The primary structure and the functional domains of an elongation factor-1 alpha from Mucor racemosus

We have determined the complete nucleotide sequence for TEF-1, one of three genes coding for elongation factor (EF)-1 alpha in Mucor racemosus. The deduced EF-1 alpha protein contains 458 amino acids encoded by two exons. The presence of an intervening sequence located near the 3' end of the gene was predicted by the nucleotide sequence data and confirmed by alkaline S1 nuclease mapping. The amino acid sequence of EF-1 alpha was compared to the published amino acid sequences of EF-1 alpha proteins from Saccharomyces cerevisiae and Artemia salina. These proteins shared nearly 85% homology. A similar comparison to the functionally analogous EF-Tu from Escherichia coli revealed several regions of amino acid homology suggesting that the functional domains are conserved in elongation factors from these diverse organisms. Secondary structure predictions indicated that alpha helix and beta sheet conformations associated with the functional domains in EF-Tu are present in the same relative location in EF-1 alpha from M. racemosus. Through this comparative structural analysis we have predicted the general location of functional domains in EF-1 alpha which interact with GTP and tRNA.     

Evolution and phylogenetic utility of alignment gaps within intron sequences of three nuclear genes in bumble bees (Bombus)

To test whether gaps resulting from sequence alignment contain phylogenetic signal concordant with those of base substitutions, we analyzed the occurrence of indel mutations upon a well-resolved, substitution-based tree for three nuclear genes in bumble bees (Bombus, Apidae: Bombini). The regions analyzed were exon and intron sequences of long-wavelength rhodopsin (LW Rh), arginine kinase (ArgK), and elongation factor-1alpha (EF-1alpha) F2 copy genes. LW Rh intron had only a few uninformative gaps, ArgK intron had relatively long gaps that were easily aligned, and EF-1alpha intron had many short gaps, resulting in multiple optimal alignments. The unambiguously aligned gaps within ArgK intron sequences showed no homoplasy upon the substitution-based tree, and phylogenetic signals within ambiguously aligned regions of EF-1alpha intron were highly congruent with those of base substitutions. We further analyzed the contribution of gap characters to phylogenetic reconstruction by incorporating them in parsimony analysis. Inclusion of gap characters consistently improved support for nodes recovered by substitutions, and inclusion of ambiguously aligned regions of EF-1alpha intron resolved several additional nodes, most of which were apical on the phylogeny. We conclude that gaps are an exceptionally reliable source of phylogenetic information that can be used to corroborate and refine phylogenies hypothesized by base substitutions, at least at lower taxonomic levels. At present, full use of gaps in phylogenetic reconstruction is best achieved in parsimony analysis, pending development of well-justified and generally applicable methods for incorporating indels in explicitly model-based methods.     

Translation elongation factor-1 alpha interacts with the 3' stem-loop region of West Nile virus genomic RNA.

The conserved 3'-terminal stem-loop (3' SL) of the West Nile virus (WNV) genomic RNA was previously used to probe for cellular proteins that may be involved in flavivirus replication and three cellular proteins were detected that specifically interact with the WNV 3' SL RNA (J. L. Blackwell and M. A. Brinton, J. Virol. 69:5650-5658, 1995). In this study, one of these cellular proteins was purified to apparent homogeneity by ammonium sulfate precipitation and liquid chromatography. Amino acid sequence Western blotting, and supershift analyses identified the cellular protein as translation elongation factor-1 alpha (EF-1 alpha). Competition gel mobility shift assays demonstrated that the interaction between EF-1 alpha and WNV 3' SL RNA was specific. Dephosphorylation of EF-1 alpha by calf intestinal alkaline phosphatase inhibited its binding to WNV 3' SL RNA. The apparent equilibrium dissociation constant for the interaction between EF-1 alpha and WNV 3' SL RNA was calculated to be 1.1 x 10(-9) M. Calculation of the stoichiometry of the interaction indicated that one molecule of EF-1 alpha binds to each molecule of WNV 3' SL RNA. Using RNase footprinting and nitrocellulose filter binding assays, we detected a high-activity binding site on the main stem of the WNV 3' SL RNA. Interaction with EF-1 alpha at the high-activity binding site was sequence specific, since nucleotide substitution in this region reduced the binding activity of the WNV 3' SL RNA for EF-1 alpha by approximately 60%. Two low-activity binding sites were also detected, and each accounted for approximately 15 to 20% of the binding activity. Intracellular association between the host protein and the viral RNA was suggested by coimmunoprecipitation of WNV genomic RNA and EF-1 alpha, using an anti-EF-1 alpha antibody.     

