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Query: UNIPROT:Q3V6T2 (ape)
 2,133 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Using a positional cloning approach, we have isolated an expressed gene from a flow-sorted Y chromosome cosmid library. The isolation of this gene was based on the identification of the Y-231 cosmid that contains CpG rich sequences (HTF islands) in its human insert. The Y-231 cosmid was capable of detecting a 1.3 kb transcript in poly (A)+ RNA samples from human testis. Several cDNA clones were isolated from a human testis cDNA library constructed in lambda gt10. In addition, DNA-mediated gene transfer and restriction enzyme mapping experiments demonstrated that two functional transcriptional units are present within the Y-231 cosmid. DNA sequencing analysis showed that the largest cDNA clone contains 1075 bp of unique sequence and a poly (A) track at the 3' end of the corresponding mRNA. An open reading frame of 762 bp that encodes a predicted protein of 253 amino acids with a calculated molecular weight of 28.9 kD was identified. The Y-231 structural gene encompasses approximately 2.7 kb of genomic sequence and contains six exons that are interrupted by five introns. The Y-231 gene shares very high (97%) identity at the DNA level to a previously described Y-specific gene, testis specific protein Y-encoded (TSPY) gene, suggesting the possibility that these two genes are related, if not identical. However, the TSPY gene has been postulated to be intronless. Further PCR and RT-PCR analyses of these two genes and their transcripts have provided evidence supporting the hypothesis that they are the same gene and are members of a Y-specific repeated gene family containing intronic sequences. The Y-231 (TSPY) gene is conserved in the male genome and expressed in the testis of the chimpanzee, suggesting that it may play an important role in the physiology of this organ in man and the great ape.
Hum Mol Genet 1992 Dec
PMID:Molecular isolation and characterization of an expressed gene from the human Y chromosome. 128 95

We have isolated and sequenced a portion of the gene encoding the carboxy-terminal domain (CTD) of the largest subunit of RNA polymerase II from three mammals. These mammalian sequences include one rodent and two primate CTDs. Comparisons of the new sequences to mouse and Chinese hamster show a high degree of conservation among the mammalian CTDs. Due to synonymous codon usage, the nucleotide differences between hamster, rat, ape, and human result in no amino acid changes. The amino acid sequence for the mouse CTD appears to have one different amino acid when compared to the other four sequences. Therefore, except for the one variation in mouse, all of the known mammalian CTDs have identical amino acid sequences. This is in marked contrast to the situation among more divergent species. The present study suggests that there is a strong evolutionary pressure to maintain the primary structure of the mammalian CTD.
J Mol Evol 1992 Nov
PMID:Conservation of the mammalian RNA polymerase II largest-subunit C-terminal domain. 148 24

We determined the nucleotide sequence of a 2.5 kb DNA fragment (1 kb is 10(3) base-pairs) that includes exon 1, intron 1 and about 1.4 kb of 5'-flanking DNA of the spider monkey gamma 1-globin pseudogene locus and compared this sequence to its homologous from other primates and rabbit. This region of the gamma 1 locus of spider monkey still retains conserved regulatory elements, suggesting that it became a pseudogene late in New World monkey phylogeny. In the 250 base-pair region immediately 5' from the transcription start site where many known regulatory elements are located, a higher rate of nucleotide substitutions occurred in the ancestral anthropoid (human, ape and monkey) lineage than in the prosimian (galago) lineage, as was also the case for non-synonymous substitutions in the coding region. The opposite pattern was observed for most other non-coding regions and for synonymous substitutions. These substitution patterns correlate with the embryonic-to-fetal transformation of the gamma-globin genes of the ancestral anthropoids. Analysis of the 5'-flanking sequences suggests that 11 gene conversion events have occurred in the anthropoid gamma-gene lineages. In the parts of the 5'-flanking region where no gene conversions have been detected, gamma 2-gene sequences have accumulated more nucleotide changes than gamma 1, which suggests that the gamma 2 gene was the more redundant duplicate that may have accumulated first the nucleotide changes responsible for the anthropoid fetal pattern of gamma-globin gene expression.
J Mol Biol 1992 Apr 05
PMID:Fetal recruitment of anthropoid gamma-globin genes. Findings from phylogenetic analyses involving the 5'-flanking sequences of the psi gamma 1 globin gene of spider monkey Ateles geoffroyi. 156 63

