Suppressor mutations in Escherichia coli methionyl-tRNA formyltransferase: role of a 16-amino acid insertion module in initiator tRNA recognition

Genetic analysis of translation initiation in bacteria: An initiator tRNA-centric view

Translation of messenger RNA (mRNA) in bacteria occurs in the steps of initiation, elongation, termination, and ribosome recycling. The initiation step comprises multiple stages and uses a special transfer RNA (tRNA) called initiator tRNA (i-tRNA), which is first aminoacylated and then formylated using methionine and N10 -formyl-tetrahydrofolate (N10 -fTHF), respectively. Both methionine and N10 -fTHF are produced via one-carbon metabolism, linking translation initiation with active cellular metabolism. The fidelity of i-tRNA binding to the ribosomal peptidyl-site (P-site) is attributed to the structural features in its acceptor stem, and the highly conserved three consecutive G-C base pairs (3GC pairs) in the anticodon stem. The acceptor stem region is important in formylation of the amino acid attached to i-tRNA and in its initial binding to the P-site. And, the 3GC pairs are crucial in transiting the i-tRNA through various stages of initiation. We utilized the feature of 3GC pairs to investigate the nuanced layers of scrutiny that ensure fidelity of translation initiation through i-tRNA abundance and its interactions with the components of the translation apparatus. We discuss the importance of i-tRNA in the final stages of ribosome maturation, as also the roles of the Shine-Dalgarno sequence, ribosome heterogeneity, initiation factors, ribosome recycling factor, and coevolution of the translation apparatus in orchestrating a delicate balance between the fidelity of initiation and/or its leakiness to generate proteome plasticity in cells to confer growth fitness advantages in response to the dynamic nutritional states.

Suppressor Mutants: History and Today's Applications

For decades, biologist have exploited the near boundless advantages that molecular and genetic tools and analysis provide for our ability to understand biological systems. One of these genetic tools, suppressor analysis, has proven invaluable in furthering our understanding of biological processes and pathways and in discovering unknown interactions between genes and gene products. The power of suppressor analysis lies in its ability to discover genetic interactions in an unbiased manner, often leading to surprising discoveries. With advancements in technology, high-throughput approaches have aided in large-scale identification of suppressors and have helped provide insight into the core functional mechanisms through which suppressors act. In this review, we examine some of the fundamental discoveries that have been made possible through analysis of suppressor mutations. In addition, we cover the different types of suppressor mutants that can be isolated and the biological insights afforded by each type. Moreover, we provide considerations for the design of experiments to isolate suppressor mutants and for strategies to identify intergenic suppressor mutations. Finally, we provide guidance and example protocols for the isolation and mapping of suppressor mutants.

Towards Engineering an Orthogonal Protein Translation Initiation System

In the last two decades, methods to incorporate non-canonical amino acids (ncAAs) into specific positions of a protein have advanced significantly; these methods have become general tools for engineering proteins. However, almost all these methods depend on the translation elongation process, and strategies leveraging the initiation process have rarely been reported. The incorporation of a ncAA specifically at the translation initiation site enables the installation of reactive groups for modification at the N-termini of proteins, which are attractive positions for introducing abiological groups with minimal structural perturbations. In this study, we attempted to engineer an orthogonal protein translation initiation system. Introduction of the identity elements of Escherichia coli initiator tRNA converted an engineered Methanococcus jannaschii tRNA^Tyr into an initiator tRNA. The engineered tRNA enabled the site-specific incorporation of O-propargyl-l-tyrosine (OpgY) into the amber (TAG) codon at the translation initiation position but was inactive toward the elongational TAG codon. Misincorporation of Gln was detected, and the engineered system was demonstrated only with OpgY. We expect further engineering of the initiator tRNA for improved activity and specificity to generate an orthogonal translation initiation system.

