Translation fMet is required for efficient initiation of protein synthesis in most groups of bacteria. The 30S ribosome–mRNA complex specifically recruits tRNAs with a formylated amino acid – tRNAfMet attached to fMet in the natural case. Because the fMet directs initiation,
proteins in bacteria start (
N-terminus) with a fMet residue instead of a methionine. Further occurrences of the "AUG" codon will result in a normal methionine, because a normal "elongating" tRNAMet is used. Unexpectedly, formyltransferase can also act upon eukaryotic initiator tRNA in living yeast cells. Even under normal conditions, the nuclear-encoded formyltransferase is not completely imported into mitochondria; even more is left in the cytosol under stress. These cytosolic formyltransferase produce fMet-tRNAi, which can be used by cytosolic ribosomes to produce proteins with a N-terminal fMet. These proteins are targeted for degradation by specific processes in the cell.
Further processing The
N-terminal fMet is removed from majority of proteins, both host and recombinant, by a sequence of two enzymatic reactions. First,
peptide deformylase (PDF) deformylates it, converting the residue back to a normal methionine. Then
methionine aminopeptidase (MetAP) removes the residue from the chain. MetAP only acts on proteins with second-position residues that are less bulky than valine.
Variation The formyl group is not strictly required for initiation. Bacteria with their formyltransferase knocked out, which prevents Met-tRNAfMet (i.e. methionine loaded onto tRNAfMet) from turning into fMet-tRNAfMet, can have varying degrees of residual ability to start protein synthesis.
E. coli,
S. pneumoniae and
B. subtilis show almost no remaining translation ability, while
P. aeruginosa,
S. aureus,
H. influenzae, and possibly
S. faecalis still churn out plenty of protein. In
P. aeruginosa, this ability is facilitated by
bacterial initiation factor 2, which can carry both Met-tRNAfMet and fMet-tRNAfMet to the ribosome. ==Relevance to immunology==