Regulation of the activity of chloroplast translational initiation factor 3 by NH2- and COOH-terminal extensions

Highly degenerate plastomes in two hemiparasitic dwarf mistletoes: Arceuthobium chinense and A. pini (Viscaceae)

The leafless and endophytic habitat may significantly relax the selection pressure on photosynthesis, and plastid transcription and translation, causing the loss/pseudogenization of several essential plastid-encoding genes in dwarf mistletoes. Dwarf mistletoes (Arceuthobium spp., Viscaceae) are the most destructive plant parasites to numerous conifer species worldwide. In this study, the plastid genomes (plastomes) of Arceuthobium chinense Lecomte and A. pini Hawksworth and Wiens were sequenced and characterized. Although dwarf mistletoes are hemiparasites capable of photosynthesis, their plastomes were highly degenerated, as indicated by the smallest plastome size, the lowest GC content, and relatively very few intact genes among the Santalales hemiparasites. Unexpectedly, several essential housekeeping genes (rpoA, rpoB, rpoC1, and rpoC2) and some core photosynthetic genes (psbZ and petL), as well as the rpl33 gene, that is indispensable for plants under stress conditions, were deleted or pseudogenized in the Arceuthobium plastomes. Our data suggest that the leafless and endophytic habit, which heavily relies on the coniferous hosts for nutrients and carbon requirement, may largely relax the selection pressure on photosynthesis, as well as plastid transcription and translation, thus resulting in the loss/pseudogenization of such essential plastid-encoding genes in dwarf mistletoes. Therefore, the higher level of plastome degradation in Arceuthobium species than other Santalales hemiparasites is likely correlated with the evolution of leafless and endophytic habit. A higher degree of plastome degradation in Arceuthobium. These findings provide new insights into the plastome degeneration associated with parasitism in Santalales and deepen our understanding of the biology of dwarf mistletoes.

Mitochondrial Translation Initiation Factor 3: Structure, Functions, Interactions, and Implication in Human Health and Disease

Mitochondria are essential organelles of eukaryotic cell that provide its respiratory function by means of the electron transfer chain. Expression of mitochondrial genes is organized in a bacterial-like manner; however multiple evolutionary differences are observed between the two systems, including translation initiation machinery. This review is dedicated to the mitochondrial translation initiation factor 3 (IF3mt), which plays a key role in the protein synthesis in mitochondria. Involvement of IF3mt in human health and disease is discussed.

The interaction of mammalian mitochondrial translational initiation factor 3 with ribosomes: evolution of terminal extensions in IF3mt

Mammalian mitochondrial initiation factor 3 (IF3_mt) has a central region with homology to bacterial IF3. This homology region is preceded by an N-terminal extension and followed by a C-terminal extension. The role of these extensions on the binding of IF3_mt to mitochondrial small ribosomal subunits (28S) was studied using derivatives in which the extensions had been deleted. The K_d for the binding of IF3_mt to 28S subunits is ∼30 nM. Removal of either the N- or C-terminal extension has almost no effect on this value. IF3_mt has very weak interactions with the large subunit of the mitochondrial ribosome (39S) (K_d = 1.5 μM). However, deletion of the extensions results in derivatives with significant affinity for 39S subunits (K_d = 0.12−0.25 μM). IF3_mt does not bind 55S monosomes, while the deletion derivative binds slightly to these particles. IF3_mt is very effective in dissociating 55S ribosomes. Removal of the N-terminal extension has little effect on this activity. However, removal of the C-terminal extension leads to a complex dissociation pattern due to the high affinity of this derivative for 39S subunits. These data suggest that the extensions have evolved to ensure the proper dissociation of IF3_mt from the 28S subunits upon 39S subunit joining.

Role of the N- and C-terminal extensions on the activity of mammalian mitochondrial translational initiation factor 3

Mammalian mitochondrial translational initiation factor 3 (IF3_mt) promotes initiation complex formation on mitochondrial 55S ribosomes in the presence of IF2_mt, fMet-tRNA and poly(A,U,G). The mature form of IF3_mt is predicted to be 247 residues. Alignment of IF3_mt with bacterial IF3 indicates that it has a central region with 20–30% identity to the bacterial factors. Both the N- and C-termini of IF3_mt have extensions of ∼30 residues compared with bacterial IF3. To examine the role of the extensions on IF3_mt, deletion constructs were prepared in which the N-terminal extension, the C-terminal extension or both extensions were deleted. These truncated derivatives were slightly more active in promoting initiation complex formation than the mature form of IF3_mt. Mitochondrial 28S subunits have the ability to bind fMet-tRNA in the absence of mRNA. IF3_mt promotes the dissociation of the fMet-tRNA bound in the absence of mRNA. This activity of IF3_mt requires the C-terminal extension of this factor. Mitochondrial 28S subunits also bind mRNA independently of fMet-tRNA or added initiation factors. IF3_mt has no effect on the formation of these complexes and cannot dissociate them once formed. These observations have lead to a new model for the function of IF3_mt in mitochondrial translational initiation.