Targeting and function of proteins mediating translation initiation in organelles of Plasmodium falciparum

The malaria parasite Plasmodium falciparum has two translationally active organelles - the apicoplast and mitochondrion, which import nuclear-encoded translation factors to mediate protein synthesis. Initiation of translation is a complex step wherein initiation factors (IFs) act in a regulated manner to form an initiation complex. We identified putative organellar IFs and investigated the targeting, structure and function of IF1, IF2 and IF3 homologues encoded by the parasite nuclear genome. A single PfIF1 is targeted to the apicoplast. Apart from its critical ribosomal interactions, PfIF1 also exhibited nucleic-acid binding and melting activities and mediated transcription anti-termination. This suggests a prominent ancillary function for PfIF1 in destabilisation of DNA and RNA hairpin loops encountered during transcription and translation of the A+T rich apicoplast genome. Of the three putative IF2 homologues, only one (PfIF2a) was an organellar protein with mitochondrial localisation. We additionally identified an IF3 (PfIF3a) that localised exclusively to the mitochondrion and another protein, PfIF3b, that was apicoplast targeted. PfIF3a exhibited ribosome anti-association activity, and monosome splitting by PfIF3a was enhanced by ribosome recycling factor (PfRRF2) and PfEF-G(Mit). These results fill a gap in our understanding of organellar translation in Plasmodium, which is the site of action of several anti-malarial compounds.

Biochemical characterization of pathogenic mutations in human mitochondrial methionyl-tRNA formyltransferase

N-Formylation of initiator methionyl-tRNA (Met-tRNA(Met)) by methionyl-tRNA formyltransferase (MTF) is important for translation initiation in bacteria, mitochondria, and chloroplasts. Unlike all other translation systems, the metazoan mitochondrial system is unique in using a single methionine tRNA (tRNA(Met)) for both initiation and elongation. A portion of Met-tRNA(Met) is formylated for initiation, whereas the remainder is used for elongation. Recently, we showed that compound heterozygous mutations within the nuclear gene encoding human mitochondrial MTF (mt-MTF) significantly reduced mitochondrial translation efficiency, leading to combined oxidative phosphorylation deficiency and Leigh syndrome in two unrelated patients. Patient P1 has a stop codon mutation in one of the MTF genes and an S209L mutation in the other MTF gene. P2 has a S125L mutation in one of the MTF genes and the same S209L mutation as P1 in the other MTF gene. Here, we have investigated the effect of mutations at Ser-125 and Ser-209 on activities of human mt-MTF and of the corresponding mutations, Ala-89 or Ala-172, respectively, on activities of Escherichia coli MTF. The S125L mutant has 653-fold lower activity, whereas the S209L mutant has 36-fold lower activity. Thus, both patients depend upon residual activity of the S209L mutant to support low levels of mitochondrial protein synthesis. We discuss the implications of these and other results for whether the effect of the S209L mutation on mitochondrial translational efficiency is due to reduced activity of the mutant mt-MTF and/or reduced levels of the mutant mt-MTF.

Peptide deformylase inhibitors as potent antimycobacterial agents

Peptide deformylase (PDF) catalyzes the hydrolytic removal of the N-terminal formyl group from nascent proteins. This is an essential step in bacterial protein synthesis, making PDF an attractive target for antibacterial drug development. Essentiality of the def gene, encoding PDF from Mycobacterium tuberculosis, was demonstrated through genetic knockout experiments with Mycobacterium bovis BCG. PDF from M. tuberculosis strain H37Rv was cloned, expressed, and purified as an N-terminal histidine-tagged recombinant protein in Escherichia coli. A novel class of PDF inhibitors (PDF-I), the N-alkyl urea hydroxamic acids, were synthesized and evaluated for their activities against the M. tuberculosis PDF enzyme as well as their antimycobacterial effects. Several compounds from the new class had 50% inhibitory concentration (IC50) values of <100 nM. Some of the PDF-I displayed antibacterial activity against M. tuberculosis, including MDR strains with MIC90 values of <1 microM. Pharmacokinetic studies of potential leads showed that the compounds were orally bioavailable. Spontaneous resistance towards these inhibitors arose at a frequency of < or =5 x 10(-7) in M. bovis BCG. DNA sequence analysis of several spontaneous PDF-I-resistant mutants revealed that half of the mutants had acquired point mutations in their formyl methyltransferase gene (fmt), which formylated Met-tRNA. The results from this study validate M. tuberculosis PDF as a drug target and suggest that this class of compounds have the potential to be developed as novel antimycobacterial agents.

