Your search keyword '"Gorilla gorilla genetics"' showing total 28 results

1. Identification of species-specific nuclear insertions of mitochondrial DNA (numts) in gorillas and their potential as population genetic markers.

Author

Soto-Calderón ID, Clark NJ, Wildschutte JV, DiMattio K, Jensen-Seaman MI, and Anthony NM

Subjects

Animals, Base Sequence, Cell Nucleus genetics, DNA genetics, Genome, Pan troglodytes genetics, Phylogeny, Sequence Analysis, DNA, Species Specificity, DNA Transposable Elements, DNA, Mitochondrial genetics, Genetic Markers, Genetics, Population, Gorilla gorilla genetics

Abstract

The first hyper-variable region (HV1) of the mitochondrial control region (MCR) has been widely used as a molecular tool in population genetics, but inadvertent amplification of nuclear translocated copies of mitochondrial DNA (numts) in gorillas has compromised the use of mitochondrial DNA in population genetic studies. At least three putative classes (I, II, III) of gorilla-specific HV1 MCR numts have been uncovered over the past decade. However, the number, size and location of numt loci in gorillas and other apes are completely unknown. Furthermore, little work to date has assessed the utility of numts as candidate population genetic markers. In the present study, we screened Bacterial Artificial Chromosome (BAC) genomic libraries in the chimpanzee and gorilla to compare patterns of mitochondrial-wide insertion in both taxa. We conducted an intensive BLAST search for numts in the gorilla genome and compared the prevalence of numt loci originating from the MCR with other great ape taxa. Additional gorilla-specific MCR numts were retrieved either through BAC library screens or using an anchored-PCR (A-PCR) amplification using genomic DNA from five unrelated gorillas. Locus-specific primers were designed to identify numt insertional polymorphisms and evaluate their potential as population genetic markers. Mitochondrial-wide surveys of chimpanzee and gorilla BACs showed that the number of numts does not differ between these two taxa. However, MCR numts are more abundant in chimpanzees than in other great apes. We identified and mapped 67 putative gorilla-specific numts, including two that contain the entire HV1 domain, cluster with sequences from two numt classes (I, IIb) and will likely co-amplify with mitochondrial sequences using most published HV1 primers. However, phylogenetic analysis coupled with post-hoc analysis of mitochondrial variation can successfully differentiate nuclear sequences. Insertional polymorphisms were evident in three out of five numts examined, indicating their potential utility as molecular markers. Taken together, these findings demonstrate the potentially powerful insight that numts could make in uncovering population history in gorillas and other mammals., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

2. Asymmetry of the midfacial skeleton of eastern lowland gorillas (Gorilla beringei graueri) and potential association with frontal lobe asymmetries.

Author

Heuzé Y and Balzeau A

Subjects

Animals, Facial Bones diagnostic imaging, Female, Frontal Lobe diagnostic imaging, Genetic Variation, Gorilla gorilla genetics, Male, Tomography, X-Ray Computed, Facial Bones anatomy & histology, Frontal Lobe anatomy & histology, Gorilla gorilla anatomy & histology

Published

2014

3. The interplay between genome organization and nuclear architecture of primate evolutionary neo-centromeres.

Author

Lomiento M, Grasser F, Rocchi M, and Müller S

Subjects

Animals, Atelinae genetics, Biological Evolution, Cell Line, Cell Nucleus genetics, Cell Nucleus physiology, Chromosomes, Genome, Gorilla gorilla genetics, Humans, In Situ Hybridization, Fluorescence, Interphase genetics, Macaca nemestrina genetics, Pongo pygmaeus genetics, Centromere genetics, Centromere ultrastructure, Evolution, Molecular, Phylogeny, Primates genetics

Abstract

An Evolutionary Neo-Centromere (ENC) is a centromere that emerged in an ectopic region of a chromosome during evolution. It is thought that the old centromere must be inactivated because dicentric chromosomes are not viable. The aim of the present study was to investigate whether 3D arrangement in the interphase nucleus of the novel and old centromeric domains was affected by the repositioning event. The data we present here strongly indicate that the ENC phenomenon does not affect the 3D location of either novel or old centromeres. Very likely, other features, such as gene density, rather than the newly acquired or lost functions, define positioning in the nucleus., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

