Mutations in Elongation Factor Ef-1α Affect the Frequency of Frameshifting and Amino Acid Misincorporation in Saccharomyces Cerevisiae

A mutational analysis of the eukaryotic elongation factor EF-1 alpha indicates that this protein functions to limit the frequency of errors during genetic code translation. We found that both amino acid misincorporation and reading frame errors are controlled by EF-1 alpha. In order to examine the function of this protein, the TEF2 gene, which encodes EF-1 alpha in Saccharomyces cerevisiae, was mutagenized in vitro with hydroxylamine. Sixteen independent TEF2 alleles were isolated by their ability to suppress frameshift mutations. DNA sequence analysis identified eight different sites in the EF-1 alpha protein that elevate the frequency of mistranslation when mutated. These sites are located in two different regions of the protein. Amino acid substitutions located in or near the GTP-binding and hydrolysis domain of the protein cause suppression of frameshift and nonsense mutations. These mutations may effect mistranslation by altering the binding or hydrolysis of GTP. Amino acid substitutions located adjacent to a putative aminoacyl-tRNA binding region also suppress frameshift and nonsense mutations. These mutations may alter the binding of aminoacyl-tRNA by EF-1 alpha. The identification of frameshift and nonsense suppressor mutations in EF-1 alpha indicates a role for this protein in limiting amino acid misincorporation and reading frame errors. We suggest that these types of errors are controlled by a common mechanism or closely related mechanisms.     

Interaction of ZPR1 with Translation Elongation Factor-1α in Proliferating Cells

The zinc finger protein ZPR1 is present in the cytoplasm of quiescent mammalian cells and translocates to the nucleus upon treatment with mitogens, including epidermal growth factor (EGF). Homologues of ZPR1 were identified in yeast and mammals. These ZPR1 proteins bind to eukaryotic translation elongation factor-1α (eEF-1α). Studies of mammalian cells demonstrated that EGF treatment induces the interaction of ZPR1 with eEF-1α and the redistribution of both proteins to the nucleus. In the yeast Saccharomyces cerevisiae, genetic analysis demonstrated that ZPR1 is an essential gene. Deletion analysis demonstrated that the NH₂-terminal region of ZPR1 is required for normal growth and that the COOH-terminal region was essential for viability in S. cerevisiae. The yeast ZPR1 protein redistributes from the cytoplasm to the nucleus in response to nutrient stimulation. Disruption of the binding of ZPR1 to eEF-1α by mutational analysis resulted in an accumulation of cells in the G2/M phase of cell cycle and defective growth. Reconstitution of the ZPR1 interaction with eEF-1α restored normal growth. We conclude that ZPR1 is essential for cell viability and that its interaction with eEF-1α contributes to normal cellular proliferation.     

Characterization of Mutations That Suppress the Temperature-Sensitive Growth of the Hpr1Δ Mutant of Saccharomyces Cerevisiae

The hpr1Δ3 mutant of Saccharomyces cerevisiae is temperature-sensitive for growth at 37° and has a 1000-fold increase in deletion of tandem direct repeats. The hyperrecombination phenotype, measured by deletion of a leu2 direct repeat, is partially dependent on the RAD1 and RAD52 gene products, but mutations in these RAD genes do not suppress the temperature-sensitive growth phenotype. Extragenic suppressors of the temperature-sensitive growth have been isolated and characterized. The 14 soh (suppressor of hpr1) mutants recovered represent eight complementation groups, with both dominant and recessive soh alleles. Some of the soh mutants suppress hpr1 hyperrecombination and are distinct from the rad mutants that suppress hpr1 hyperrecombination. Comparisons between the SOH genes and the RAD genes are presented as well as the requirement of RAD genes for the Soh phenotypes. Double soh mutants have been analyzed and reveal three classes of interactions: epistatic suppression of hpr1 hyperrecombination, synergistic suppression of hpr1 hyperrecombination and synthetic lethality. The SOH1 gene has been cloned and sequenced. The null allele is 10-fold increased for recombination as measured by deletion of a leu2 direct repeat.     