Differential expression of proteins and genes in the lag phase of Lactococcus lactis subsp. lactis grown in synthetic medium and reconstituted skim milk

We investigated protein and gene expression in the lag phase of Lactococcus lactis subsp. lactis CNRZ 157 and compared it to the exponential and stationary phases. By means of two-dimensional polyacrylamide gel electrophoresis, 28 highly expressed lag-phase proteins, implicated in nucleotide metabolism, glycolysis, stress response, translation, transcription, cell division, amino acid metabolism, and coenzyme synthesis, were identified. Among the identified proteins, >2-fold induction and down-regulation in the lag phase were determined for 12 proteins in respect to the exponential phase and for 18 proteins in respect to the stationary phase. Transcriptional changes of the lag-phase proteins in L. lactis were studied by oligonucleotide microarrays. Good correlation between protein and gene expression studies was demonstrated for several differentially expressed proteins, including nucleotide biosynthetic enzymes, adenylosuccinate synthase (PurA), IMP dehydrogenase (GuaB), and aspartate carbamoyl transferase (PyrB); heat-shock protein DnaK; serine hydroxymethyl transferase (GlyA); carbon catabolite control protein (CcpA); elongation factor G (FusA); and cell division protein (FtsZ).

Modular organization of FDH: Exploring the basis of hydrolase catalysis

An abundant enzyme of liver cytosol, 10-formyltetrahydrofolate dehydrogenase (FDH), is an interesting example of a multidomain protein. It consists of two functionally unrelated domains, an aldehyde dehydrogenase-homologous domain and a folate-binding hydrolase domain, which are connected by an approximately 100-residue linker. The amino-terminal hydrolase domain of FDH (Nt-FDH) is a homolog of formyl transferase enzymes that utilize 10-formyl-THF as a formyl donor. Interestingly, the concerted action of all three domains of FDH produces a new catalytic activity, NADP+-dependent oxidation of 10-formyltetrahydrofolate (10-formyl-THF) to THF and CO2. The present studies had two objectives: First, to explore the modular organization of FDH through the production of hybrid enzymes by domain replacement with methionyl-tRNA formyltransferase (FMT), an enzyme homologous to the hydrolase domain of FDH. The second was to explore the molecular basis for the distinct catalytic mechanisms of Nt-FDH and related 10-formyl-THF utilizing enzymes. Our studies revealed that FMT cannot substitute for the hydrolase domain of FDH in order to catalyze the dehydrogenase reaction. It is apparently due to inability of FMT to catalyze the hydrolysis of 10-formyl-THF in the absence of the cosubstrate of the transferase reaction despite the high similarity of the catalytic centers of the two enzymes. Our results further imply that Ile in place of Asn in the FDH hydrolase catalytic center is an important determinant for hydrolase catalysis as opposed to transferase catalysis.

Ribose 2'-hydroxyl groups in the 5' strand of the acceptor arm of P-site tRNA are not essential for EF-G catalyzed translocation

The coupled movement of tRNA-mRNA complex through the ribosome is a fundamental step during the protein elongation process. We demonstrate that the ribosome will translocate a P-site-bound tRNA(Met) with a break in the phosphodiester backbone between positions 17 and 18 in the D-loop. Crystallographic data showed that the acceptor arms of P- and E-site tRNA interact extensively with the ribosomal large subunit. Therefore, we used this fragmented P-site-bound tRNA(Met) to investigate the contributions of single 2'-hydroxyl groups in the 5' strand of the acceptor arm for translocation into the ribosomal E-site. EF-G-dependent translocation of the tRNAs was monitored using a toeprinting assay and a fluorescence-based rapid kinetic method. Surprisingly, our results show that none of the 2'-hydroxyl groups in the 5' strand of the acceptor arm of P-site-bound tRNA(Met) between positions 1-17 play a critical role during translocation. This suggests that either these 2'-hydroxyl groups are not important for translocation or they are redundant and the three-dimensional shape of the P-site tRNA is more important for translocation.

Structural basis for the control of translation initiation during stress

During environmental stress, organisms limit protein synthesis by storing inactive ribosomes that are rapidly reactivated when conditions improve. Here we present structural and biochemical data showing that protein Y, an Escherichia coli stress protein, fills the tRNA- and mRNA-binding channel of the small ribosomal subunit to stabilize intact ribosomes. Protein Y inhibits translation initiation during cold shock but not at normal temperatures. Furthermore, protein Y competes with conserved translation initiation factors that, in bacteria, are required for ribosomal subunit dissociation. The mechanism used by protein Y to reduce translation initiation during stress and quickly release ribosomes for renewed translation initiation may therefore occur widely in nature.

Ribosome formation from subunits studied by stopped-flow and Rayleigh light scattering

Light scattering and standard stopped-flow techniques were used to monitor rapid association of ribosomal subunits during initiation of eubacterial protein synthesis. The effects of the initiation factors IF1, IF2, IF3 and buffer conditions on subunit association were studied along with the role of GTP in this process. The part of light scattering theory that is essential for kinetic measurements is high-lighted in the main text and a more general treatment of Rayleigh scattering from macromolecules is given in an appendix.

