Marguerite Lemonnier scite author profile

The toxin Kid and antitoxin Kis are encoded by the parD operon of Escherichia coli plasmid R1. Kid and its chromosomal homologues MazF and ChpBK have been shown to inhibit protein synthesis in cell extracts and to act as ribosome-independent endoribonucleases in vitro. Kid cleaves RNA preferentially at the 5 0 side of the A residue in the nucleotide sequence 5 0 -UA(A/C)-3 0 of single-stranded regions. Here, we show that RNA cleavage by Kid yields two fragments with a 2 0 :3 0 -cyclic phosphate group and a free 5 0 -OH group, respectively. The cleavage mechanism is similar to that of RNases A and T1, involving the uracil 2 0 -OH group. Via NMR titration studies with an uncleavable RNA mimic, we demonstrate that residues of both monomers of the Kid dimer together form a concatenated RNA-binding surface. Docking calculations based on the NMR chemical shifts, the cleavage mechanism and previously reported mutagenesis data provide a detailed picture of the position of the AUACA fragment within the binding pocket. We propose that residues D75, R73 and H17 form the active site of the Kid toxin, where D75 and R73 are the catalytic base and acid, respectively. The RNA sequence specificity is defined by residues T46, S47, A55, F57, T69, V71 and R73. Our data show the importance of these residues for Kid function, and the implications of our results for related toxins, such as MazF, CcdB and RelE, are discussed.

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Rho GTPase-activating bacterial toxins: from bacterial virulence regulation to eukaryotic cell biology

Lemonnier

Landraud

Lemichez

2007

FEMS Microbiol Rev

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Studies on the interactions of bacterial pathogens with their host have provided an invaluable source of information on the major functions of eukaryotic and prokaryotic cell biology. In addition, this expanding field of research, known as cellular microbiology, has revealed fascinating examples of trans-kingdom functional interplay. Bacterial factors actually exploit eukaryotic cell machineries using refined molecular strategies to promote invasion and proliferation within their host. Here, we review a family of bacterial toxins that modulate their activity in eukaryotic cells by activating Rho GTPases and exploiting the ubiquitin/proteasome machineries. This family, found in human and animal pathogenic Gram-negative bacteria, encompasses the cytotoxic necrotizing factors (CNFs) from Escherichia coli and Yersinia species as well as dermonecrotic toxins from Bordetella species. We survey the genetics, biochemistry, molecular and cellular biology of these bacterial factors from the standpoint of the CNF1 toxin, the paradigm of Rho GTPase-activating toxins produced by urinary tract infections causing pathogenic Escherichia coli. Because it reveals important connections between bacterial invasion and the host inflammatory response, the mode of action of CNF1 and its related Rho GTPase-targetting toxins addresses major issues of basic and medical research and constitutes a privileged experimental model for host-pathogen interaction.

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Multiple mRNAs encode peripherin, a neuronal intermediate filament protein.

et al. 1989

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Three cDNA clones of 1.6 (3u), 1.2 (5g) and 0.6 (5b) kbp with probes covering the 3' end of the two unexpected regions show that three distinct mRNAs correspond to the three cDNAs. Moreover, three peripherin products, two minor 61 and 56 kd products in addition to the major 58 kd peripherin, are observed when poly(A)+ RNA is in vitro translated, the 61 kd peripherin being translated from the 3u-selected RNA. The three RNAs originate from alternative splicing of a unique peripherin gene, thus generating polymorphism of peripherin.

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Disruption of the F plasmid partition complex in vivo by partition protein SopA

Lemonnier¹,

Bouet²,

Libante

et al. 2000

Molecular Microbiology

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The SopA protein plays an essential, though so far undefined, role in partition of the mini‐F plasmid but, when overproduced, it causes loss of mini‐F from growing cells. Our investigation of this phenomenon has revealed that excess SopA protein reduces the linking number of mini‐F. It appears to do so by disturbing the partition complex, in which SopB normally introduces local positive supercoiling upon binding to the sopC centromere, as it occurs only in plasmids carrying sopC and in the presence of SopB protein. SopA‐induced reduction in linking number is not associated with altered sop promoter activity or levels of SopB protein and occurs in the absence of changes in overall supercoil density. SopA protein mutated in the ATPase nucleotide‐binding site (K120Q) or lacking the presumed SopB interaction domain does not induce the reduction in linking number, suggesting that excess SopA disrupts the partition complex by interacting with SopB to remove positive supercoils in an ATP‐dependent manner. Destabilization of mini‐F also depends on sopC and SopB, but the K120Q mutant retains some capacity for destabilizing mini‐F. SopA‐induced destabilization thus appears to be complex and may involve more than one SopA activity. The results are interpreted in terms of a regulatory role for SopA in the oligomerization of SopB dimers bound to the centromere.

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