Coordination of Eukaryotic Translation Elongation Factor 1A (eEF1A) Function in Actin Organization and Translation Elongation by the Guanine Nucleotide Exchange Factor eEF1B��

Eukaryotic translation elongation factor 1A (eEF1A) both shuttles aminoacyl-tRNA (aa-tRNA) to the ribosome and binds and bundles actin. A single domain of eEF1A is proposed to bind actin, aa-tRNA and the guanine nucleotide exchange factor eEF1Bα. We show that eEF1Bα has the ability to disrupt eEF1A-induced actin organization. Mutational analysis of eEF1Bα F163, which binds in this domain, demonstrates effects on growth, eEF1A binding, nucleotide exchange activity, and cell morphology. These phenotypes can be partially restored by an intragenic W130A mutation. Furthermore, the combination of F163A with the lethal K205A mutation restores viability by drastically reducing eEF1Bα affinity for eEF1A. This also results in a consistent increase in actin bundling and partially corrected morphology. The consequences of the overlapping functions in this eEF1A domain and its unique differences from the bacterial homologs provide a novel function for eEF1Bα to balance the dual roles in actin bundling and protein synthesis.The final step of gene expression takes place at the ribosome as mRNA is translated into protein. In the yeast Saccharomyces cerevisiae, elongation of the polypeptide chain requires the orchestrated action of three soluble factors. The eukaryotic elongation factor 1 (eEF1)² complex delivers aminoacyl-tRNA (aa-tRNA) to the empty A-site of the elongating ribosome (1). The eEF1A subunit is a classic G-protein that acts as a “molecular switch” for the active and inactive states based on whether GTP or GDP is bound, respectively (2). Once an anticodon-codon match occurs, the ribosome acts as a GTPase-activating factor to stimulate GTP hydrolysis resulting in the release of inactive GDP-bound eEF1A from the ribosome. Because the intrinsic rate of GDP release from eEF1A is extremely slow (3, 4), a guanine nucleotide exchange factor (GEF) complex, eEF1B, is required (5, 6). The yeast S. cerevisiae eEF1B complex contains two subunits, the essential catalytic subunit eEF1Bα (5) and the non-essential subunit eEF1Bγ (7).The co-crystal structures of eEF1A:eEF1Bα C terminus:GDP: Mg²⁺ and eEF1A:eEF1Bα C terminus:GDPNP (8, 9) demonstrated a surprising structural divergence from the bacterial EF-Tu-EF-Ts (10) and mammalian mitochondrial EF-Tu_mt-EF-Ts_mt (11). While the G-proteins have a similar topology and consist of three well-defined domains, a striking difference was observed in binding sites for their GEFs. The C terminus of eEF1Bα interacts with domain I and a distinct pocket of domain II eEF1A, creating two binding interfaces. In contrast, the bacterial counterpart EF-Ts and mammalian mitochondrial EF-Ts_mt, make extensive contacts with domain I and III of EF-Tu and EF-Tu_mt, respectively. The altered binding interface of eEF1Bα to domain II of eEF1A is particularly unexpected given the functions associated with domain II of eEF1A and EF-Tu. The crystal structure of the EF-Tu:GDPNP:Phe-tRNA^Phe complex reveals aa-tRNA binding to EF-Tu requires only minor parts of both domain II and tRNA to sustain stable contacts (12). That eEF1A employs the same aa-tRNA binding site is supported by genetic and biochemical data (13-15). Interestingly, eEF1Bα contacts many domain II eEF1A residues in the region hypothesized to be involved in the binding of the aa-tRNA CCA end (8). Because, the shared binding site of eEF1Bα and aa-tRNA on domain II of eEF1A is significantly different between the eukaryotic and bacterial/mitochondrial systems, eEF1Bα may play a unique function aside from guanine nucleotide release in eukaryotes.In eukaroytes, eEF1A is also an actin-binding and -bundling protein. This noncanonical function of eEF1A was initially observed in Dictyostelium amoebae (16). It is estimated that greater than 60% of Dictyostelium eEF1A is associated with the actin cytoskeleton (17). The eEF1A-actin interaction is conserved among species from yeast to mammals, suggesting the importance of eEF1A for cytoskeleton integrity. Using a unique genetic approach, multiple eEF1A mutations were identified that altered cell growth and morphology, and are deficient in bundling actin in vitro (18, 19). Intriguingly, most mutations localized to domain II, the shared aa-tRNA and eEF1Bα binding site. Previous studies have demonstrated that actin bundling by eEF1A is significantly reduced in the presence of aa-tRNA while eEF1A bound to actin filaments is not in complex with aa-tRNA (20). Therefore, actin and aa-tRNA binding to eEF1A is mutually exclusive. In addition, overexpression of yeast eEF1A or actin-bundling deficient mutants do not affect translation elongation (18, 19, 21), suggesting eEF1A-dependent cytoskeletal organization is independent of its translation elongation function (18, 20). Thus, while aa-tRNA binding to domain II is conserved between EF-Tu and eEF1A, this actin bundling function associated with eEF1A domain II places greater importance on its relationship with the “novel” binding interface between eEF1A domain II and eEF1Bα.Based on this support for an overlapping actin bundling and eEF1Bα binding site in eEF1A domain II, we hypothesize that eEF1Bα modulates the equilibrium between actin and translation functions of eEF1A and is perhaps the result of evolutionary selective pressure to balance the eukaryotic-specific role of eEF1A in actin organization. Here, we present kinetic and biochemical evidence using a F163A mutant of eEF1Bα for the importance of the interactions between domain II of eEF1A and eEF1Bα to prevent eEF1A-dependent actin bundling as well as promoting guanine nucleotide exchange. Furthermore, altered affinities of eEF1Bα mutants for eEF1A support that this complex formation is a determining factor for eEF1A-induced actin organization. Interestingly, the F163A that reduces eEF1A affinity is an intragenic suppressor of the lethal K205A eEF1Bα mutant that displays increased affinity for eEF1A. This, along with a consistent change in the actin bundling correlated with the affinity of eEF1Bα for eEF1A, indicates that eEF1Bα is a balancer, directing eEF1A to translation elongation and away from actin, and alterations in this balance result in detrimental effects on cell growth and eEF1A function.     