The DRB region of the human and great-ape major histocompatibility complex displays not only gene but also haplotype polymorphism. The number of genes in the human DRB region can vary from one to four, and even greater variability exists among the DRB haplotypes of chimpanzees, gorillas, and orangutans. Accumulating evidence indicates that, like gene polymorphism, part of the haplotype polymorphism predates speciation. In an effort to determine when the gene haplotype polymorphisms emerged in the primate lineage, we sequenced three cDNA clones of the New-World monkey, the cottontop tamarin (Saguinus oedipus). We could identify two DRB loci in this species, one (Saoe-DRB1) occupied by apparently functional alleles (*0101 and *0102) which differ by only two nucleotide substitutions and the other (Saoe-DRB2) occupied by an apparent pseudogene. The Saoe-DRB2 gene contains an extra sequence derived from the 3' portion of exon 2 and placed 5' to this exon. This sequence contains a stop codon which makes the translation of the bulk of the Saoe-DRB2 gene unlikely. Preliminary Southern blot hybridization analysis with probes derived from these two genes suggests that both the DRB gene polymorphism and the haplotype polymorphism in the cottontop tamarin may be low. In most individuals the DRB region of this species probably consists of three genes. Comparisons of the Saoe-DRB sequences with those of other primates suggest that probably all of the DRB genes found until now in the Catarrhini were derived from a common ancestor after the separation of the Catarrhini and Platyrrhini lineages. The extant DRB gene and haplotype polymorphism may therefore have been founded in the mid-Oligocene some 33 Mya.
Mol Biol Evol 1992 May
PMID:Major-histocompatibility-complex DRB genes of a New-World monkey, the cottontop tamarin (Saguinus oedipus). 158 11

The DRB family of human class II major histocompatibility complex (Mhc) loci is unusual in that individuals differ in the number and combination of genes (haplotypes) they carry. Indications are that both the allelic and haplotype polymorphisms of the DRB loci predate speciation. Searching for the evolutionary origins of these polymorphisms, we have sequenced five DRB clones isolated from a cDNA library of a pigtail macaque (Macaca nemestrina) B lymphocyte line. The clones represent five different genes which we designate Mane-DRB*01-Mane-DRB*05. The genes appears to be approximately equidistant from each other, so that allelic relationships between them cannot be established on the basis of the sequence data alone. If positions coding for the peptide-binding region of the class II beta chains are eliminated from sequence comparisons, the Mane-DRB genes appear to be most closely related to the human (HLA) DRB1 genes of the DRw52 group. We interpret this finding to indicate that the ancestral gene of the DRw52 group of human DRB1 alleles separated from the rest of the HLA-DRB1 alleles before the separation of the Old World monkeys (Cercopithecoidea) from the apes (Hominoidea) in the early Oligocene. After this separation, the ancestral DRB1 gene of the DRw52 group duplicated in the Old World monkey lineage to give rise to genes at three loci at least, while in the ape lineage this gene may have remained single and diverged into a number of alleles instead. These findings suggest that some of the polymorphism currently present at the DRB1 locus is greater than 35 Myr old.
Mol Biol Evol 1991 Sep
PMID:Mhc-DRB genes of the pigtail macaque (Macaca nemestrina): implications for the evolution of human DRB genes. 176 59

An 8.4-kb genomic region spanning both the psi eta-globin gene locus and flanking DNA was sequenced from the common gibbon (Hylobates lar). In addition, sequencing of the entire orthologous region from galago (Galago crassicaudatus) was completed. The gibbon and galago sequences, along with published orthologous sequences from 10 other species, were aligned. These noncoding nucleotide sequences represented four human alleles, four apes (chimpanzee, gorilla, organgutan, and gibbon), an Old World monkey (rhesus monkey), two New World monkeys (spider and owl monkeys), tarsier, two strepsirhines (galago and lemur), and goat. Divergence and maximum parsimony analyses of the psi eta genomic region first groups humans and chimpanzees and then, at progressively more ancient branch points, successively joins gorillas, orangutans, gibbons, Old World monkeys, New World monkeys, tarsiers, and strepsirhines (the lemuriform-lorisiform branch of primates). This cladistic pattern supports the taxonomic grouping of all extant hominoids into family Hominidae, the division of Hominidae into subfamilies Hylobatinae (gibbons) and Homininae, the division of Homininae into tribes Pongini (orangutans) and Hominini, and the division of Hominini into subtribes Gorillina (gorillas) and Hominina (chimpanzees and humans). The additional gibbon and galago sequence data provide further support for the occurrence of a graded evolutionary-rate slowdown in the descent of simian primates, with the slowing rate being more pronounced in the great-ape and human lineages than in the gibbon or monkey lineages. A comparison of global versus local molecular clocks reveals that local clock predictions, when focused on a specific number of species within a narrow time frame, provide a more accurate estimate of divergence dates than do those of global clocks.
Mol Biol Evol 1991 Mar
PMID:Molecular evolution of the psi eta-globin gene locus: gibbon phylogeny and the hominoid slowdown. 204 42

