Activity of Euglena gracilis chloroplast ribosomes with procaryotic and eucaryotic initiation factors

Isolation, characterization, phosphorylation and site of synthesis of Spinacia chloroplast ribosomal proteins

We have characterized the ribosomal proteins from Spinacia chloroplasts using two-dimensional gel electrophoresis. The 30S and 50S subunits contain 23-25 and 36 ribosomal proteins, respectively. In contrast to prokaryotic ribosomes, chloroplast ribosomes contain at least one (and possibly two) phosphorylated ribosomal proteins. Isolated chloroplasts synthesize in the presence of ((35)S) labeled methionine and cysteine at least seven 30S and thirteen 50S ribosomal proteins which are assembled into (pre)ribosomes. This suggests that about one third of the chloroplast ribosomal proteins is encoded by the chloroplast DNA itself. The identity of several labeled proteins in the two-dimensional gel electrophoretic patterns which did not comigrate with stained chloroplast ribosomal proteins is discussed.

Contacts between mammalian mitochondrial translational initiation factor 3 and ribosomal proteins in the small subunit

Mammalian mitochondrial translational initiation factor 3 (IF3(mt)) binds to the small subunit of the ribosome displacing the large subunit during the initiation of protein biosynthesis. About half of the proteins in mitochondrial ribosomes have homologs in bacteria while the remainder are unique to the mitochondrion. To obtain information on the ribosomal proteins located near the IF3(mt) binding site, cross-linking studies were carried out followed by identification of the cross-linked proteins by mass spectrometry. IF3(mt) cross-links to mammalian mitochondrial homologs of the bacterial ribosomal proteins S5, S9, S10, and S18-2 and to unique mitochondrial ribosomal proteins MRPS29, MRPS32, MRPS36 and PTCD3 (Pet309) which has now been identified as a small subunit ribosomal protein. IF3(mt) has extensions on both the N- and C-termini compared to the bacterial factors. Cross-linking of a truncated derivative lacking these extensions gives the same hits as the full length IF3(mt) except that no cross-links were observed to MRPS36. IF3 consists of two domains separated by a flexible linker. Cross-linking of the isolated N- and C-domains was observed to a range of ribosomal proteins particularly with the C-domain carrying the linker which showed significant cross-linking to several ribosomal proteins not found in prokaryotes.

Insertion domain within mammalian mitochondrial translation initiation factor 2 serves the role of eubacterial initiation factor 1

Mitochondria have their own translational machineries for the synthesis of thirteen polypeptide chains that are components of the complexes that participate in the process of oxidative phosphorylation (or ATP generation). Translation initiation in mammalian mitochondria requires two initiation factors, IF2(mt) and IF3(mt), instead of the three that are present in eubacteria. The mammalian IF2(mt) possesses a unique 37 amino acid insertion domain, which is known to be important for the formation of the translation initiation complex. We have obtained a three-dimensional cryoelectron microscopic map of the mammalian IF2(mt) in complex with initiator fMet-tRNA(iMet) and the eubacterial ribosome. We find that the 37 amino acid insertion domain interacts with the same binding site on the ribosome that would be occupied by the eubacterial initiation factor IF1, which is absent in mitochondria. Our finding suggests that the insertion domain of IF2(mt) mimics the function of eubacterial IF1, by blocking the ribosomal aminoacyl-tRNA binding site (A site) at the initiation step.

Preferential selection of the 5'-terminal start codon on leaderless mRNAs by mammalian mitochondrial ribosomes

Mammalian mitochondrial mRNAs are basically leaderless, having few or no untranslated nucleotides prior to the 5'-start codon. We demonstrate here that mammalian mitochondrial 55 S ribosomes preferentially form initiation complexes at a 5'-terminal AUG codon over an internal AUG. The preferential use of the 5'-start codon is also seen on mitochondrial 28 S small subunits, which suggests that mitochondrial translation initiation on leaderless mRNAs does not require the large ribosomal subunit. The selection of the 5'-AUG is dependent on the presence of fMet-tRNA and is enhanced by the presence of the mitochondrial initiation factor IF2(mt). In prokaryotes, IF3 is believed to antagonize initiation on leaderless mRNAs. However, IF3(mt) stimulates initiation complex formation on leaderless mRNAs when tested with 55 S ribosomes. The addition of even a few nucleotides 5' to the AUG codon significantly reduces the efficiency of initiation, highlighting the importance of the leaderless or nearly leaderless nature of mitochondrial mRNAs. In addition, very few initiation complexes could form on a hybrid mRNA construct consisting of tRNA(Met) attached at the 5'-end of a mitochondrial protein-coding sequence. This observation demonstrates that post-transcriptional processing must occur prior to translation in mammalian mitochondria.

