Primary Structure Revision and Active Site Mapping of E. Coli Isoleucyl-tRNA Synthetase by Means of Maldi Mass Spectrometry

The correct amino acid sequence of E. coli isoleucyl-tRNA synthetase (IleRS) was established by means of peptide mapping by MALDI mass spectrometry, using a set of four endoproteases (trypsin, LysC, AspN and GluC). Thereafter, the active site of IleRS was mapped by affinity labeling with reactive analogs of the substrates. For the ATP binding site, the affinity labeling reagent was pyridoxal 5'-diphospho-5'-adenosine (ADP-PL), whereas periodate-oxidized tRNAIle, the 2',3'-dialdehyde derivative of tRNAIle was used to label the binding site for the 3'-end of tRNA on the synthetase. Incubation of either reagent with IleRS resulted in a rapid loss of both the tRNAIle aminoacylation and isoleucinedependent isotopic ATP-PPi exchange activities. The stoichiometries of IleRS labeling by ADP-PL or tRNAIleox corresponded to 1 mol of reagent incorporated per mol of enzyme. Altogether, the oxidized 3'-end of tRNAIle and the pyridoxal moiety of the ATP analog ADP-PL react with the lysyl residues 601 and 604 of the consensus sequence 601KMSKS605. Identification of the binding site for L-isoleucine or for non cognate amino acids on E. coli IleRS was achieved by qualitative comparative labeling of the synthetase with bromomethyl ketone derivatives of L-isoleucine (IBMK) or of the non-cognate amino acids valine (VBMK), phenylalanine (FBMK) and norleucine (NleBMK). Labeling of the enzyme with IBMK resulted in a complete loss of isoleucine-dependent isotopic [32P]PPi-ATP exchange activity. VBMK, NleBMK and FBMK were also capable of abolishing the activity of IleRS, FBMK being the less efficient in inactivating the synthetase. Analysis by MALDI mass spectrometry designated cysteines-462 and -718 as the target residues of the substrate analog IBMK on E. coli IleRS, whereas VBMK, NleBMK and FBMK labeled in common His-394, His-478 and Cys-718. In addition, VBMK and NleBMK, which are chemically similar to IBMK, were found covalently bound to Cys-462, and VBMK was specifically attached to His-332 (or His-337) of the synthetase. The amino acid residues labeled by the substrate analogs are mainly distributed between three regions in the primary structure of E. coli IleRS: these are segments [325-394], [451-479] and [591-604]. In the 3-D structures of IleRS from T. thermophilus and S. aureus, the [325-394] stretch is part of the editing domain, while fragments [451-479] and [591-604] representing the isoleucine binding domain and the dinucleotide (or Rossmann) fold domain, respectively, are located in the catalytic core. His-332 of E. coli IleRS, that is strictly conserved among all the available IleRS sequences is located in the editing active site of the synthetase. It is proposed that His-332 of E. coli IleRS participates directly in hydrolysis, or helps to deprotonate the hydroxyl group of threonine at the hydrolytic site

Recent advances in the characterization of peptidyl transferase center: zero-distance labeling of proteins at or near the catalytic site of human 80S or Escherichia coli 70S ribosomes by means of periodate-oxidized tRNA

International audiencePeriodate-oxidized tRNA (tRNAox), the 2’,3’-dialdehyde derivative of tRNA, was used as a zero-length active site-directed affinity labeling reagent, to covalently label proteins at the peptidyl transferase center (PTC), the catalytic site of the large ribosomal subunit. When human 80S or Escherichia coli 70S ribosomes were reacted separately with tRNAox positioned at the P-site, in the presence of an appropriate 12 mer mRNA, a set of two tRNAox-labeled ribosomal proteins was observed. These proteins referred to in this work as rPox1 and rPox2 exhibited comparable physico-chemical properties including apparent molecular weights. In the case of human 80S ribosome, the protein present in the major labeled tRNA-rPox1 covalent complex was identified as the 60S ribosomal protein L36a-like (RPL36AL) by mass spectrometry. The molecular weight of the minor labeled tRNA-rPox2 covalent complex was estimated from the data of the 1-D SDS-PAGE, and a deduced molecular weight of 34,000 + 2,000 Da for the ribosomal protein referred to as rPox2 designated protein RPL5 as the candidate minor labeled protein of human 80S ribosome. Search for candidate ribosomal proteins for the tRNAoxlabeled proteins rPox1 and rPox2 of 70S ribosome from E. coli designated RPL2 (M.W. 29,860 Da), the largest eubacterial rP as the tRNAox-labeled protein corresponding to the minor labeled human RPL5, and RPL15 (M.W. 14,980 Da) or RPL16 (M.W. 15,281 Da) as corresponding to the major labeled human RPL36A