The evolution of the anthropoid involucrin gene has resulted largely from a process of vectorial addition of short tandem repeats. The coding region of the involucrin gene of the gibbon (Hylobates lar), including the segment of repeats, has been cloned and sequenced, and its repeat structure can now be compared with that of the other hominoids. In the gibbon, as in the others, repeat additions in the past can be assigned to early, middle, and late regions of the present-day segment of repeats. All 10 repeats of the gibbon early region were completed in a common anthropoid ancestor. All 17 repeats of the gibbon middle region were completed in a common hominoid ancestor. After divergence of the gibbon lineage, eight repeats were added to the middle region of the great ape-human lineages. Seven of these are shared by two to four species, according to the order of their divergences from each other. After its divergence, the gibbon lineage added a short species-specific late region. The gibbon also possesses an incomplete repeat just 3' of the early region, the only addition in this region in any hominoid. Comparison of the number of repeats added with the number of nucleotides substituted shows an inconstant relation between the two.
Mol Biol Evol 1990 May
PMID:The involucrin gene of the gibbon: the middle region shared by the hominoids. 235 62

Using in vitro protein binding and in vivo functional studies, we have identified novel regulatory sequences near the 5' end of murine leukemia virus (MuLV) long terminal repeats (LTRs). These sequences are highly conserved in all MuLV LTRs as well as in feline leukemia virus and gibbon ape leukemia virus LTRs. In this upstream conserved region (UCR), gel retardation assays detected two overlapping but distinct binding sites (UCR-U and UCR-L) for nuclear proteins (UCRF-U and UCRF-L). Three lines of evidence suggest a negative regulatory role for the UCR in viral transcription: (i) an inverse correlation was found between MuLV transcripts and nuclear proteins binding the UCR in the spleens of five different mouse strains; (ii) in vivo treatment of NFS mice with lipopolysaccharide resulted in the induction of splenic viral transcripts and the concomitant disappearance of UCR-binding proteins; and (iii) in mouse L cells transfected with an MuLV LTR linked to the chloramphenicol acetyltransferase (CAT) gene, cotransfected UCR oligonucleotides increased CAT expression, presumably by competing for inhibitory trans-acting factors.
Mol Cell Biol 1989 Feb
PMID:Negative control region at the 5' end of murine leukemia virus long terminal repeats. 254 Apr 25

The clone designated hMF #1 represents a clustered DNA family, located on chromosome 1, consisting of tandem arrays displaying a monomeric length of 40 bp and a repetition frequency of approximately 7 x 10(3) copies per haploid genome. The sequence hMF #1 reveals multiple restriction fragment length polymorphisms (RFLPs) when human genomic DNA is digested with a variety of 4-6-bp recognition sequence restriction enzymes (i.e., Taq I, Eco RI, Pst I, etc.). When hamster and mouse genomic DNA was digested and analyzed, no cross-species homology could be observed. Further investigation revealed considerable hybridization in the higher primates (chimpanzee, gorilla, and orangutan) as well as some monkey species. The evolutionary relationship of this repetitive DNA sequence, found in humans, to that of other primates was explored using two hybridization methods: DNA dot blot to establish copy number and Southern DNA analysis to examine the complexity of the RFLPs. Homology to the hMF #1 sequence was found throughout the suborder Anthropoidea in 14 ape and New and Old World monkey species. However the sequence was absent in one species of the suborder Prosimii. Several discrepancies between "established" evolutionary relationships and those predicted by hMF #1 exist, which suggests that repetitive elements of this type are not reliable indicators of phylogenetic branching patterns. The phenomenon of marked diversity between sequence homologies and copy numbers of dispersed repetitive DNA of closely related species has been observed in Drosophila, mice, Galago, and higher primates. We report here a similar phenomenon for a clustered repeat that may have originated at an early stage of primate evolution.
J Mol Evol 1989 Mar
PMID:Primate evolution of a human chromosome 1 hypervariable repetitive element. 256 37

At least two subunits contributed to the formation in vitro of a specific complex binding to the AP1 consensus sequence (TGAGTCA) in the gibbon ape leukemia virus (GALV) enhancer in MLA144 cells. This complex can be dissociated on a monomeric GALV oligonucleotide affinity column. One protein, termed the core protein, was retained on the oligonucleotide affinity column. The second protein flowed through the oligonucleotide affinity column and, when alone, did not bind to DNA; however, when present with the core protein, it bound strongly and very specifically to the GALV sequence. MLA144 cells contained only trace amounts of c-fos and c-jun by immunoblot analysis, suggesting that the proteins specifically binding to the GALV AP1 site were distinct from c-fos and c-jun. In addition to the major complex that recognized the GALV element, MLA144 cells contained a minor complex that is chromatographically different from and antigenically related to c-fos. The factor in the flowthrough complemented a human T-cell nuclear extract (Jurkat cell line), which, when alone, had no assayable complex that specifically bound to the GALV enhancer; this complementation gave rise to a specific complex similar to that seen in MLA144 cells. Together, these results suggest that the GALV enhancer can interact with multicomponent protein complexes in a cell-line-specific manner.
Mol Cell Biol 1989 Nov
PMID:Multiple components are required for sequence recognition of the AP1 site in the gibbon ape leukemia virus enhancer. 260 94


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