4. Dental and phylogeographic patterns of variation in gorillas.

Author

Pilbrow V

Subjects

Africa South of the Sahara, Animals, Biodiversity, Cluster Analysis, Discriminant Analysis, Female, Gorilla gorilla classification, Gorilla gorilla genetics, Male, Gorilla gorilla anatomy & histology, Molar, Third anatomy & histology

Abstract

Gorilla patterns of variation have great relevance for studies of human evolution. In this study, molar morphometrics were used to evaluate patterns of geographic variation in gorillas. Dental specimens of 323 adult individuals, drawn from the current distribution of gorillas in equatorial Africa were divided into 14 populations. Discriminant analyses and Mahalanobis distances were used to study population structure. Results reveal that: 1) the West and East African gorillas form distinct clusters, 2) the Cross River gorillas are well separated from the rest of the western populations, 3) gorillas from the Virunga mountains and the Bwindi Forest can be differentiated from the lowland gorillas of Utu and Mwenga-Fizi, 4) the Tshiaberimu gorillas are distinct from other eastern gorillas, and the Kahuzi-Biega gorillas are affiliated with them. These findings provide support for a species distinction between Gorilla gorilla and Gorilla beringei, with subspecies G. g. diehli, G. g. gorilla, G. b. graueri, G. b. beringei, and possibly, G. b. rex-pygmaeorum. Clear correspondence between dental and other patterns of taxonomic diversity demonstrates that dental data reveal underlying genetic patterns of differentiation. Dental distances increased predictably with altitude but not with geographic distances, indicating that altitudinal segregation explains gorilla patterns of population divergence better than isolation-by-distance. The phylogeographic pattern of gorilla dental metric variation supports the idea that Plio-Pleistocene climatic fluctuations and local mountain building activity in Africa affected gorilla phylogeography. I propose that West Africa comprised the historic center of gorilla distribution and experienced drift-gene flow equilibrium, whereas Nigeria and East Africa were at the periphery, where climatic instability and altitudinal variation promoted drift and genetic differentiation. This understanding of gorilla population structure has implications for gorilla conservation, and for understanding the distribution of sympatric chimpanzees and Plio-Pleistocene hominins.

Published

2010

5. Identification of human specific gene duplications relative to other primates by array CGH and quantitative PCR.

Author

Armengol G, Knuutila S, Lozano JJ, Madrigal I, and Caballín MR

Subjects

Animals, Comparative Genomic Hybridization, Gorilla gorilla genetics, Humans, Oligonucleotide Array Sequence Analysis, Pan troglodytes genetics, Polymerase Chain Reaction, Pongo genetics, Species Specificity, Evolution, Molecular, Gene Duplication, Genes, Duplicate, Primates genetics

Abstract

In order to identify human lineage specific (HLS) copy number differences (CNDs) compared to other primates, we performed pair wise comparisons (human vs. chimpanzee, gorilla and orangutan) by using cDNA array comparative genomic hybridization (CGH). A set of 23 genes with HLS duplications were identified, as well as other lineage differences in gene copy number specific of chimpanzee, gorilla and orangutan. Each species has gained more copies of specific genes rather than losing gene copies. Eleven of the 23 genes have only been observed to have undergone HLS duplication in Fortna et al. (2004) and in the present study. Then, seven of these 11 genes were analyzed by quantitative PCR in chimpanzee, gorilla and orangutan, as well as in other six primate species (Hylobates lar, Cercopithecus aethiops, Papio hamadryas, Macaca mulatta, Lagothrix lagothricha, and Saimiri sciureus). Six genes confirmed array CGH data, and four of them appeared to have bona fide HLS duplications (ABCB10, E2F6, CDH12, and TDG genes). We propose that these gene duplications have a potential to contribute to specific human phenotypes., (Copyright 2010 Elsevier Inc. All rights reserved.)

