Bacteriophage Mu repressor as a target for the Escherichia coli ATP-dependent Clp Protease.

Laachouch, Jamal E; Desmet, Lucie; Geuskens, Vincent; Grimaud, Régis; Toussaint, Ariane

doi:10.1002/j.1460-2075.1996.tb00374.x

Cited by 56 publications

(48 citation statements)

References 38 publications

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“…Wawrzynow et al (42) have hypothesized that determinants on the substrate specify whether ClpX will release the substrate to promote protein folding or present the substrate to ClpP for degradation. Determinants necessary for degradation are present in the C-terminal regions of the ClpXP substrates MuA (28,41) and Mu Vir repressor (43). The last 10 amino acids at the C terminus of MuA, when attached to the C terminus of the phage P22 Arc protein, are sufficient to convert Arc into a ClpXP substrate (41).…”

Section: Clpxp Promotes Transition From Stc1 To Stc2 Leaving Activatmentioning

confidence: 99%

“…The last 10 amino acids at the C terminus of MuA, when attached to the C terminus of the phage P22 Arc protein, are sufficient to convert Arc into a ClpXP substrate (41). However, when 7 amino acids from the C terminus of Vir3061 are fused to F plasmid proteins CcdA and CcdB, only CcdA becomes a ClpXP substrate (43). This leaves open the possibility that additional determinants present in Arc and CcdA but not in CcdB are also needed to promote degradation of the substrate by the protease.…”

Section: Clpxp Promotes Transition From Stc1 To Stc2 Leaving Activatmentioning

confidence: 99%

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Versatile Action of Escherichia coli ClpXP as Protease or Molecular Chaperone for Bacteriophage Mu Transposition

Jones

Welty

Nakai

1998

Journal of Biological Chemistry

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Section: Clpxp Promotes Transition From Stc1 To Stc2 Leaving Activatmentioning

confidence: 99%

Section: Clpxp Promotes Transition From Stc1 To Stc2 Leaving Activatmentioning

confidence: 99%

Versatile Action of Escherichia coli ClpXP as Protease or Molecular Chaperone for Bacteriophage Mu Transposition

Jones

Welty

Nakai

1998

Journal of Biological Chemistry

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“…Mu repressor is also a target of this protease (7,9), and SsrA is essential for the thermal induction of Mucts62 (29). To elucidate the mechanism by which SsrA affects the physiology of Mu, and in particular the key regulator of the lysis-lysogeny decision, Repc, we have studied the effect of different ssrA alleles on prophage induction and on the physical properties of the repressor.…”

Section: Ssra Charging With Alanine Decreases Mu Repressionmentioning

confidence: 99%

“…Muvir repressors carry a frameshift mutation that alters the C terminus end of Repc, making the protein hypersensitive to degradation by the host ATP-dependent protease ClpXP. This property is transmitted to the more stable wild-type (WT) and cts repressors, enabling Muvir phages to induce the resident prophage on superinfection of a WT Muc ϩ or Mucts lysogen (4)(5)(6)(7)(8)(9). Four point mutations in the N-terminal part of Repc (cts45:S18L; cts71:M28I; cts25:D43G; and cts62:R47Q) (Fig.…”

mentioning

confidence: 99%

The tRNA function of SsrA contributes to controlling repression of bacteriophage Mu prophage

Ranquet

Geiselmann

Toussaint

2001

Proc. Natl. Acad. Sci. U.S.A.

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The small regulatory RNA SsrA has both tRNA and mRNA activities. It charges alanine and interacts with stalled ribosomes, allowing for translation to resume on the SsrA mRNA moiety. Hence, unfinished peptides carry a short amino acid tag, which serves as a signal for degradation by energy-dependent proteases. In SsrAdefective Escherichia coli strains, thermoinducible mutants of the transposable bacteriophage Mu (Mucts) are no longer induced at high temperature. Here we show that truncated forms of the key regulator of Mu lysogeny, the repressor Repc, accumulate in the absence of SsrA. These forms resemble C-terminally truncated dominant Mu repressor mutants previously isolated from Mucts, which are no longer thermoinducible and bind operator DNA with a high affinity even at high temperature. Using various ssrA alleles, we demonstrate the importance of SsrA charging on the ribosome for controlling Mu prophage repression. Our results thus substantiate the previous observation that trans-translation is not the only function of the SsrA. The alternative function of SsrA appears to influence the stability of Mu lysogens by controlling the translation of the C-terminal domain of the repressor protein, which modulates the affinity of the protein for DNA and its susceptibility to proteolytic degradation.Mu repressor ͉ tmRNA ͉ truncated proteins ͉ lysis-lysogeny switch

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“…N-terminal domains including destabilizing residues of the N-end rule also specifically target proteins for degradation by the proteases such as ClpP of E. coli (218,244). Proteins with destabilizing nonpolar C-termini are recognized by Clp and FtsH proteins in E. coli (245)(246)(247)(248)(249)(250). This includes the ssrA-tagging system which adds nonpolar C-termini to damaged proteins produced from 3'-truncated mRNA (251), mRNAs which contain rare codons, and during tRNA scarcity (252).…”

Section: Ubiquitin-independentmentioning

confidence: 99%

Proteasomes in the archaea from structure to function

Maupin-Furlow¹

2000

Front Biosci

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Bacteriophage Mu repressor as a target for the Escherichia coli ATP-dependent Clp Protease.

Cited by 56 publications

References 38 publications

Versatile Action of Escherichia coli ClpXP as Protease or Molecular Chaperone for Bacteriophage Mu Transposition

Versatile Action of Escherichia coli ClpXP as Protease or Molecular Chaperone for Bacteriophage Mu Transposition

The tRNA function of SsrA contributes to controlling repression of bacteriophage Mu prophage

Proteasomes in the archaea from structure to function

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