Initiation of protein synthesis in bacteria

Valuable information on translation initiation is available from biochemical data and recently solved structures. We present a detailed description of current knowledge about the structure, function, and interactions of the individual components involved in bacterial translation initiation. The first section describes the ribosomal features relevant to the initiation process. Subsequent sections describe the structure, function, and interactions of the mRNA, the initiator tRNA, and the initiation factors IF1, IF2, and IF3. Finally, we provide an overview of mechanisms of regulation of the translation initiation event. Translation occurs on ribonucleoprotein complexes called ribosomes. The ribosome is composed of a large subunit and a small subunit that hold the activities of peptidyltransfer and decode the triplet code of the mRNA, respectively. Translation initiation is promoted by IF1, IF2, and IF3, which mediate base pairing of the initiator tRNA anticodon to the mRNA initiation codon located in the ribosomal P-site. The mechanism of translation initiation differs for canonical and leaderless mRNAs, since the latter is dependent on the relative level of the initiation factors. Regulation of translation occurs primarily in the initiation phase. Secondary structures at the mRNA ribosomal binding site (RBS) inhibit translation initiation. The accessibility of the RBS is regulated by temperature and binding of small metabolites, proteins, or antisense RNAs. The future challenge is to obtain atomic-resolution structures of complete initiation complexes in order to understand the mechanism of translation initiation in molecular detail.

Proteomic identification of all plastid-specific ribosomal proteins in higher plant chloroplast 30S ribosomal subunit

Six ribosomal proteins are specific to higher plant chloroplast ribosomes [Subramanian, A.R. (1993) Trends Biochem. Sci.18, 177-180]. Three of them have been fully characterized [Yamaguchi, K., von Knoblauch, K. & Subramanian, A. R. (2000) J. Biol. Chem. 275, 28455-28465; Yamaguchi, K. & Subramanian, A. R. (2000) J. Biol. Chem. 275, 28466-28482]. The remaining three plastid-specific ribosomal proteins (PSRPs), all on the small subunit, have now been characterized (2D PAGE, HPLC, N-terminal/internal peptide sequencing, electrospray ionization MS, cloning/ sequencing of precursor cDNAs). PSRP-3 exists in two forms (alpha/beta, N-terminus free and blocked by post-translational modification), whereas PSRP-2 and PSRP-4 appear, from MS data, to be unmodified. PSRP-2 contains two RNA-binding domains which occur in mRNA processing/stabilizing proteins (e.g. U1A snRNP, poly(A)-binding proteins), suggesting a possible role for it in the recruiting of stored chloroplast mRNAs for active protein synthesis. PSRP-3 is the higher plant orthologue of a hypothetical protein (ycf65 gene product), first reported in the chloroplast genome of a red alga. The ycf65 gene is absent from the chloroplast genomes of higher plants. Therefore, we suggest that Psrp-3/ycf65, encoding an evolutionarily conserved chloroplast ribosomal protein, represents an example of organelle-to-nucleus gene transfer in chloroplast evolution. PSRP-4 shows strong homology with Thx, a small basic ribosomal protein of Thermus thermophilus 30S subunit (with a specific structural role in the subunit crystallographic structure), but its orthologues are absent from Escherichia coli and the photosynthetic bacterium Synechocystis. We would therefore suggest that PSRP-4 is an example of gene capture (via horizontal gene transfer) during chloro-ribosome emergence. Orthologues of all six PSRPs are identifiable in the complete genome sequence of Arabidopsis thaliana and in the higher plant expressed sequence tag database. All six PSRPs are nucleus-encoded. The cytosolic precursors of PSRP-2, PSRP-3, and PSRP-4 have average targeting peptides (62, 58, and 54 residues long), and the mature proteins are of 196, 121, and 47 residues length (molar masses, 21.7, 13.8 and 5.2 kDa), respectively. Functions of the PSRPs as active participants in translational regulation, the key feature of chloroplast protein synthesis, are discussed and a model is proposed.

