@article{open1515,
          volume = {196},
          number = {1},
           month = {January},
          author = {Sanjay Kumar and Pavitra Kanudia and Subramanian Karthikeyan and Pradip K Chakraborti},
            note = {Copyright of this article belongs to American Society for Microbiology.},
           title = {Identification of crucial amino acids of bacterial Peptide deformylases affecting enzymatic activity in response to oxidative stress.},
       publisher = {ASM},
            year = {2014},
         journal = {Journal of bacteriology},
           pages = {90--99},
        keywords = {Peptide deformylase;Mycobacterium tuberculosis},
             url = {http://crdd.osdd.net/open/1515/},
        abstract = {Peptide deformylase (PDF) is an essential bacterial metalloprotease involved in deformylation of N-formyl group from nascent polypeptide chains during protein synthesis. Iron-containing variants of this enzyme from Salmonella enterica serovar Typhimurium (sPDF) and Mycobacterium tuberculosis (mPDF), although inhibited by oxidizing agents like H2O2, exhibited strikingly different 50\% inhibitory concentrations (IC50s) that ranged from nanomolar (sPDF) to millimolar (mPDF) levels. Furthermore, the metal dissociation rate was higher in sPDF than mPDF. We hypothesized that a restriction in entry of environmental oxygen or oxidizing agents into the active site of mPDF might be the cause for such discrepancies between two enzymes. Since the active-site residues of the two proteins are similar, we evaluated the role of the oxidation-prone noncatalytic residue(s) in the process. Amino acid sequence analysis revealed that Cys-130 of sPDF corresponds to Met-145 of mPDF and that they are away from the active sites. Swapping methionine with cysteine in mPDF, the M145C protein displayed a drastic decrease in the IC50 for H2O2 and an increased metal dissociation rate compared to the wild type. Matrix-assisted laser desorption ionization (MALDI) analysis of a trypsin-digested fragment containing Cys-145 of the M145C protein also indicated its increased susceptibility to oxidation. To incorporate residues identical to those of mPDF, we created a double mutant of sPDF (C130M-V63C) that showed increased IC50 for H2O2 compared to the wild type. Interestingly, the oxidation state of cysteines in C130M-V63C was unaffected during H2O2 treatment. Taken together, our results unambiguously established the critical role of noncatalytic cysteine/methionine for enzymatic sensitivity to H2O2 and, thus, for conferring behavioral distinction of bacterial PDFs under oxidative stress conditions.}
}