Chromosomal arrangement of the duck alpha-globin genes and primary structure of the embryonic alpha-globin gene pi

A recombinant lambda Charon 4A bacteriophage, D alpha G-1, carrying the genes coding for the duck embryonic (pi') and adult (alpha A, alpha D) alpha-like globins was isolated from a previously constructed duck DNA recombinant library. The three globin genes are transcribed from the same DNA strand and are arranged in the order of their expression during development: 5'-pi'-alpha D-alpha A-3'. We have determined the complete nucleotide sequence of the duck pi'-globin gene, including the flanking regions. Due to the unusual length of intron 1 (963 bp) and intron 2 (568 bp) the 2167-bp duck pi'-globin gene is by far the largest among all known mammalian or avian alpha- and beta-globin genes. For instance, the duck pi'-globin gene introns are almost twice as long as those of the chicken pi'-globin genes. A surprisingly high degree of nucleotide sequence homology (88%) has been found for the 5' flanking region (positions -1 to -223) of the duck and chicken pi'-globin gene.     

Formation of the 3'' end of U1 snRNA is directed by a conserved sequence located downstream of the coding region.

U1 is a small non-polyadenylated nuclear RNA that is transcribed by RNA polymerase II and is known to play a role in mRNA splicing. The mature 3' end of U1 snRNA is formed in at least two steps. The first step generates precursors of U1 RNA with a few extra nucleotides at the 3' end; in the second step, these precursors are shortened to mature U1 RNA. Here, I have determined the sequences required for the first step. Human U1 genes with various deletions and substitutions near the 3' end of the coding region were constructed and introduced into HeLa cells by DNA transfection. The structure of the RNA synthesized during transient expression of the exogenous U1 gene was analyzed by S1 mapping. The results show that a 13 nucleotide sequence located downstream from the U1 coding region and conserved among U1, U2 and U3 genes of different species is the only sequence required to direct the first step in the formation of the 3' end of U1 snRNA.     

Both genes for EF-1α in Candida albicans are translated

In previous work, we showed that Candida albicans has two genes, TEF-1 and TEF-2, which encode identical polypeptides for the highly conserved, essential, protein synthesis factor EF-1 alpha (Breviario et al., 1988). This result prompted questions as to whether C. albicans preferentially uses one of the genes over the other and whether both genes are actually translated into protein. Gene-specific sequence differences in the untranslated portion of each gene made it possible to prepare gene-specific oligonucleotide hybridization probes. Results with the probes showed that the relative steady-state mRNA levels of the two genes were equivalent and that the mRNA for each gene was present in active translation complexes.     

A general upstream binding factor for genes of the yeast translational apparatus.

Fractionation of yeast extracts on heparin-agarose revealed the presence of a DNA footprinting activity that interacted specifically with the 5'-upstream region of TEF1 and TEF2 genes coding for the protein synthesis elongation factor EF-1 alpha, and of the ribosomal protein gene RP51A. The protected regions encompassed the conserved sequences 'HOMOL1' (AACATC TA CG T A G CA) or RPG-box (ACCCATACATT TA) previously detected 200-400 bp upstream of most of the yeast ribosomal protein genes examined. Two types of protein-DNA complexes were separated by a gel electrophoresis retardation assay. Complex 1, formed on TEF1, TEF2 and RP51A 5'-flanking region, was correlated with the protection of a 25-bp sequence. Complex 2, formed on TEF2 or RP51A probes at higher protein concentrations, corresponded to an extended footprint of 35-40 bp. The migration characteristics of the protein-DNA complexes and competition experiments indicated that the same component(s) interacted with the three different promoters. It is suggested that this DNA factor(s) is required for activation and coordinated regulation of the whole family of genes coding for the translational apparatus.     

DNA Sequence Evolution of the Amylase Multigene Family in Drosophila Pseudoobscura

The alpha-Amylase locus in Drosophila pseudoobscura is a multigene family of one, two or three copies on the third chromosome. The nucleotide sequences of the three Amylase genes from a single chromosome of D. pseudoobscura are presented. The three Amylase genes differ at about 0.5% of their nucleotides. Each gene has a putative intron of 71 (Amy1) or 81 (Amy2 and Amy3) bp. In contrast, Drosophila melanogaster Amylase genes do not have an intron. The functional Amy1 gene of D. pseudoobscura differs from the Amy-p1 gene of D. melanogaster at an estimated 13.3% of the 1482 nucleotides in the coding region. The estimated rate of synonymous substitutions is 0.398 +/- 0.043, and the estimated rate of nonsynonymous substitutions is 0.068 +/- 0.008. From the sequence data we infer that Amy2 and Amy3 are more closely related to each other than either is to Amy1. From the pattern of nucleotide substitutions we reason that there is selection against synonymous substitutions within the Amy1 sequence; that there is selection against nonsynonymous substitutions within the Amy2 sequence, or that Amy2 has recently undergone a gene conversion with Amy1; and that Amy3 is nonfunctional and subject to random genetic drift.     

Characterization of a mouse interferon gene locus I. Isolation of a cluster of four alpha interferon genes.