The Daf2-2 Mutation, a Dominant Inhibitor of the Ste4 Step in the α-Factor Signaling Pathway of Saccharomyces Cerevisiae Matα Cells

A dominant mutation (DAF2-2) resulting in resistance to the mating pheromone alpha-factor in Saccharomyces cerevisiae MATa cells was identified and characterized genetically. Whereas wild-type cells induce a high level of the FUS1 mRNA from a low baseline on exposure to alpha-factor, DAF2-2 cells were constitutive producers of an intermediate level of FUS1 RNA; the level was increased only modestly by alpha-factor. FUS1 constitutivity required STE4, STE5 and STE18, but did not require STE2, the alpha-factor receptor gene. DAF2-2 suppressed the alpha-factor supersensitivity of a STE2 C-terminal truncation, and suppressed lethality due to scg1 mutations. Thus DAF2-2 may act by uncoupling the signaling pathway from alpha-factor binding at some point in the pathway between Scg1 inactivation and the action of Ste4, Ste5 and Ste18; this uncoupling might occur at the expense of partial constitutive activation of the pathway. DAF2-2 suppressed the unconditional cell-cycle arrest phenotype of a dominant "constitutive signaling" allele of STE4 (STE4Hpl), although the constitutive FUS1 phenotype of DAF2-2 was suppressed by ste4 null mutations; therefore DAF2-2 may directly affect the performance of the STE4 step.     

On the value of Elongation factor-1α for reconstructing pterygote insect phylogeny

Pterygota are traditionally divided in two lineages, the “Palaeoptera” and Neoptera. Despite several efforts neither morphology nor molecular systematics have resolved the phylogeny of the pterygote insects. Too few markers have yet been identified for adequately tracking mesozoic-aged divergences. We tested the Elongation factor-1α for its phylogenetic value in pterygote insect systematics. This highly conserved nuclear protein-coding gene has previously been reported to be useful in other groups for phylogenetic analyses at the intraordinal level as well as at the interordinal level. The analyses suggest that EF-1α DNA sequences as well as intron positions provide informative markers for pterygote phylogenetics.     

The Pheromone Receptors Inhibit the Pheromone Response Pathway in Saccharomyces Cerevisiae by a Process That Is Independent of Their Associated Gα Protein

Dominant mutations at the DAF2 locus confer resistance to the cell-cycle arrest that normally occurs in MATa cells exposed to α-factor. One of these alleles, DAF2-2, has also been shown to suppress the constitutive signaling phenotype of null alleles of the gene encoding the α subunit of the G protein involved in pheromone signaling. These observations indicate that DAF2-2 inhibits transmission of the pheromone response signal. The DAF2-2 mutation has two effects on the expression of a pheromone inducible gene, FUS1. In DAF2-2 cells, FUS1 RNA is present at an increased basal level but is no longer fully inducible by pheromone. Cloning of DAF2-2 revealed that it is an allele of STE3, the gene encoding the a-factor receptor. STE3 is normally an α-specific gene, but is inappropriately expressed in a cells carrying a STE3(DAF2-2) allele. The two effects of STE3(DAF2-2) alleles on the pheromone response pathway are the result of different functions of the receptor. The increased basal level of FUS1 RNA is probably due to stimulation of the pathway by an autocrine mechanism, because it required at least one of the genes encoding a-factor. Suppression of a null allele of the G(α) subunit gene, the phenotype associated with the inhibitory function of STE3, was independent of a-factor. This suppression was also observed when the wild-type STE3 gene was expressed in a cells under the control of an inducible promoter. Inappropriate expression of STE2 in α cells was able to suppress a point mutation, but not a null allele, of the G(α) subunit gene. The ability of the pheromone receptors to block the pheromone response signal in the absence of the G(α) subunit indicates that these receptors interact with another component of the signal transduction pathway.     

