Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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

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.
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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.
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PMID:Major-histocompatibility-complex DRB genes of a New-World monkey, the cottontop tamarin (Saguinus oedipus). 158 11

We have investigated the presence/absence of two types of retroposed sequences found in human ribosomal DNA in equivalent positions in chimpanzee, gorilla, orangutan, gibbon, and rhesus monkey rDNA. These sequences are one pseudogene derived from the single-copy cdc27hs gene and seven complete Alu elements. The 2-kb pseudogene is present in the apes but not in Old World monkeys, indicating fixation in an ape ancestor. Five of the Alu elements are shared by the whole set of primates studied, indicating insertion and fixation prior to the split of the ape and Old World monkey lineages. One is absent only from the rhesus monkey rDNA, and another is absent from both gibbon and rhesus rDNA, indicating fixation at different times in primate evolutionary history. Since branching times for the primate phylogenetic tree are known from a combination of the fossil record and multiple molecular data sets, it is possible to compare Alu fixation times determined from the phylogenetic information with those calculated from Alu element mutation rates.
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PMID:Fixation times of retroposons in the ribosomal DNA spacer of human and other primates. 827 15

Karyotypic homology in relation to human chromosome 9 (HSA 9) was studied through comparative mapping of the immunoglobulin-processed pseudogene C epsilon 3 (IGHEP2) in primates. IGHEP2, which has been mapped to 9p24.2 --> p24.1 in the human genome, was assigned to PTR 11q34 (common chimpanzee), PPA 11q34 (pygmy chimpanzee), PPY 13q16 (orangutan), HLA 8qter (white-handed gibbon), HAG 8qter (agile gibbon), and MFU 14q22 (Japanese macaque) by fluorescence in situ hybridization. To verify the breakpoints of presumed pericentric inversions on the ancestral great ape chromosomes, three DNA markers on HSA 9, cCI9-37 (9q22.1 --> q22.2), cCI9-135 (9q22.32 --> q22.33), and cCI9-208 (9p13.3 --> p13.2), were also assigned to PTR/PPA 11p11 (cCI9-37 and 135), PTR/PPA 11q22 (cCI9-208), PPY 13q22 (cCI9-37 and 135), and PPY 13q12 (cCI9-208). These data more clearly define the position of the breakpoints of pericentric inversions that occurred in the human-chimp ancestral and chimpanzee ancestral chromosomes and support the hypothesis of HSA 9 genesis previously derived from banding analyses of HSA 9 and its homologs.
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PMID:Molecular anatomy of human chromosome 9: comparative mapping of the immunoglobulin processed pseudogene C epsilon 3 (IGHEP2) in primates. 864 93

We have previously reported (Villa et al. (1993), Genomics 18: 223) the characterization of the human ZNF75 gene located on Xq26, which has only limited homology (less than 65%) to other ZF genes in the databases. Here, we describe three human zinc finger genes with 86 to 95% homology to ZNF75 at the nucleotide level, which represent all the members of the human ZNF75 subfamily. One of these, ZNF75B, is a pseudogene mapped to chromosome 12q13. The other two, ZNF75A and ZNF75C, maintain an ORF in the sequenced region, and at least the latter is expressed in the U937 cell line. They were mapped to chromosomes 16 and 11, respectively. All these genes are conserved in chimpanzees, gorillas, and orangutans. The ZNF75B homologue is a pseudogene in all three great apes, and in chimpanzee it is located on chromosome 10 (phylogenetic XII), at p13 (corresponding to the human 12q13). The chimpanzee homologue of ZNF75 is also located on the Xq26 chromosome, in the same region, as detected by in situ hybridization. As expected, nucleotide changes were clearly more abundant between human and orangutan than between human and chimpanzee or gorilla homologues. Members of the same class were more similar to each other than to the other homologues within the same species. This suggests that the duplication and/or retrotranscription events occurred in a common ancestor long before great ape speciation. This, together with the existence of at least two genes in cows and horses, suggests a relatively high conservation of this gene family.
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PMID:The ZNF75 zinc finger gene subfamily: isolation and mapping of the four members in humans and great apes. 866 Nov 44

A large portion of human Xq28 has been completely characterized but the interval between G6PD and Xqter has remained poorly understood. Because of a lack of stable, high-density clone coverage in this region, we constructed a 1.6-Mb bacterial and P1 artificial chromosome (BAC and PAC, respectively) contig to expedite mapping, structural and evolutionary analysis, and sequencing. The contig helped to reposition previously mismapped genes and to characterize the XAP135 pseudogene near the int22h-2 repeat. BAC clones containing the distal int22h repeats also demonstrated spontaneous rearrangements and sparse coverage, which suggested that they were unstable. Because the int22h repeats are involved in genetic diseases, we examined them in great apes to see if they have always been unstable. Differences in copy number among the apes, due to duplications and deletions, indicated that they have been unstable throughout their evolution. Taking another approach toward understanding the genomic nature of distal Xq28, we examined the homologous mouse region and found an evolutionary junction near the distal int22h loci that separated the human distal Xq28 region into two segments on the mouse X chromosome. Finally, haplotype analysis showed that a segment within Xq28 has resisted excessive interchromosomal exchange through great ape evolution, potentially accounting for the linkage disequilibrium recently reported in this region. Collectively, these data highlight some interesting features of the genomic sequence in Xq28 and will be useful for positional cloning efforts, mouse mutagenesis studies, and further evolutionary analyses.
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PMID:Physical and genetic characterization reveals a pseudogene, an evolutionary junction, and unstable loci in distal Xq28. 1182 55

