Supplementary MaterialsFigure S1: Dose-dependent interaction of the Kis antitoxin to the

Supplementary MaterialsFigure S1: Dose-dependent interaction of the Kis antitoxin to the CcdB toxin analyzed by SPR. Kis was able to inhibit the activation of DNA gyrase-mediated cleavage of DNA by CcdB, albeit less efficiently than CcdA. We further show that physical relationships between the toxins and antitoxins of the different systems do happen and determine the stoichiometry of the complexes created. We found that CcdB did not degrade RNA nor did Kid possess any reproducible effect on the tested DNA gyrase activities, suggesting that these toxins evolved to reach different, rather than common, cellular targets. Intro The and systems of plasmids F and R1 were the two first proteic bacterial toxin-antitoxin (TA) systems recognized [1], [2]. Both TA modules carry antitoxin and toxin genes of small and related sizes that are structured within an operon. The antitoxin protein of each system interacts with its cognate toxin to neutralise the activity of the toxin, and also prospects to Cilengitide pontent inhibitor the formation of an efficient repressor [3]C[7]. The toxins of the and systems take action on different focuses on: CcdB focuses on and inhibits DNA gyrase [8], while Kid (identical to PemK) is definitely a specific endoribonuclease that inhibits translation and additional RNA-dependent processes [9], [10]. The crystal constructions of CcdB [11] and Kid [12] have been resolved. In spite of practical differences, comparison of these constructions indicated that both toxins share a common structural module [12]. This structural homology prompted an positioning between the CcdB and Kid toxins that was hard to detect otherwise due to the low similarity in their amino-acid sequences. Cilengitide pontent inhibitor The antitoxins of the and systems have been reported not to have cross-neutralizing activities within the toxin of the additional system [13]. However, alignments between the antitoxins of these systems have been proposed Cilengitide pontent inhibitor [13], [14] in support of the hypothesis of their common source. The crystal structure of MazE-MazF (also called ChpAI and ChpAK [15]), the antitoxin and toxin proteins of a system homologous to found in the chromosome of antitoxin protein) share a high degree of similarity and the structures of the MazF (in complex [14]) and Kid (antitoxin-free [12]) toxins Cilengitide pontent inhibitor are very related. The practical corporation of the CcdA and Kis antitoxins is also related, with an N-terminal region specifically involved in rules and a C-terminal region more involved in toxin neutralization [7], [13]. These antitoxins share clear homology with the MazE antitoxin that forms a dimer in which the N-terminal region is organized; the C-terminal region of MazE is definitely disorganized in remedy and in the dimer make specific contacts with the toxin that lead to its neutralization [5], [14], [16]. This structural info suggests that the toxins and antitoxins of the and systems could interact in a similar way. In the case of Kid and Kis binding, 4 different connection sites have been proposed, 3 of them involving STMY the C-terminal region of the antitoxin and the 4th one diminishing the N-terminal region of Kis and the toxin [17]. Practical or physical relationships between toxin and antitoxins of homologous TA systems have been previously reported [17], [18]. By native mass spectrometry and NMR spectroscopy, relationships between Kid and MazE antitoxin, that neutralized the activity of the Kid toxin, were analysed. The pattern of interaction and the stoichiometry of the complexes formed (heterotetramers instead of heterohexamers) changed in these relationships. Further structural info on complexes of CcdB and a gyrase fragment [19] and of Kid and its RNA target [20] showed the RNase and gyrase-binding activities are separated in these toxins which open the possibility of their coexistence in the common ancestor. Taken collectively, the available info suggests that the and systems could derive from a common ancestor in which the toxins evolved to reach different targets and the antitoxins co-evolved with their toxins to neutralise their activity. Since detailed structural and mechanistic info Cilengitide pontent inhibitor is now available.