Characterisation of the MutS and MutL Proteins from the Pseudomonas avellanae Mismatch Repair (MMR) System.

The identification and analysis of the Pseudomonas avellanae mismatch repair system (MMR) were performed via sequencing and cloning the mutS and mutL genes and then analyzing the characteristics of the corresponding proteins studying their function and biological role in an E. coli heterologous system. In these studies, the P. avellanae MutS and MutL proteins were shown to localise at the nucleoid level, in a MutS-dependent manner as far as MutL is concerned, and were also able to complement the defect observed in both the mutS and mutL knockout strains of E. coli. In addition, their ability to form both homo and heterodimers between each other was shown by using the prokaryotic two-hybrid assay. Our results represent a first step to elucidate the MMR mechanism in plant pathogenic pseudomonads since the MMR genes were identified in P. syringae pathovars but there was no evidence on their action as effective repair products.

Division protein interaction web: identification of a phylogenetically conserved common interactome between Streptococcus pneumoniae and Escherichia coli.

The ability of each of the 11 Streptococcus pneumoniae division proteins to interact with itself and with each of the remaining proteins was studied in 66 combinations of protein pairs, using a bacterial two-hybrid system. Interactions (homo- or hetero-dimerizations) were detected between 37 protein pairs, whereas 29 protein pairs did not interact. In some cases, positive interactions of the S. pneumoniae proteins were confirmed by co-immunoprecipitation experiments in Escherichia coli. Comparison between the S. pneumoniae division protein interaction web and that of E. coli, the only micro-organisms for which the whole division interactome has been described systematically, was also performed. At least nine division proteins, ZapA, FtsZ, FtsA, FtsK, FtsQ/DivIB, FtsB/DivIC, FtsL, FtsI and FtsW, are believed to have a conserved function between these bacteria and thus we may say that a significant part of the interactions are conserved. Out of 45 protein pairs tested in both bacteria, 30 showed the same behaviour: 23 interacted while seven did not. In agreement with these results, cross-interactions between S. pneumoniae proteins and the corresponding E. coli orthologues were observed. Taken together, these results suggest a phylogenetically conserved minimal common interactome of the division proteins.

The Escherichia coli FtsK functional domains involved in its interaction with its divisome protein partners.

FtsK is a multifunctional protein involved in both cell division and chromosome segregation. As far as its role in cell division is concerned, FtsK is among the first divisome proteins that localizes at mid-cell, after FtsZ, FtsA and ZipA, and is required for the recruitment of the other divisome components. The ability of FtsK to interact with several cell division proteins, namely FtsZ, FtsQ, FtsL and FtsI, by the two-hybrid assay was already shown by our group. In this work, we describe the identification of the protein domain(s) involved in the interaction with the cell division partner proteins. The biological role of some interactions is also discussed.