The enzymes in this family are involved in the beta-lysylation step of the post-translational modification of translation elongation factor P (EF-P) on 'Lys-34'. They all display lysine 2,3-aminomutase activity, producing (R)-beta-lysine from (S)-alpha-lysine (L-lysine). Cannot use (S)-ornithine or (R)-alpha-lysine as a substrate. This product is the opposite enantiomer of the LAM_1 family.
Behshad E, Ruzicka FJ, Mansoorabadi SO, Chen D, Reed GH, Frey PA
Enantiomeric free radicals and enzymatic control of stereochemistry in a radical mechanism: the case of lysine 2,3-aminomutases
▸ Abstract
The product of yjeK in Escherichia coli is a homologue of lysine 2,3-aminomutase (LAM) from Clostridium subterminale SB4, and both enzymes catalyze the isomerization of (S)- but not (R)-alpha-lysine by radical mechanisms. The turnover number for LAM from E. coli is 5.0 min(-1), 0.1% of the value for clostridial LAM. The reaction of E. coli LAM with (S)-alpha-[3,3,4,4,5,5,6,6-(2)H8]lysine proceeds with a kinetic isotope effect (kH/kD) of 1.4, suggesting that hydrogen transfer is not rate-limiting. The product of the E. coli enzyme is (R)-beta-lysine, the enantiomer of the clostridial product. Beta-lysine-related radicals are observed in the reactions of both enzymes by electron paramagnetic resonance (EPR). The radical in the reaction of clostridial LAM has the (S)-configuration, whereas that in the reaction of E. coli LAM has the (R)-configuration. Moreover, the conformations of the beta-lysine-related radicals at the active sites of E. coli and clostridial LAM are different. The nuclear hyperfine splitting between the C3 hydrogen and the unpaired electron at C2 shows the dihedral angle to be 6 degrees, unlike the value of 77 degrees reported for the analogous radical bound to the clostridial enzyme. Reaction of (S)-4-thialysine produces a substrate-related radical in the steady state of E. coli LAM, as in the action of the clostridial enzyme. While (S)-beta-lysine is not a substrate for E. coli LAM, it undergoes hydrogen abstraction to form an (S)-beta-lysine-related radical with the same stereochemistry of hydrogen transfer from C2 of (S)-beta-lysine to the 5'-deoxyadenosyl radical as in the action of the clostridial enzyme. The resulting beta-lysyl radical has a conformation different from that at the active site of clostridial LAM. All evidence indicates that the opposite stereochemistry displayed by E. coli LAM is determined by the conformation of the lysine side chain in the active site. Stereochemical models for the actions of LAM from C. subterminale and E. coli are presented.
Biochemistry
2006;45(42):12639-12646
| PubMed ID:
17042480
Bailly M, de Crécy-Lagard V
Predicting the pathway involved in post-translational modification of elongation factor P in a subset of bacterial species
▸ Abstract
BACKGROUND: The bacterial elongation factor P (EF-P) is strictly conserved in bacteria and essential for protein synthesis. It is homologous to the eukaryotic translation initiation factor 5A (eIF5A). A highly conserved eIF5A lysine is modified into an unusual amino acid derived from spermidine, hypusine. Hypusine is absolutely required for eIF5A's role in translation in Saccharomyces cerevisiae. The homologous lysine of EF-P is also modified to a spermidine derivative in Escherichia coli. However, the biosynthesis pathway of this modification in the bacterial EF-P is yet to be elucidated.
PRESENTATION OF THE HYPOTHESIS: Here we propose a potential mechanism for the post-translational modification of EF-P. By using comparative genomic methods based on physical clustering and phylogenetic pattern analysis, we identified two protein families of unknown function, encoded by yjeA and yjeK genes in E. coli, as candidates for this missing pathway. Based on the analysis of the structural and biochemical properties of both protein families, we propose two potential mechanisms for the modification of EF-P.
TESTING THE HYPOTHESIS: This hypothesis could be tested genetically by constructing a bacterial strain with a tagged efp gene. The tag would allow the purification of EF-P by affinity chromatography and the analysis of the purified protein by mass spectrometry. yjeA or yjeK could then be deleted in the efp tagged strain and the EF-P protein purified from each mutant analyzed by mass spectrometry for the presence or the absence of the modification. This hypothesis can also be tested by purifying the different components (YjeK, YjeA and EF-P) and reconstituting the pathway in vitro.