Identification of mammalian mitochondrial translational initiation factor 3 and examination of its role in initiation complex formation with natural mRNAs

Human mitochondrial translational initiation factor 3 (IF3(mt)) has been identified from the human expressed sequence tag data base. Using consensus sequences derived from conserved regions of the bacterial IF3, several partially sequenced cDNA clones were identified, and the complete sequence was assembled in silico from overlapping clones. IF3(mt) is 278 amino acid residues in length. MitoProt II predicts a 97% probability that this protein will be localized in mitochondria and further predicts that the mature protein will be 247 residues in length. The cDNA for the predicted mature form of IF3(mt) was cloned, and the protein was expressed in Escherichia coli in a His-tagged form. The mature form of IF3(mt) has short extensions on the N and C termini surrounding a region homologous to bacterial IF3. The region of IF3(mt) homologous to prokaryotic factors ranges between 21-26% identical to the bacterial proteins. Purified IF3(mt) promotes initiation complex formation on mitochondrial 55 S ribosomes in the presence of mitochondrial initiation factor 2 (IF2(mt)), [(35)S]fMet-tRNA, and either poly(A,U,G) or an in vitro transcript of the cytochrome oxidase subunit II gene as mRNA. IF3(mt) shifts the equilibrium between the 55 S mitochondrial ribosome and its subunits toward subunit dissociation. In addition, the ability of E. coli initiation factor 1 to stimulate initiation complex formation on E. coli 70 S and mitochondrial 55 S ribosomes was investigated in the presence of IF2(mt) and IF3(mt).

The plastid ribosomal proteins. Identification of all the proteins in the 50 S subunit of an organelle ribosome (chloroplast)

We have completed identification of all the ribosomal proteins (RPs) in spinach plastid (chloroplast) ribosomal 50 S subunit via a proteomic approach using two-dimensional electrophoresis, electroblotting/protein sequencing, high performance liquid chromatography purification, polymerase chain reaction-based screening of cDNA library/nucleotide sequencing, and mass spectrometry (reversed-phase HPLC coupled to electrospray ionization mass spectrometry and electrospray ionization mass spectrometry). Spinach plastid 50 S subunit comprises 33 proteins, of which 31 are orthologues of Escherichia coli RPs and two are plastid-specific RPs (PSRP-5 and PSRP-6) having no homologues in other types of ribosomes. Orthologues of E. coli L25 and L30 are absent in spinach plastid ribosome. 25 of the plastid 50 S RPs are encoded in the nuclear genome and synthesized on cytosolic ribosomes, whereas eight of the plastid RPs are encoded in the plastid organelle genome and synthesized on plastid ribosomes. Sites for transit peptide cleavages in the cytosolic RP precursors and formyl Met processing in the plastid-synthesized RPs were established. Post-translational modifications were observed in several mature plastid RPs, including multiple forms of L10, L18, L31, and PSRP-5 and N-terminal/internal modifications in L2, L11 and L16. Comparison of the RPs in gradient-purified 70 S ribosome with those in the 30 and 50 S subunits revealed an additional protein, in approximately stoichiometric amount, specific to the 70 S ribosome. It was identified to be plastid ribosome recycling factor. Combining with our recent study of the proteins in plastid 30 S subunit (Yamaguchi, K., von Knoblauch, K., and Subramanian, A. R. (2000) J. Biol. Chem. 275, 28455-28465), we show that spinach plastid ribosome comprises 59 proteins (33 in 50 S subunit and 25 in 30 S subunit and ribosome recycling factor in 70 S), of which 53 are E. coli orthologues and 6 are plastid-specific proteins (PSRP-1 to PSRP-6). We propose the hypothesis that PSRPs were evolved to perform functions unique to plastid translation and its regulation, including protein targeting/translocation to thylakoid membrane via plastid 50 S subunit.

Translation in chloroplasts

The discovery that chloroplasts have semi-autonomous genetic systems has led to many insights into the biogenesis of these organelles and their evolution from free-living photosynthetic bacteria. Recent developments of our understanding of the molecular mechanisms of translation in chloroplasts suggest selective pressures that have maintained the 100-200 genes of the ancestral endosymbiont in chloroplast genomes. The ability to introduce modified genes into chloroplast genomes by homologous recombination and the recent development of an in vitro chloroplast translation system have been exploited for analyses of the cis-acting requirements for chloroplast translation. Trans-acting translational factors have been identified by genetic and biochemical approaches. Several studies have suggested that chloroplast mRNAs are translated in association with membranes.