parD toxin-antitoxin system of plasmid R1--basic contributions, biotechnological applications and relationships with closely-related toxin-antitoxin systems.

Toxin-antitoxin systems, as found in bacterial plasmids and their host chromosomes, play a role in the maintenance of genetic information, as well as in the response to stress. We describe the basic biology of the parD/kiskid toxin-antitoxin system of Escherichia coli plasmid R1, with an emphasis on regulation, toxin activity, potential applications in biotechnology and its relationships with related toxin-antitoxin systems. Special reference is given to the ccd toxin-antitoxin system of plasmid F because its toxin shares structural homology with the toxin of the parD system.

A mutagenic analysis of the RNase mechanism of the bacterial Kid toxin by mass spectrometry.

Kid, the toxin of the parD (kis, kid) maintenance system of plasmid R1, is an endoribonuclease that preferentially cleaves RNA at the 5' of A in the core sequence 5'-UA(A/C)-3'. A model of the Kid toxin interacting with the uncleavable mimetic 5'-AdUACA-3' is available. To evaluate this model, a significant collection of mutants in some of the key residues proposed to be involved in RNA binding (T46, A55, T69 and R85) or RNA cleavage (R73, D75 and H17) were analysed by mass spectrometry in RNA binding and cleavage assays.

Interactions of Kid-Kis toxin-antitoxin complexes with the parD operator-promoter region of plasmid R1 are piloted by the Kis antitoxin and tuned by the stoichiometry of Kid-Kis oligomers.

The parD operon of Escherichia coli plasmid R1 encodes a toxin-antitoxin system, which is involved in plasmid stabilization. The toxin Kid inhibits cell growth by RNA degradation and its action is neutralized by the formation of a tight complex with the antitoxin Kis. A fascinating but poorly understood aspect of the kid-kis system is its autoregulation at the transcriptional level.

Structure and function of bacterial kid-kis and related toxin-antitoxin systems.

Toxin-antitoxin systems were discovered as plasmid auxiliary maintenance cassettes. In recent years, an increasing amount of structural and functional information has become available about the proteins involved, allowing the understanding of bacterial cell growth inhibition by the toxins on a molecular level. A well-studied TA system is formed by the proteins Kid and Kis, encoded by the parD operon of the Escherichia coli plasmid R1.

Interactions between the toxin Kid of the bacterial parD system and the antitoxins Kis and MazE.

The proteins Kid and Kis are the toxin and antitoxin, respectively, encoded by the parD operon of Escherichia coli plasmid R1. Kis prevents the inhibition of E. coli cell growth caused by the RNA cleavage activity of Kid.

The folding energy landscape of apoflavodoxin is rugged: hydrogen exchange reveals nonproductive misfolded intermediates.

Many native proteins occasionally form partially unfolded forms (PUFs), which can be detected by hydrogen/deuterium exchange and NMR spectroscopy. Knowledge about these metastable states is required to better understand the onset of folding-related diseases. So far, not much is known about where PUFs reside within the energy landscape for protein folding.

Model for RNA binding and the catalytic site of the RNase Kid of the bacterial parD toxin-antitoxin system.

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' side of the A residue in the nucleotide sequence 5'-UA(A/C)-3' of single-stranded regions.

The CXCR3 binding chemokine IP-10/CXCL10: structure and receptor interactions.

The structure of IP-10 was solved by NMR spectroscopy and represents the first structure from the class of agonists toward the receptor CXCR3. CXCR3 binding chemokines are unique in their ability to bind receptors from both the CC and CXC classes of chemokine receptors. An unusual structural feature of IP-10 was identified that may provide the basis for the ability of IP-10 to bind both CXCR3 and CCR3.