The effect of spermine on the initiation of mitochondrial protein synthesis

Polyamines are important in both prokaryotic and eukaryotic translational systems. Spermine is a quaternary aliphatic amine that is cationic under physiological conditions. In this paper, we demonstrate that spermine stimulates fMet-tRNA binding to mammalian mitochondrial 55S ribosomes. The stimulatory effect of spermine is independent of the identity of the mRNA. The degree of stimulation of spermine is the same at all concentrations of mitochondrial initiation factor 2 (IF2(mt)) and mitochondrial initiation factor 3 (IF3(mt)). This observation indicates that IF2(mt) and IF3(mt), while essential for initiation, are not the primary components of the translation initiation system affected by spermine. IF3(mt) dissociates 55S ribosomes detectably in the absence of spermine, but this effect is strongly inhibited in the presence of spermine. This observation indicates that the positive effect of spermine on initiation is not due to an increase in the availability of the small subunits for initiation. Spermine also promotes fMet-tRNA binding to small subunits of the mitochondrial ribosome in the presence of IF2(mt). The major effect of spermine in promoting initiation complex formation thus appears to be on the interaction of fMet-tRNA with the ribosome.

Evidence for an active role of IF3mt in the initiation of translation in mammalian mitochondria

Mitochondrial translational initiation factor 3 (IF3(mt)) is a 29 kDa protein that has N- and C-terminal domains, homologous to prokaryotic IF3, connected by a linker region. The homology domains are preceded and followed by short extensions. No information is currently available on the specific residues in IF3(mt) important for its activity. On the basis of homology models of IF3(mt), mutations were designed in the N-terminal, C-terminal, and linker domains to identify the functionally important regions. Mutation of residues 170-171, and 175 in the C-terminal domain to alanine resulted in a nearly complete loss of activity in initiation complex formation and in the dissociation of mitochondrial 55S ribosomes. However, these mutated proteins bind to the small (28S) subunit of the mammalian mitochondrial ribosome with K(d) values similar to that of the wild-type factor. These mutations appear to lead to a factor defective in the ability to displace the large (39S) subunit of the ribosome from the 55S monosomes in an active process. Other mutations in the N-terminal domain, the linker region, and the C-terminal domain had little or no effect on the ability of IF3(mt) to promote initiation complex formation on mitochondrial 55S ribosomes. Mutation of residues 247 and 248 in the C-terminal extension abolished the ability of IF3(mt) to reduce the level of binding of fMet-tRNA to the ribosome in the absence of mRNA. Our results suggest that IF3(mt) plays an active role in initiation of translation.

Roles of the N- and C-terminal domains of mammalian mitochondrial initiation factor 3 in protein biosynthesis

Bacterial initiation factor 3 (IF3) is organized into N- and C-domains separated by a linker. Mitochondrial IF3 (IF3(mt)) has a similar domain organization, although both domains have extensions not found in the bacterial factors. Constructs of the N- and C-domains of IF3(mt) with and without the connecting linker were prepared. The K(d) values for the binding of full-length IF3(mt) and its C-domain with and without the linker to mitochondrial 28S subunits are 30, 60, and 95 nM, respectively, indicating that much of the ribosome binding interactions are mediated by the C-domain. However, the N-domain binds to 28S subunits with only a 10-fold lower affinity than full-length IF3(mt). This observation indicates that the N-domain of IF3(mt) has significant contacts with the protein-rich small subunit of mammalian mitochondrial ribosomes. The linker also plays a role in modulating the interactions between the 28S subunit and the factor; it is not just a physical connector between the two domains. The presence of the two domains and the linker may optimize the overall affinity of IF3(mt) for the ribosome. These results are in sharp contrast to observations with Escherichia coli IF3. Removal of the N-domain drastically reduces the activity of IF3(mt) in the dissociation of mitochondrial 55S ribosomes, although the C-domain itself retains some activity. This residual activity depends significantly on the linker region. The N-domain alone has no effect on the dissociation of ribosomes. Full-length IF3(mt) reduces the binding of fMet-tRNA to the 28S subunit in the absence of mRNA. Both the C-terminal extension and the linker are required for this effect. IF3(mt) promotes the formation of a binary complex between IF2(mt) and fMet-tRNA that may play an important role in mitochondrial protein synthesis. Both domains play a role promoting the formation of this complex.

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.