Targeting and insertion of heterologous membrane proteins in E. coli

Membrane targeting and insertion of the archaeal Halobacter halobium proton pump bacterioopsin (Bop) and the human melanocortin 4 receptor (MC(4)R) were studied in vitro, using E. coli components for protein synthesis, membrane targeting and insertion. These heterologous proteins are targeted to E. coli membranes in a signal recognition particle (SRP) dependent manner and inserted into the membrane co-translationally. Furthermore, we demonstrate that nascent chains of Bop and MC(4)R first interact with SecY and then with YidC as they move through the translocon. Our results suggest that the initial stages of membrane targeting and insertion of heterologous proteins in E. coli proceed by the pathway used for native E. coli membrane proteins. No significant pausing of protein elongation was observed in the presence of E. coli SRP, in line with the suggestion that translational arrest requires an Alu domain, which is absent in SRP from E. coli.

Common location of determinants in initiator transfer RNAs for initiator-elongator discrimination in bacteria and in eukaryotes

Initiator tRNAs are used exclusively for initiation of protein synthesis and not for elongation. We show that both Escherichia coli and eukaryotic initiator tRNAs have negative determinants, at the same positions, that block their activity in elongation. The primary negative determinant in E. coli initiator tRNA is the C1xA72 mismatch at the end of the acceptor stem. The primary negative determinant in eukaryotic initiator tRNAs is located in the TPsiC stem, whereas a secondary negative determinant is the A1:U72 base pair at the end of the acceptor stem. Here we show that E. coli initiator tRNA also has a secondary negative determinant for elongation and that it is the U50.G64 wobble base pair, located at the same position in the TPsiC stem as the primary negative determinant in eukaryotic initiator tRNAs. Mutation of the U50.G64 wobble base pair to C50:G64 or U50:A64 base pairs increases the in vivo amber suppressor activity of initiator tRNA mutants that have changes in the acceptor stem and in the anticodon sequence necessary for amber suppressor activity. Binding assays of the mutant aminoacyl-tRNAs carrying the C50 and A64 changes to the elongation factor EF-Tu.GTP show marginally higher affinity of the C50 and A64 mutant tRNAs and increased stability of the EF-Tu.GTP. aminoacyl-tRNA ternary complexes. Other results show a large effect of the amino acid attached to a tRNA, glutamine versus methionine, on the binding affinity toward EF-Tu.GTP and on the stability of the EF-Tu.GTP.aminoacyl-tRNA ternary complex.

Expression of Escherichia coli methionyl-tRNA formyltransferase in Saccharomyces cerevisiae leads to formylation of the cytoplasmic initiator tRNA and possibly to initiation of protein synthesis with formylmethionine

Protein synthesis in eukaryotic cytoplasm and in archaebacteria is initiated with methionine, whereas, that in eubacteria and in eukaryotic organelles, such as mitochondria and chloroplasts, is initiated with formylmethionine. In view of this clear distinction, we have investigated whether protein synthesis in the eukaryotic cytoplasm can be initiated with formylmethionine, and, if so, what the consequences are to the cell. For this purpose, we have expressed in an inducible manner the Escherichia coli methionyl-tRNA formyltransferase (MTF) in the cytoplasm of the yeast Saccharomyces cerevisiae. Expression of active MTF, but not of an inactive mutant, leads to formylation of methionine attached to the yeast cytoplasmic initiator tRNA to the extent of about 70%. As a consequence, the yeast strain grows slowly. Coexpression of the E. coli polypeptide deformylase (DEF), which removes the formyl group from the N-terminal formylmethionine in a polypeptide, rescues the slow-growth phenotype, whereas, coexpression of an inactive mutant of DEF does not. These results suggest that the cytoplasmic protein-synthesizing system of yeast, like that of eubacteria, can at least to some extent utilize formylated initiator Met-tRNA to initiate protein synthesis and that initiation of proteins with formylmethionine leads to the slow-growth phenotype. Removal of the formyl group in these proteins by DEF would explain the rescue of the slow-growth phenotype.

