenix phenotypes

Several mutations in the Pxr sRNA gene have been observed. [7] The first mutation causes an obligate cheat (OC) phenotype to emerge, these bacteria exploit the fruiting bodies of wild-type M. xanthus to sporulate more efficiently. This phenotype is thought to be caused by a mutation which prevents the repression of Pxr-S, thereby inhibiting the formation of fruiting bodies indefinitely. If Pxr-S is derived from Pxr-L, it may be that RNAi-like processing elements have been knocked out. [1]

In a laboratory experiment, the OC phenotype out-competed and excluded the wild type, eventually bringing about a population crash when there were not enough wild type bacteria to exploit. [7] After this event, a new phenotype emerged via spontaneous mutation dubbed phoenix (PX). [1] The PX phenotype was developmentally superior to both OC and wt, it was able to sporulate autonomously - without forming fruiting bodies and with high efficiency. [7] Two-component system operon (histidine kinase gene and a σ54 response regulator) is associated with production and processing of Pxr sRNA. [8]

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References

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