Frameshift events associated with the lysyl-tRNA and the rare arginine codon, AGA, in Escherichia coli: a case study involving the human Relaxin 2 protein.

Human Relaxin 2 is an insulin-related peptide hormone with a mass of 19,084 Da. The mRNA contains a number of arginine codons that are rarely used by Escherichia coli to produce highly expressed proteins. As a result, expressing this recombinant protein in E. coli is problematic. When human Relaxin 2 was expressed in E. coli BL21 (DE3), several forms of the protein were made. One species had the expected molecular weight (19,084 Da). A second species observed had a molecular weight of 21,244 Da. A third minor species had a molecular weight of 17,118 Da. These aberrant molecular weights can be explained as follows. First, a sequence CGA-AAA-AAG-AGA, containing the rare arginine codons CGA and AGA was the site of the +1 frameshift that generated the 21,244 Da species. Since there was a limited supply of this arginyl-tRNA, the peptidyl-tRNA moved +1 nucleotide to occupy the codon and resumed protein synthesis. Second, a -1 frameshift associated with 'slippery A' sequence XXA-AAA-AAG accounted for 10% of the product with a mass of 17,118 Da. Presumably, the shift to -1 also occurred because there was a paucity of the arginyl-tRNAArgucu. Introduction of a plasmid coding for the cognate tRNA for AGA and site directed mutagenesis prevented the formation of both frameshift species.

Phylogenomic and biochemical characterization of three Legionella pneumophila polypeptide deformylases.

Legionella pneumophila is a gram-negative facultative intracellular human pathogen that can cause fatal Legionnaires' disease. Polypeptide deformylase (PDF) is a novel broad-spectrum antibacterial target, and reports of inhibitors of PDF with potent activities against L. pneumophila have been published previously. Here, we report the identification of not one but three putative pdf genes, pdfA, pdfB, and pdfC, in the complete genome sequences of three strains of L. pneumophila. Phylogenetic analysis showed that L. pneumophila PdfA is most closely related to the commonly known gamma-proteobacterial PDFs encoded by the gene def. PdfB and PdfC are more divergent and do not cluster with any specific bacterial or eukaryotic PDF. All three putative pdf genes from L. pneumophila strain Philadelphia 1 have been cloned, and their encoded products have been overexpressed in Escherichia coli and purified. Enzymatic characterization shows that the purified PDFs with Ni2+ substituted are catalytically active and able to remove the N-formyl group from several synthetic polypeptides, although they appear to have different substrate specificities. Surprisingly, while PdfA and PdfB with Zn2+ substituted are much less active than the Ni2+ forms of each enzyme, PdfC with Zn2+ substituted was as active as the Ni2+ form for the fMA substrate and exhibited substrate specificity different from that of Ni2+ PdfC. Furthermore, the catalytic activities of these enzymes are potently inhibited by a known small-molecule PDF inhibitor, BB-3497, which also inhibits the extracellular growth of L. pneumophila. These results indicate that even though L. pneumophila has three PDFs, they can be effectively inhibited by PDF inhibitors which can, therefore, have potent anti-L. pneumophila activity.