Conformational change of Escherichia coli initiator methionyl-tRNA(fMet) upon binding to methionyl-tRNA formyl transferase

The specific formylation of initiator methionyl-tRNA (Met-tRNA) by methionyl-tRNA formyltransferase (MTF) is important for the initiation of protein synthesis in Escherichia coli. The determinants for formylation are located in the acceptor stem and in the dihydrouridine (D) stem of the initiator tRNA (tRNA(fMet)). Here, we have used ethylation interference analysis to study the interactions between the Met-tRNA(fMet) and MTF in solution. We have identified three clusters of phosphates in the tRNA that, when ethylated, interfere with binding of MTF. Interference due to ethylation of phosphates in the acceptor stem and in the D stem is most likely due to the close proximity of the protein as seen in the crystal structure of the MTF.fMet-tRNA(fMet) complex. The third cluster of phosphates, whose ethylation interferes with binding of MTF, is dispersed along the anticodon stem, which is distal to the sites of tRNA protein contacts. Interestingly, these latter positions correspond to sites of increased cleavages by RNase V1 in RNA footprinting experiments. Together, these results suggest that in addition to the protein, which binds to the substrate tRNA in an induced fit mechanism, the tRNA also undergoes induced structural changes during its binding to MTF.

Aminoacyl-tRNA synthesis

Aminoacyl-tRNAs are substrates for translation and are pivotal in determining how the genetic code is interpreted as amino acids. The function of aminoacyl-tRNA synthesis is to precisely match amino acids with tRNAs containing the corresponding anticodon. This is primarily achieved by the direct attachment of an amino acid to the corresponding tRNA by an aminoacyl-tRNA synthetase, although intrinsic proofreading and extrinsic editing are also essential in several cases. Recent studies of aminoacyl-tRNA synthesis, mainly prompted by the advent of whole genome sequencing and the availability of a vast body of structural data, have led to an expanded and more detailed picture of how aminoacyl-tRNAs are synthesized. This article reviews current knowledge of the biochemical, structural, and evolutionary facets of aminoacyl-tRNA synthesis.

The many routes of bacterial transfer RNAs after aminoacylation

Subsequent to their aminoacylation, tRNAs are subject to specific maturation and/or correction processes. Aminoacylated tRNAs ready for use in translation are then specifically channelled to the ribosomal A or P sites. Structural and biochemical studies have opened the way towards furthering our understanding of these routes to the ribosome, which involve a strict distinction between initiator and elongator tRNAs.

Recognition of the initiator tRNA by the Pseudomonas aeruginosa methionyl-tRNA formyltransferase: importance of the base-base mismatch at the end of the acceptor stem

Formylation of the initiator methionyl-tRNA (Met-tRNAfMet) in eubacteria is catalyzed by methionyl-tRNA formyltransferase (MTF). Features of the Escherichia coli tRNAfMet that are important for formylation are the base-base mismatch between nucleotides 1 and 72, and the second and third base pairs of the acceptor stem. The base-base mismatch is the most crucial formylation determinant in the E. coli tRNAfMet. However, it is not known whether this feature is also important for formylation of other eubacterial tRNAfMet. We cloned the Pseudomonas aeruginosa MTF gene by complementation of an E. coli MTF mutant strain with a genomic library, and investigated the catalytic properties and substrate specificity of the enzyme. The results show that the P. aeruginosa and E. coli enzymes have comparable affinities for the tRNAfMet and N10-formyltetrahydrofolate (fTHF) substrates. Overproduction of the P. aeruginosa MTF rescued the initiator activity of an E. coli formylation-defective tRNAfMet with a base pair between nucleotides 1 and 72, indicating that the base-base mismatch is utilized by the P. aeruginosa MTF for recognition of the tRNAfMet. Therefore, this feature may be used by MTFs from other eubacteria to distinguish the initiator from elongator tRNAs.

Mapping the active site of the Haemophilus influenzae methionyl-tRNA formyltransferase: residues important for catalysis and tRNA binding

Formylation of the initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF) is an essential step in initiation of protein synthesis in eubacteria. Here, site-directed mutagenesis was used to identify active site residues of the Haemophilus influenzae MTF. Of the nine residues investigated, only Arg-41, Asn-107, His-109 and Asp-145 were important for the function of the H. influenzae MTF. Replacement of these residues with Ala resulted in a significant reduction in the efficiency of catalysis. Intrinsic fluorescence analysis indicated that this was not due to a defect in N10-formyltetrahydrofolate (fTHF) binding. The Asp-145 and Arg-41 mutations reduced the affinity of the enzyme for the initiator tRNA, whereas the Asn-107 and His-109 mutations affected catalysis but not tRNA binding. Replacement of Arg-41, His-109 and Asp-145 with functionally similar residues also affected the activity of the enzyme. The data suggest that Asn-107, His-109 and Asp-145 are catalytic residues, whereas Arg-41 is involved in tRNA recognition. In the Escherichia coli glycinamide ribonucleotide formyltransferase, which also uses fTHF as the formyl donor, Asn-106, His-108 and Asp-144 participate in the catalytic step. Together, these observations imply that this group of enzymes uses the same basic mechanism in formylating their substrates.