Construction of a Novel а-Agglutinin Expression System on the Surface of Wild-Type Saccharomyces cerevisiae Y5 and Genetic Immobilization of β-Glucosidase1

Saccharomyces cerevisiae Y5 is a newly developed wild-type strain demonstrating a strong bioethanol fermentation capacity. In the present study, we attempted to construct an а-agglutinin-displaying expression system for genetic immobilization β-glucosidase1 (BGL1) on a yeast cell surface in its active form. The AGA1 gene of native а-agglutinin under the control of a GAL1 promoter was integrated into the genomes of S. cerevisiae Y5. A cDNA-encoding BGL1 from the fungus Aspergillus aculeatus was fused with the gene encoding the C-terminal half of Aga2p. The multicopy plasmid containing this fusion gene was introduced into S. cerevisiae and expressed under the control of the GAL1 promoter as was the AGA1 gene. The display of the BGL1 protein on the cell surface was confirmed by immunofluorescence microscopy and Western blotting. The cells displaying BGL1 could produce 5.07 g/l ethanol from 20 g/l cellobiose as the sole carbon source. These results demonstrated that BGL1 was anchored on the cell wall in its active form.     

Elongation factor 1α genes of the red alga Porphyra purpurea include a novel, developmentally specialized variant

The life cycle of the red alga Porphyra purpurea alternates between two morphologically distinct phases: a shell-boring, filamentous sporophyte and a free-living, foliose gametophyte. From a subtracted cDNA library enriched for sporophyte-specific sequences, we isolated a cDNA encoding an unusual elongation factor 1 (EF-1) that is expressed only in the sporophyte. A second EF-1 gene that is expressed equally in the sporophyte and the gametophyte was isolated from a genomic library. These are the only EF-1 genes detectable in P. purpurea. The constitutively expressed gene encodes and EF-1 very similar to those of most eukaryotes. However, the sporophyte-specific EF-1 is one of the most divergent yet described, with nine insertions or deletions ranging in size from 1 to 26 amino acids. This is the first report of a developmental stage-specific EF-1 outside of the animal kingdom and suggests a fundamental role for EF-1 in the developmental process.     

Expression of a library of fungal β-glucosidases in Saccharomyces cerevisiae for the development of a biomass fermenting strain

Converting cellulosic biomass to ethanol involves the enzymatic hydrolysis of cellulose and the fermentation of the resulting glucose. The yeast Saccharomyces cerevisiae is naturally ethanologenic, but lacks the enzymes necessary to degrade cellulose to glucose. Towards the goal of engineering S. cerevisiae for hydrolysis of and ethanol production from cellulose, 35 fungal β-glucosidases (BGL) from the BGL1 and BGL5 families were screened for their ability to be functionally expressed and displayed on the cell surface. Activity assays revealed that the BGL families had different substrate specificities, with only the BGL1s displaying activity on their natural substrate, cellobiose. However, growth on cellobiose showed no correlation between the specific growth rates, the final cell titer, and the level of BGL1 activity that was expressed. One of the BGLs that expressed the highest levels of cellobiase activity, Aspergillus niger BGL1 (Anig-Bgl101), was then used for further studies directed at developing an efficient cellobiose-fermenting strain. Expressing Anig-Bgl101 from a plasmid yielded higher ethanol levels when secreted into the medium rather than anchored to the cell surface. In contrast, ethanol yields from anchored and secreted Anig-Bgl101 were comparable when integrated on the chromosome. Flow cytometry analysis revealed that chromosomal integration of Anig-Bgl101 resulted in a higher percentage of the cell population that displayed the enzyme but with overall lower expression levels.     