Overexpression and purification of mammalian mitochondrial translational initiation factor 2 and initiation factor 3

Two mammalian mitochondrial initiation factors have been identified. Initiation factor 2 (IF2(mt)) selects the initiator tRNA (fMet-tRNA) and promotes its binding to the ribosome. Initiation factor 3 (IF3(mt)) promotes the dissociation of the 55S mitochondrial ribosome into subunits and may play additional, less-well-understood, roles in initiation complex formation. Native bovine IF2(mt) was purified from liver a number of years ago. The yield of this factor is very low making biochemical studies difficult. The cDNA for bovine IF2(mt) was expressed in Escherichia coli under the control of the T7 polymerase promoter in a vector that provides a His(6)-tag at the C-terminus of the expressed protein. This factor was expressed in E. coli and purified by chromatography on Ni-NTA resins. The expressed protein has a number of degradation products in partially purified preparations and this factor is then further purified by high-performance liquid chromatography or gravity chromatography on anion exchange resins. IF3(mt) has never been purified from any mammalian system. However, the cDNA for this protein can be identified in the expressed sequence tag (EST) libraries. The portion of the sequence encoding the region of human IF3(mt) predicted to be present in the mitochondrially imported form of this factor was cloned and expressed in E. coli using a vector that provides a C-terminal His(6)-tag. The tagged factor is partially purified on Ni-NTA resins. However, a major proteolytic fragment arising from a defined cleavage of this protein is present in these preparations. This contaminant can be removed by a single step of high-performance liquid chromatography on a cation exchange resin. Alternatively, the mature form of IF3(mt) can be purified by two sequential passes through a gravity S-Sepharose column.

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.

The interaction of mitochondrial translational initiation factor 2 with the small ribosomal subunit

Bovine mitochondrial translational initiation factor 2 (IF-2(mt)) is organized into four domains, an N-terminal domain, a central G-domain and two C-terminal domains. These domains correspond to domains III-VI in the six-domain model of Escherichia coli IF-2. Variants in IF-2(mt) were prepared and tested for their abilities to bind the small (28S) subunit of the mitochondrial ribosome. The binding of wild-type IF-2(mt) was strong (K(d) approximately 10-20 nM) and was not affected by fMet-tRNA. Deletion of the N-terminal domain substantially reduced the binding of IF-2(mt) to 28S subunits. However, the addition of fMet-tRNA stimulated the binding of this variant at least 2-fold demonstrating that contacts between fMet-tRNA and IF-2(mt) can stabilize the binding of this factor to 28S subunits. No binding was observed for IF-2(mt) variants lacking the G-domain which probably plays a critical role in organizing the structure of IF-2(mt). IF-2(mt) contains a 37-amino acid insertion region between domains V and VI that is not found in the prokaryotic factors. Mutations in this region caused a significant reduction in the ability of the factor to promote initiation complex formation and to bind 28S subunits.

Interaction of mitochondrial initiation factor 2 with mitochondrial fMet-tRNA

The mammalian mitochondrial genome contains a single tRNA(Met) gene that gives rise to the initiator and elongator tRNA(Met). It is generally believed that mitochondrial protein synthesis begins with formylmethionyl-tRNA, which indicates that the formylation of mitochondrial Met-tRNA specifies its participation in initiation through its interaction with initiation factor 2 (IF-2). However, recent studies in yeast mitochondria, suggest that formylation is not required for protein synthesis. In addition, bovine IF-2(mt) could replace yeast IF-2(mt) in strains that lack fMet-tRNA which suggests that this paradigm may extend to mammalian mitochondria. Here, the importance of the formylation of mitochondrial Met-tRNA for the interaction with IF-2(mt) was investigated by measuring the ability of bovine IF-2(mt) to bind mitochondrial fMet-tRNA. In direct binding experiments, bovine IF-2(mt) has a 25-fold greater affinity for mitochondrial fMet-tRNA than Met-tRNA, using either the native mitochondrial tRNA(Met) or an in vitro transcript of bovine mitochondrial tRNA(Met). In addition, IF-2(mt) will not effectively stimulate mitochondrial Met-tRNA binding to mitochondrial ribosomes, exhibiting a 50-fold preference for fMet-tRNA over Met-tRNA in this assay. Finally, the region of IF-2(mt) responsible for the interaction with fMet-tRNA was mapped to the C2 sub-domain of domain VI of this factor.

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).

Do plastid envelope membranes play a role in the expression of the plastid genome?