Induced fit of a peptide loop of methionyl-tRNA formyltransferase triggered by the initiator tRNA substrate

A 16-aa insertion loop present in eubacterial methionyl-tRNA formyltransferases (MTF) is critical for specific recognition of the initiator tRNA in Escherichia coli. We have studied the interactions between this region of the E. coli enzyme and initiator methionyl-tRNA (Met-tRNA) by using two complementary protection experiments: protection of MTF against proteolytic cleavage by tRNA and protection of tRNA against nucleolytic cleavage by MTF. The insertion loop in MTF is uniquely sensitive to cleavage by trypsin. We show that the substrate initiator Met-tRNA protects MTF against trypsin cleavage, whereas a formylation-defective mutant initiator Met-tRNA, which binds to MTF with approximately the same affinity, does not. Also, mutants of MTF within the insertion loop (which are defective in formylation) are not protected by the initiator Met-tRNA. Thus, a functional enzyme-substrate complex is necessary for protection of MTF against trypsin cleavage. Along with other data, these results strongly suggest that a segment of the insertion loop, which is exposed and unstructured in MTF, undergoes an induced fit in the functional MTF.Met-tRNA complex but not in the nonfunctional one. Footprinting experiments show that MTF specifically protects the acceptor stem and the 3'-end region of the initiator Met-tRNA against cleavage by double and single strand-specific nucleases. This protection also depends on formation of a functional MTF.Met-tRNA complex. Thus, the insertion loop interacts mostly with the acceptor stem of the initiator Met-tRNA, which contains the critical determinants for formylation.

Crystal structure of methionyl-tRNAfMet transformylase complexed with the initiator formyl-methionyl-tRNAfMet

The crystal structure of Escherichia coli methionyl-tRNAfMet transformylase complexed with formyl-methionyl-tRNAfMet was solved at 2.8 A resolution. The formylation reaction catalyzed by this enzyme irreversibly commits methionyl-tRNAfMet to initiation of translation in eubacteria. In the three-dimensional model, the methionyl-tRNAfMet formyltransferase fills in the inside of the L-shaped tRNA molecule on the D-stem side. The anticodon stem and loop are away from the protein. An enzyme loop is wedged in the major groove of the acceptor helix. As a result, the C1-A72 mismatch characteristic of the initiator tRNA is split and the 3' arm bends inside the active centre. This recognition mechanism is markedly distinct from that of elongation factor Tu, which binds the acceptor arm of aminoacylated elongator tRNAs on the T-stem side.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Mammalian mitochondrial methionyl-tRNA transformylase from bovine liver. Purification, characterization, and gene structure

The mammalian mitochondrial methionyl-tRNA transformylase (MTFmt) was partially purified 2,200-fold from bovine liver mitochondria using column chromatography. The polypeptide responsible for MTFmt activity was excised from a sodium dodecyl sulfate-polyacrylamide gel and the amino acid sequences of several peptides were determined. The cDNA encoding bovine MTFmt was obtained and its nucleotide sequence was determined. The deduced amino acid sequence of the mature form of MTFmt consists of 357 amino acid residues. This sequence is about 30% identical to the corresponding Escherichia coli and yeast mitochondrial MTFs. Kinetic parameters governing the formylation of various tRNAs were obtained. Bovine MTFmt formylates its homologous mitochondrial methionyl-tRNA and the E. coli initiator methionyl-tRNA (Met-tRNAfMet) with essentially equal efficiency. The E. coli elongator methionyl-tRNA (Met-tRNAmMet) was also formylated although with somewhat less favorable kinetics. These results suggest that the substrate specificity of MTFmt is not as rigid as that of the E. coli MTF which clearly discriminates between the bacterial initiator and elongator Met-tRNAs. These observations are discussed in terms of the presence of a single tRNAMet gene in mammalian mitochondria.