Translation Elongation Factor 1A Mutants with Altered Actin Bundling Activity Show Reduced Aminoacyl-tRNA Binding and Alter Initiation via eIF2α Phosphorylation

Apart from its canonical function in translation elongation, eukaryotic translation elongation factor 1A (eEF1A) has been shown to interact with the actin cytoskeleton. Amino acid substitutions in eEF1A that reduce its ability to bind and bundle actin in vitro cause improper actin organization in vivo and reduce total translation. Initial in vivo analysis indicated the reduced translation was through initiation. The mutant strains exhibit increased levels of phosphorylated initiation factor 2α (eIF2α) dependent on the presence of the general control nonderepressible 2 (Gcn2p) protein kinase. Gcn2p causes down-regulation of total protein synthesis at initiation in response to increases in deacylated tRNA levels in the cell. Increased levels of eIF2α phosphorylation are not due to a general reduction in translation elongation as eEF2 and eEF3 mutants do not exhibit this effect. Deletion of GCN2 from the eEF1A actin bundling mutant strains revealed a second defect in translation. The eEF1A actin-bundling proteins exhibit changes in their elongation activity at the level of aminoacyl-tRNA binding in vitro. These findings implicate eEF1A in a feedback mechanism for regulating translation at initiation.     

The Titer of the Lentiviral Vector Encoding Chimeric TRIM5α-HRH Gene is Reduced Due to Expression of TRIM5α-HRH in Producer Cells and the Negative Effect of Ef1α Promoter

Molecular Biology - The chimeric protein TRIM5α-HRH is a promising antiviral factor for HIV-1 gene therapy. This protein is able to protect cells from HIV-1 by blocking the virus in the...     

Expression of a Soluble Functional Form of the Integrin α4β1 in Mammalian Cells

The integrin α₄β₁(VLA4) has been expressed as a soluble, active, heterodimeric immunoglobulin fusion protein. cDNAs encoding the extracellular domains of the human α₄ and β₁ subunits were fused to the genomic DNA encoding the human γ1 immunoglobulin Fc domain and functional integrin fusion protein was expressed as a secreted, soluble molecule from a range of mammalian cell lines. Specific mutations were introduced into the Fc region of the molecules to promote α₄β₁ heterodimer formation. The soluble α₄β₁ Fc fusion protein exhibited divalent cation dependent binding to VCAM-1, which was blocked by the appropriate function blocking antibodies. The apparent K_d for VCAM-1 binding were similar for both the soluble and native forms of α₄β₁. In addition, the integrin–Fc fusion was shown to stain cells expressing VCAM-1 on their surface by FACs analysis. This approach for expressing soluble α₄β₁ should be generally applicable to a range of integrins.     

Diversification of the Microtubule System in the Early Stage of Eukaryote Evolution: Elongation Factor 1α and α-Tubulin Protein Phylogeny of Termite Symbiotic Oxymonad and Hypermastigote Protists

The symbiotic protists of the lower termite have been regarded as a model of early-branched eukaryotes because of their simple cellular systems and morphological features. However, cultivation of these symbiotic protists is very difficult. For this reason, these interesting protists have not been well characterized in terms of their molecular biology. In research on these organisms which have not yet been cultivated, we developed a method for retrieving specific genes from a small number of cells, through micromanipulation without axenic cultivation, and we obtained EF-1 alpha and alpha-tubulin genes from members of the Hypermastigida--the parabasalid protist Trichonympha agilis and the oxymonad protists Pyrsonympha grandis and Dinenympha exilis--from the termite Reticulitermes speratus gut community. Results of phylogenetic analysis of the amino acid sequences of both proteins, EF-1 alpha and alpha-tubulin, indicate that the hypermastigid, parabasalid, and oxymonad protists do not share a close common ancestor. In addition, although the EF-1 alpha phylogeny indicates that these two groups of protists branched at an early stage of eukaryotic evolution, the alpha-tubulin phylogeny indicates that these protists can be assigned to two diversified clades. As shown in a recent investigation of alpha-tubulin phylogeny, eukaryotic organisms can be divided into three classes: an animal--parabasalids clade, a plant--protists clade, and the diplomonads. In this study, we show that parabasalids, including hypermastigids, can be classified as belonging to the animal--parabasalids clade and the early-branching eukaryote oxymonads can be classified as belonging to the plant--protists clade. Our findings suggest that these protists have a cellular microtubule system that has diverged considerably, and it seems that such divergence of the microtubule system occurred in the earliest stage of eukaryotic evolution.