A unique biochemical machinery is present within the two envelope membranes surrounding plastids (Joyard et al., Plant Physiol. 118 (1998) 715-723) that reflects the stage of development of the plastid and the specific metabolic requirements of the various tissues. Envelope membranes are the site for the synthesis and metabolism of specific lipids. They are also the site of transport of metabolites, proteins and information between plastids and surrounding cellular compartments. For instance, a complex machinery for the import of nuclear-encoded plastid proteins is rapidly being elucidated. The functional studies of plastid envelope membranes result in the characterization of an increasing number of envelope proteins with unexpected functions. For instance, recent experiments have demonstrated that envelope membranes bind specifically to plastid genetic systems, the nucleoids surrounded by plastid ribosomes. At early stages of plastid differentiation, the inner envelope membrane contains a unique protein (named PEND protein) that binds specifically to plastid DNA. This tight connection suggests that the PEND protein is at least involved in partitioning the plastid DNA to daughter plastids during division. The PEND protein can also provide a physical support for replication and transcription. In addition, factors involved in the control of plastid protein synthesis can become associated to envelope membranes. This was shown for a protein homologous to the E. coli ribosome recycling factor and for the stabilizing factors of some specific chloroplast mRNAs encoding thylakoid membrane proteins. In fact, the envelope membranes together with the plastid DNA are the two essential constituents of plastids that confer identity to plastids and their interactions are becoming uncovered through molecular as well as cytological studies. In this review, we will focus on these recent observations (which are consistent with the endosymbiotic origin of plastids) and we discuss possible roles for the plastid envelope in the expression of plastid genome.

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

The mature form of the chloroplast translational initiation factor 3 (IF3chl) from Euglena gracilis consists of an internal region homologous to prokaryotic IF3 flanked by long NH2- and COOH-terminal extensions. Sequences in these extensions reduce the activity of the homology domain in promoting initiation complex formation with chloroplast mRNAs and 30 S ribosomal subunits. A series of deletions of the NH2- and COOH-terminal extensions of IF3chl were constructed and tested for their effects on the activity of the homology domain. About half of the inhibitory effect arises from sequences within 9 residues of the junction between the NH2-terminal extension and the homology domain. The remaining inhibitory effect is the result of sequences in the COOH-terminal extension. The equilibrium constant governing the binding of the homology domain of IF3chl to 30 S subunits is estimated to be 1.3 x 10(7) M-1. Sequences close to the junction of the NH2-terminal extension and the homology domain reduce this binding constant about 10-fold. Sequences in the COOH-terminal extension have a similar negative effect. The negative effects of these two regions are cumulative, resulting in a 100-fold reduction of the binding constant. The 9 residues at the NH2-terminal extension effectively prevent the proofreading activity of IF3chl. The entire COOH-terminal extension reduces the proofreading ability by about half. These results are discussed in terms of the proposed three-dimensional structure of the homology domain of IF3chl.

Expression and functional analysis of Euglena Gracilis chloroplast initiation factor 3

A portion of a cDNA predicted to encode the mature form of Euglena gracilis chloroplast translational initiation factor 3 (IF-3chlM, molecular mass, 46 402) and the portion of this factor homologous to bacterial IF-3 (IF-3chlH, molecular mass 22 829) have been cloned and expressed in Escherichia coli as histidine-tagged proteins. The homology domain can be expressed in reasonable levels in E. coli. However, IF-3chlM is quite toxic and can only be produced in small amounts. Both forms of the chloroplast factor are associated with E. coli ribosomes. Purification procedures have been developed for both IF-3chlM and IF-3chlH using Ni-NTA affinity chromatography followed by ion exchange chromatography. IF-3chlM and IF-3chlH are active in promoting ribosome dissociation and in promoting the binding of fMet-tRNA to E. coli ribosomes. However, IF-3chlH has at least 5-fold more activity than either native IF-3chl or IF-3chlM in promoting initiation complex formation on chloroplast 30S ribosomal subunits in the presence of a mRNA carrying a natural translational initiation signal. This observation suggests that regions of IF-3chl lying outside of the homology domain may down-regulate the activity of this factor.

Nucleotide and aminoacyl-tRNA specificity of the mammalian mitochondrial elongation factor EF-Tu.Ts complex

The bovine mitochondrial elongation factor Tu.Ts complex (EF-Tu.Tsmt) promotes the binding of aminoacyl-tRNA to ribosomes. In the presence of GTP, this complex functions catalytically. Both dGTP and ddGTP can replace GTP although about 4-fold higher concentrations are required. ATP, CTP and UTP are not active. ITP can replace GTP when used at 10- to 20-fold higher concentrations. The catalytic use of EF-Tu.Tsmt is inhibited by GDP but not by GMP. XDP also inhibits although about 20-fold higher concentrations are required. EF-Tu.Tsmt will promote the binding of Phe-tRNA to either Escherichia coli or mitochondrial ribosomes. Unlike E. coli EF-Tu, EF-Tu.Tsmt will promote the binding of AcPhe-tRNA to ribosomes about 25% as efficiently as Phe-tRNA. EF-Tu.Tsmt is active in catalyzing the binding of E. coli Met-tRNAmmet to ribosomes. EF-Tu.Tsmt has about 30% as much activity with E. coli Met-tRNAimet but has essentially no activity with E. coli fMet-tRNAimet. Neither yeast Met-tRNAimet nor fMet-tRNAimet is recognized by bovine EF-Tu.Tsmt.