A BALB/c mouse genomic library was screened with a murine interferon alpha 2 (MuIFN-alpha 2) cDNA coding region fragment. Eight clones were isolated which contain different mouse chromosomal segments related to the MuIFN-alpha 2 probe and a 28 kilobase (kb) region of mouse genomic DNA containing four different MuIFN-alpha genes (alpha 1, alpha 4, alpha 5 and alpha 6) was identified and characterized; an intergenic 1000 nucleotide long conserved sequence was found to be associated with three of these four alpha genes, indicating that this alpha-IFN gene cluster evolved through tandem duplications. Sequence analysis revealed the absence of a polyadenylation site in the 3' untranslated region of MuIFN-alpha 1, and showed that one of the genes (alpha 4) contains an internal deletion of 5 amino acids in the coding region.     

The keratin BIIIB gene family: isolation of cDNA clones and structure of a gene and a related pseudogene

The nucleotide sequence of cDNA clones encoding the three major BIIIB high-sulfur wool keratin proteins (BIIIB2, 3, and 4) and the structure of a BIIIB4 gene and a BIIIB3 pseudogene are reported. Although Southern blot analysis indicates that the BIIIB genes comprise a multigene family in the sheep genome, they are poorly represented in genomic DNA libraries. The family sequence homology of the coding region extends into the 5' and 3' untranslated regions and the near 5' flanking region of the BIIIB3 and 4 genes. These homologies suggest that the BIIIB3 and 4 genes represent the latest gene duplication event in the evolution of the BIIIB multigene family. Like the genes coding for other wool keratin matrix protein components, the BIIIB genes have the conserved 18-bp sequence immediately 5' to the initiation codon and also appear to lack introns.     

Chimpanzee fetal G gamma and A gamma globin gene nucleotide sequences provide further evidence of gene conversions in hominine evolution

The fetal globin genes G gamma and A gamma from one chromosome of a chimpanzee (Pan troglodytes) were sequenced and found to be closely similar to the corresponding genes of man and the gorilla. These genes contain identical promoter and termination signals and have exons 1 and 2 separated by the conserved short intron 1 (122 bp) and exons 2 and 3 separated by the more rapidly evolving, larger intron 2 (893 bp and 887 bp in chimpanzee G gamma and A gamma, respectively). Each intron 2 has a stretch of simple sequence DNA (TG)n serving possibly as a "hot spot" for recombination. The two chimpanzee genes encode polypeptide chains that differ only at position 136 (glycine in G gamma and alanine in A gamma) and that are identical to the corresponding human chains, which have aspartic acid at position 73 and lysine at 104 in contrast to glycine and arginine at these respective positions of the gorilla A gamma chain. Phylogenetic analysis by the parsimony method revealed four silent (synonymous) base substitutions in evolutionary descent of the chimpanzee G gamma and A gamma codons and none in the human and gorilla codons. These Homininae (Pan, Homo, Gorilla) coding sequences evolved at one-tenth the average mammalian rate for nonsynonymous and one-fourth that for synonymous substitutions. Three sequence regions that were affected by gene conversions between chimpanzee G gamma and A gamma loci were identified: one extended 3' of the hot spot with G gamma replaced by the A gamma sequence, another extended 5' of the hot spot with A gamma replaced by G gamma, and the third conversion extended from the 5' flanking to the 5' end of intron 2, with G gamma replaced here by the A gamma sequence. A conversion similar to this third one has occurred independently in the descent of the gorilla genes. The four previously identified conversions, labeled C1-C4 (Scott et al. 1984), were substantiated with the addition of the chimpanzee genes to our analysis (C1 being shared by all three hominines and C2, C3, and C4 being found only in humans). Thus, the fetal genes from all three of these hominine species have been active in gene conversions during the descent of each species.      

Cloning, nucleotide sequence, and expression of one of two genes coding for yeast elongation factor 1 alpha

One gene coding for yeast cytoplasmic elongation factor 1 alpha (EF-1 alpha) was isolated by colony hybridization using a cDNA probe prepared from purified EF-1 alpha mRNA. A recombinant plasmid, pLB1, with a 6-kilobase yeast DNA insert, was found by hybrid selection and translation experiments to carry the entire gene. The nucleotide sequence of the gene with its 5'- and 3'-flanking regions was determined. The 5' and 3' ends of EF-1 alpha mRNA were localized by the S1 nuclease mapping technique. The cloned gene, called TEF1, encodes a protein of 458 amino acids (Mr = 50,071) in a single, uninterrupted reading frame. The amino acid sequence shows a strong homology with several domains of Artemia salina EF-1 alpha cytoplasmic factor, as evidenced by diagonal dot matrix analysis. Protein sequence homology is comparatively much lower with the yeast mitochondrial elongation factor. S1 nuclease mapping of the mRNA, hybridization analysis of chromosomal DNA using intragenic or extragenic DNA probes, and gene disruption experiments demonstrated the existence of two genes coding for the cytoplasmic elongation factor EF-1 alpha/haploid genome. The presence of an intact chromosomal TEF1 gene is not essential for growth of haploid yeast cells.