Abstract
Peptide deformylase (PDF) inhibitors have a strong potential to be used as a new class of antibiotics. However, recent studies have shown that the mitochondria of most eukaryotes, including humans, contain an essential PDF, PDF1A. The crystal structure of the Arabidopsis thaliana PDF1A (AtPDF1A), considered representative of PDF1As in general, has been determined. This structure displays several similarities to that of known bacterial PDFs. AtPDF1A behaves as a dimer, with the C-terminal residues responsible for linking the two subunits. This arrangement is similar to that of Leptospira interrogans PDF, the only other dimeric PDF identified to date. AtPDF1A is the first PDF for which zinc has been identified as the catalytic ion. However, the zinc binding pocket does not differ from the binding pockets of PDFs with iron rather than zinc. The crystal structure of AtPDF1A in complex with a substrate analog revealed that the substrate binding pocket of PDF1A displays strong modifications. The S1' binding pocket is significantly narrower, due to the creation of a floor from residues present in all PDF1As but not in bacterial PDFs. A true S3' pocket is created by the residues of a helical CD-loop, which is very long in PDF1As. Finally, these modified substrate binding pockets modify the position of the substrate in the active site. These differences provide guidelines for the design of bacterial PDF inhibitors that will not target mitochondrial PDFs.
Highlights
In all organisms, the protein synthesis machinery requires newly synthesized peptides to start systematically with methionine
Overall Structure of A. thaliana PDF1A—We studied the three-dimensional structure of A. thaliana PDF1A (AtPDF1A), using the mature protein
Compared with all currently known bacterial peptide deformylase (PDF) structures, mitochondrial Arabidopsis thaliana PDF1A (AtPDF1A) displays a number of important new properties, at the level of the metal specificity and of the substrate recognition pockets in the active site
Summary
N-formyl; PDF, peptide deformylase; AtPDF1A, A. thaliana PDF1A; EcPDF, E. coli PDF; PDF-In, peptide deformylase inhibitor(s); r.m.s., root mean square; HsPDF1A, Homo sapiens PDF1A; PEG, polyethylene glycol; LiPDF, L. interrogans PDF; Mes, 4-morpholineethanesulfonic acid; MKE, monomethyl ether. Unlike PDF1B, which is specific to plants and Apicomplexa, PDF1A is found in almost all eukaryotes Both classes of PDF1 are functional in deformylation and potently inhibited by actinonin [31, 32]. Unlike eukaryotic PDF1Bs, which do not differ significantly from bacterial PDFs in terms of their biochemistry [32] or three-dimensional structures [35], PDF1As have a number of specific features. They are active and stable with a zinc cation bound at the active site (TABLE ONE). Our findings provide guidelines for the design of PDF-In specific for bacterial enzymes
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