Expression, purification, and mechanistic studies of bovine mitochondrial translational initiation factor 2

A complete cDNA clone encoding bovine mitochondrial translational initiation factor 2 (IF-2mt) has been obtained. The regions of the cDNA corresponding to mature IF-2mt and several of its functional domains have been expressed in Escherichia coli as histidine-tagged proteins. The precursor (approximately 90 kDa) and mature (approximately 85 kDa) forms of IF-2mt are toxic to E. coli and can only be expressed at low levels. Shorter forms of this factor (approximately 80 and approximately 72 kDa) are also found during the expression of mature IF-2mt. The various forms of IF-2mt can be separated by high performance liquid chromatography. All of these forms are active in promoting the GTP-dependent binding of formyl-Met-tRNA to the small subunit of either E. coli or bovine mitochondrial ribosomes. IF-2mt can bind to mitochondrial ribosomes in the absence of GTP, initiator tRNA, or messenger RNA. The presence of GTP stimulates IF-2mt binding to ribosomes about 3-fold. IF-2mt interacts only weakly with GTP or with the initiator tRNA in the absence of ribosomes. Molecular dissection of IF-2mt shows that a long deletion (approximately 150 amino acid residues) from the NH2-terminal region does not affect its activity in vitro. The COOH domain of IF-2mt (amino acid residues 332-727) can bind to ribosomes even though it does not promote initiator-tRNA binding.

Bovine mitochondrial initiation and elongation factors

The procedures summarized above provide nearly homogeneous preparations of IF-2mt, EF-Tu. Tsmt, and EF-Gmt. The scheme developed for IF-2mr leads to a 24,000-fold purification of this factor with a 26% recovery of activity. Analysis by SDS-polyacrylamide gel electrophoresis and gel filtration chromatography indicates that this factor functions as a monomer with a molecular weight of about 85,000. The scheme developed EF-Tu.Tsmt provides a 10,000-fold purification with an overall yield of about 10%. The EF-Tumt component in this complex has a molecular weight of about 46,000, whereas EF-Tsmt has a molecular weight of about 32,000 on SDS-polyacrylamide gel electrophoresis. The EF-Tu. Tsmt complex is tightly associated and appears to have a native molecular weight of about 70,000. The five-step purification procedure outlined above for EF-Gmt results in a 14,000-fold purification of EF-Gmt with a 2-5% recovery of activity. Analysis by SDS-polyacrylamide gel electrophoresis and gel filtration chromatography indicates that EF-Gmt functions as a monomeric protein with an apparent molecular weight of about 80,000.

Initiation complex formation on Euglena chloroplast 30S subunits in the presence of natural mRNAs

An in vitro system has been developed that allows the formation of translation initiation complexes with Euglena chloroplast 30S ribosomal subunits and natural mRNAs. For these experiments two regions of the Euglena chloroplast genome have been cloned behind the T7 transcriptional promoter and the corresponding RNAs synthesized in vitro. These mRNAs are capable of forming initiation complexes with chloroplast 30S subunits in the presence of fMet-tRNA and E. coli initiation factors. Deletion of the normal translation start site results in a message that is no longer recognized by the chloroplast subunits suggesting that the correct AUG initiation codon on the mRNA is being selected by the small ribosomal subunit. Initiation complex formation with the chloroplast 30S subunits is specific for chloroplast mRNAs and mRNA from the phage MS2 is not active in this system.

The gene encoding translation initiation factor 3 is highly conserved in gram-negative bacteria

A 1.1-kb Hp alpha I fragment of the Escherichia coli chromosome containing the gene for translation initiation factor 3 was employed as a probe in heterologous hybridization to chromosomal DNA from a variety of other procaryotes. Positive hybridization was observed to DNA derived from all gram-negative bacteria tested. In contrast, no hybridization to DNA from gram-positive bacteria was detected. In addition, homologous sequences were found in Euglena gracilis chloroplast DNA, while this was not the case with Saccharomyces cerevisiae mitochondrial DNA. These results are discussed in light of existing data on the components and mechanism of translation initiation in the various organisms and organelles employed in this study.