IMPLICATION OF THE HYPOTHESIS: The requirement for a fully modified EF-P for protein synthesis in certain bacteria implies the presence of specific post-translational modification mechanism in these organisms. All of the 725 bacterial genomes analyzed, possess an efp gene but only 200 (28%) possess both yjeA and yjeK genes. In the other organisms, EF-P may be modified by another pathway or the translation machinery must have adapted to the lack of EF-P modification. Our hypotheses, if confirmed, will lead to the discovery of a new post-translational modification pathway.
REVIEWERS: This article was reviewed by Céline Brochier-Armanet, Igor B. Zhulin and Mikhail Gelfand. For the full reviews, please go to the Reviewers' reports section.
Biol Direct
2010;5(None):None-None
| PubMed ID:
20070887
Yanagisawa T, Sumida T, Ishii R, Takemoto C, Yokoyama S
A paralog of lysyl-tRNA synthetase aminoacylates a conserved lysine residue in translation elongation factor P
▸ Abstract
Aminoacyl-tRNA synthetase (aaRS) paralogs with unknown functions exist in various species. We now report novel 'protein lysylation' by an Escherichia coli lysyl-tRNA synthetase paralog, GenX/PoxA/YjeA. X-ray crystallographic analysis shows that the structure of the GenX protein resembles that of a class II aaRS. Further in vitro studies reveal that it specifically aminoacylates EF-P with lysine. The shape of the protein substrate mimics that of the L-shaped tRNA, and its lysylation site corresponds to the tRNA 3' end. Thus, we show how the aaRS architecture can be adapted to achieve aminoacylation of a specific protein. Moreover, in vivo analyses reveal that the translation elongation factor P (EF-P) lysylation by GenX is enhanced by YjeK (lysine 2,3-aminomutase paralog), which is encoded next to the EF-P gene, and might convert alpha-lysyl-EF-P to beta-lysyl-EF-P. In vivo analyses indicate that the EF-P modification by GenX and YjeK is essential for cell survival.
Nat Struct Mol Biol
2010;17(9):1136-1143
| PubMed ID:
20729861
Park JH, Johansson HE, Aoki H, Huang BX, Kim HY, Ganoza MC, Park MH
Post-translational modification by β-lysylation is required for activity of Escherichia coli elongation factor P (EF-P)
▸ Abstract
Bacterial elongation factor P (EF-P) is the ortholog of archaeal and eukaryotic initiation factor 5A (eIF5A). EF-P shares sequence homology and crystal structure with eIF5A, but unlike eIF5A, EF-P does not undergo hypusine modification. Recently, two bacterial genes, yjeA and yjeK, encoding truncated homologs of class II lysyl-tRNA synthetase and of lysine-2,3-aminomutase, respectively, have been implicated in the modification of EF-P to convert a specific lysine to a hypothetical β-lysyl-lysine. Here we present biochemical evidence for β-lysyl-lysine modification in Escherichia coli EF-P and for its role in EF-P activity by characterizing native and recombinant EF-P proteins for their modification status and activity in vitro. Mass spectrometric analyses confirmed the lysyl modification at lysine 34 in native and recombinant EF-P proteins. The β-lysyl-lysine isopeptide was identified in the exhaustive Pronase digests of native EF-P and recombinant EF-P isolated from E. coli coexpressing EF-P, YjeA, and YjeK but not in the digests of proteins derived from the vectors encoding EF-P alone or EF-P together with YjeA, indicating that both enzymes, YjeA and YjeK, are required for β-lysylation of EF-P. Endogenous EF-P as well as the recombinant EF-P preparation containing β-lysyl-EF-P stimulated N-formyl-methionyl-puromycin synthesis ∼4-fold over the preparations containing unmodified EF-P and/or α-lysyl-EF-P. The mutant lacking the modification site lysine (K34A) was inactive. This is the first report of biochemical evidence for the β-lysylation of EF-P in vivo and the requirement for this modification for the activity of EF-P.
J Biol Chem
2012;287(4):2579-2590
| PubMed ID:
22128152
Conserved residues that are potentially involved in substrate binding include D561 and E598 (which are equivalent to D293 and D330 in LAM)
The function of this group of enzymes is currently not known, however, they form a discrete cluster of sequences at an E() Value of 1E-75 and have thus been classified as a provisional Family.
Represented by IPR022462
