Darren D. Sledjeski scite author profile

DsrA RNA regulates both transcription, by overcoming transcriptional silencing by the nucleoidassociated H-NS protein, and translation, by promoting efficient translation of the stress factor, RpoS. These two activities of DsrA can be separated by mutation: the first of three stem-loops of the 85 nucleotide RNA is necessary for RpoS translation but not for anti-H-NS action, while the second stem-loop is essential for antisilencing and less critical for RpoS translation. The third stem-loop, which behaves as a transcription terminator, can be substituted by the trp transcription terminator without loss of either DsrA function. The sequence of the first stem-loop of DsrA is complementary with the upstream leader portion of rpoS messenger RNA, suggesting that pairing of DsrA with the rpoS message might be important for translational regulation. Mutations in the Rpos leader and compensating mutations in DsrA confirm that this predicted pairing is necessary for DsrA stimulation of RpoS translation. We propose that DsrA pairing stimulates RpoS translation by acting as an anti-antisense RNA, freeing the translation initiation region from the cis-acting antisense RNA and allowing increased translation.

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Escherichia coli Hfq has distinct interaction surfaces for DsrA, rpoS and poly(A) RNAs

Mikulecky

Kaw

Brescia

et al. 2004

Nat Struct Mol Biol

225

395

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The bacterial Sm-like protein Hfq facilitates RNA-RNA interactions involved in posttranscriptional regulation of the stress response. Specifically, Hfq helps pair noncoding RNAs (ncRNAs) with complementary regions of target mRNAs. To probe the mechanism of this pairing, we generated a series of Hfq mutants and measured their affinity for RNAs like those with which Hfq must associate in vivo. We tested the mutants' DsrA-dependent activation of rpoS, and their ability to stabilize DsrA ncRNA against degradation in vivo. Our results suggest that Hfq has two independent RNA-binding surfaces. In addition to a well-known site around the core of the Hfq hexamer, we observe interactions with the distal face of Hfq, a new locus with which mRNAs and poly(A) sequences associate. Our model explains how Hfq can simultaneously bind a ncRNA and its mRNA target to facilitate the strand displacement reaction required for Hfq-dependent translational regulation.Hfq protein from Escherichia coli was first described in connection with Qβ-phage replication 1,2 . Hfq has recently emerged as a central player in post-transcriptional gene regulation as mediated by bacterial ncRNAs [3][4][5][6] . Escherichia coli Hfq mutants show disrupted signaling in stress response pathways 7,8 , arising from the need for Hfq to mediate base-pairing between regulatory ncRNAs and their mRNA targets. Examples of these partnerships include DsrA-rpoS 7,9,10 , OxyS-fhlA 11,12 , OxyS-rpoS 13 , RprA-rpoS 14 , RyhBsodB [15][16][17] .Complexes between ncRNAs and their mRNA targets function in several ways. Most commonly, complexed structures lead to translational activation or repression by remodeling mRNA regulatory regions containing the ribosome-binding site (RBS) and/or start codon. Alternatively, the interaction can enhance decay of the target mRNA16 or simply block translation11. Clearly, Hfq facilitates base-pairing between ncRNAs and their targets, but how it does so is poorly understood. How the chaperone function relates to other Hfq activities such as the control of poly(A) tail elongation19 , 20 and regulation of mRNA stability21 , 22 is also unknown. COMPETING INTERESTS STATEMENTThe authors declare that they have no competing financial interests. NIH Public Access Author ManuscriptNat Struct Mol Biol. Author manuscript; available in PMC 2011 April 5. NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author ManuscriptHfq shares sequence similarity to the eukaryotic Lsm proteins [23][24][25][26][27] We addressed these questions through a mutational analysis of Hfq, probing in vitro binding to several model RNAs that represent species with which Hfq must interact. Hfq mutants were assayed in vivo using a reporter assay and RNA lifetime experiments. Together, the results support a model wherein at least two independent RNA-binding sites exist on the Hfq hexamer, and juxtaposition of bound RNAs facilitates base-pairing. RESULTS Hfq mutagenesisTo identify amino acids essential for RNA binding, we constructed a series of E. coli Hfq misse...

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The small RNA, DsrA, is essential for the low temperature expression of RpoS during exponential growth in Escherichia coli.

1996

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dsrA encodes a small, untranslated RNA. When over‐expressed, DsrA antagonizes the H‐NS‐mediated silencing of numerous promoters. Cells devoid of DsrA grow normally and show little change in the expression of a number of H‐NS‐silenced genes. Expression of a transcriptional fusion of lacZ to dsrB, the gene next to dsrA, is significantly lower in cells carrying mutations in dsrA. All expression of beta‐galactosidase from the dsrB::lacZ fusion is also dependent on the stationary phase sigma factor, RpoS. DsrA RNA was found to regulate dsrB::lacZ indirectly, by modulating RpoS synthesis. Levels of RpoS protein are substantially lower in a dsrA mutant, both in stationary and exponential phase cells. Mutations in dsrA decrease the expression of an RpoS::LacZ translational fusion, but not a transcriptional fusion, suggesting that DsrA is acting after transcription initiation. While RpoS expression is very low in exponential phase at temperatures of 30 degrees C and above, at 20 degrees C there is substantial synthesis of RpoS during exponential growth, all dependent on DsrA RNA. dsrA expression is also increased at low temperatures. These results suggest a new role for RpoS during exponential growth at low temperatures, mediated by DsrA.

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