Humans are genetically deficient in the common mammalian sialic acid N-glycolylneuraminic acid (Neu5Gc) because of an Alu-mediated inactivating mutation of the gene encoding the enzyme CMP-N-acetylneuraminic acid (CMP-Neu5Ac) hydroxylase (CMAH). This mutation occurred after our last common ancestor with bonobos and chimpanzees, and before the origin of present-day humans. Here, we take multiple approaches to estimate the timing of this mutation in relationship to human evolutionary history. First, we have developed a method to extract and identify sialic acids from bones and bony fossils. Two Neanderthal fossils studied had clearly detectable Neu5Ac but no Neu5Gc, indicating that the CMAH mutation predated the common ancestor of humans and the Neanderthal, approximately 0.5-0.6 million years ago (mya). Second, we date the insertion event of the inactivating human-specific sahAluY element that replaced the ancestral AluSq element found adjacent to exon 6 of the CMAH gene in the chimpanzee genome. Assuming Alu source genes based on a phylogenetic tree of human-specific Alu elements, we estimate the sahAluY insertion time at approximately 2.7 mya. Third, we apply molecular clock analysis to chimpanzee and other great ape CMAH genes and the corresponding human pseudogene to estimate an inactivation time of approximately 2.8 mya. Taken together, these studies indicate that the CMAH gene was inactivated shortly before the time when brain expansion began in humankind's ancestry, approximately 2.1-2.2 mya. In this regard, it is of interest that although Neu5Gc is the major sialic acid in most organs of the chimpanzee, its expression is selectively down-regulated in the brain, for as yet unknown reasons.
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PMID:Inactivation of CMP-N-acetylneuraminic acid hydroxylase occurred prior to brain expansion during human evolution. 1219 86

We have analysed the genomic structure and transcriptional activity of a 2.3-Mb genomic sequence in the juxtacentromeric region of human chromosome 21. Our work shows that this region comprises two different chromosome domains. The 1.5-Mb proximal domain: (i) is a patchwork of chromosome duplications; (ii) shares sequence similarity with several chromosomes; (iii) contains several gene fragments (truncated genes having an intron/exon structure) intermingled with retrotransposed pseudogenes; and (iv) harbours two genes (TPTE and BAGE2) that belong to gene families and have a cancer and/or testis expression profile. The TPTE gene family was generated before the branching of Old World monkeys from the great ape lineage, by intra- and interchromosome duplications of the ancestral TPTE gene mapping to phylogenetic chromosome XIII. By contrast, the 0.8-Mb distal domain: (i) is devoid of chromosome duplications; (ii) has a chromosome 21-specific sequence; (iii) contains no gene fragments and only one retrotransposed pseudogene; and (iv) harbours six genes including housekeeping genes. G-rich sequences commonly associated with duplication termini cluster at the boundary between the two chromosome domains. These structural and transcriptional features lead us to suggest that the proximal domain has heterochromatic properties, whereas the distal domain has euchromatic properties.
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PMID:Juxtacentromeric region of human chromosome 21: a boundary between centromeric heterochromatin and euchromatic chromosome arms. 1290 39

A retroprocessed pseudogene (retropseudogene) descended from the gene encoding ribonuclease (RNase) H1 has been found in ape genomes that preserves a splice junction mutation event that altered the carboxyl-terminal end of the enzyme. The GT --> GC transition mutant at the 5' splice junction of RNase H1 exon 7/intron 7 led to the absence of exon 8 and more than 1 kb of intron 7 sequence being substituted. Comparison of source gene and pseudogene sequences indicates that the retrotranscription event occurred 19 million years ago. Present in these sequences is an in-frame stop and several available polyadenylation signals, suggesting that the mutant allele could have been translated. At the present time, the genetic fossil is the only evidence that the mutation ever occurred, and thus represents an archival marker of an ancient genetic event in primate evolution.
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PMID:An ancient RNase H1 splice junction mutant preserved in a 19-million-year-old genetic fossil in ape genomes. 1522 Mar 93

Chemokine and chemoattractant receptors are members of the large superfamily of G protein-coupled receptors (GPCR), which control leukocyte chemotaxis. In addition to their physiological role, several chemokine and chemoattractant receptors, such as CCR5 and Duffy, have been directly associated with pathogen entry. GPR33 is an orphan chemoattractant GPCR that was previously identified as a pseudogene in humans. GPR33 evolved in mammals about 125-190 million years ago. The cloning and analysis of more than 120 mammalian GPR33 orthologs from 16 of 18 eutherian orders revealed an inactivation of this chemoattractant GPCR not only in humans, but also in several great ape and rodent species. Intriguingly, in all ape and some rodent species where the inactivation occurred, samples harbored both pseudogene and intact gene variants. The analysis of over 1200 human individuals representing all major linguistic groups revealed that the intact allele of GPR33 is still present in the human population. Estimates of the age of the human alleles suggest inactivation in the past 1 million years. Similarly, analysis of more than 120 wild-caught gray rats (Rattus norvegicus), revealed that inactivation of gpr33 is worldwide fixed and occurred in less than 0.7 million years ago. The coincidental inactivation and its fixation in several species of distantly related mammalian orders suggest a selective pressure on this chemoattractant receptor gene.
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PMID:The rise and fall of the chemoattractant receptor GPR33. 1598 86


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