Published

2010

6. Evolutionary history of chromosome 11 featuring four distinct centromere repositioning events in Catarrhini.

Author

Cardone MF, Lomiento M, Teti MG, Misceo D, Roberto R, Capozzi O, D'Addabbo P, Ventura M, Rocchi M, and Archidiacono N

Subjects

Animals, Cats, Cattle, Cell Line, Cell Line, Transformed, Gorilla gorilla genetics, Hominidae genetics, Humans, Hylobatidae genetics, Lemur genetics, Biological Evolution, Catarrhini genetics, Centromere genetics, Chromosomes, Human, Pair 11 genetics

Abstract

Panels of BAC clones used in FISH experiments allow a detailed definition of chromosomal marker arrangement and orientation during evolution. This approach has disclosed the centromere repositioning phenomenon, consisting in the activation of a novel, fully functional centromere in an ectopic location, concomitant with the inactivation of the old centromere. In this study, appropriate panels of BAC clones were used to track the chromosome 11 evolutionary history in primates and nonprimate boreoeutherian mammals. Chromosome 11 synteny was found to be highly conserved in both primate and boreoeutherian mammalian ancestors. Amazingly, we detected four centromere repositioning events in primates (in Old World monkeys, in gibbons, in orangutans, and in the Homo-Pan-Gorilla (H-P-G) clade ancestor), and one in Equidae. Both H-P-G and Lar gibbon novel centromeres were flanked by large duplicons with high sequence similarity. Outgroup species analysis revealed that this duplicon was absent in phylogenetically more distant primates. The chromosome 11 ancestral centromere was probably located near the HSA11q telomere. The domain of this inactivated centromere, in humans, is almost devoid of segmental duplications. An inversion occurred in chromosome 11 in the common ancestor of H-P-G. A large duplicon, again absent in outgroup species, was found located adjacent to the inversion breakpoints. In Hominoidea, almost all the five largest duplicons of this chromosome appeared involved in significant evolutionary architectural changes.

Published

2007

7. Distinguishing gorilla mitochondrial sequences from nuclear integrations and PCR recombinants: guidelines for their diagnosis in complex sequence databases.

Author

Anthony NM, Clifford SL, Bawe-Johnson M, Abernethy KA, Bruford MW, and Wickings EJ

Subjects

Animals, Base Sequence, Phylogeny, Polymerase Chain Reaction, Sequence Analysis, DNA, Cell Nucleus genetics, DNA, Mitochondrial, Databases, Nucleic Acid, Gorilla gorilla genetics, Recombination, Genetic

Abstract

Nuclear integrations of mitochondrial DNA (Numts) are widespread in many taxa and if left undetected can confound phylogeny interpretation and bias estimates of mitochondrial DNA (mtDNA) diversity. This is particularly true in gorillas, where recent studies suggest multiple integrations of the first hypervariable (HV1) domain of the mitochondrial control region. Problems can also arise through the inadvertent incorporation of artifacts produced by in vitro recombination between sequence types during polymerase chain reaction amplification. This issue has attracted little attention yet could potentially exacerbate errors in databases already contaminated by Numts. Using a set of existing diagnostic tools, this study set out to systematically inventory Numts and PCR recombinants in a gorilla HV1 sequence database and address the degree to which existing public databases are contaminated. Phylogenetic analysis revealed three distinct gorilla HV1 Numt groups (I, II, and III) that could be readily differentiated from mtDNA sequences by Numt-specific diagnostic sites and sequence-based motifs. Several instances of genuine recombination were also identified by a suite of detection methods. The location of putative breakpoints was identified by eye and by likelihood analysis. Findings from this study reveal widespread nuclear contamination of gorilla HV1 GenBank databases and underline the importance of recognizing not only Numts but also PCR recombinant artifacts as potential sources of data contamination. Guidelines for the routine identification of Numts and in vitro recombinants are presented and should prove useful in the detection of similar artifacts in other species mtDNA databases.

Published

2007

8. Construction of a gorilla fosmid library and its PCR screening system.

Author

Kim CG, Fujiyama A, and Saitou N

Subjects

Animals, Female, Multigene Family, Cosmids, Genomic Library, Gorilla gorilla genetics, Polymerase Chain Reaction methods

Abstract

A gorilla fosmid library of 261,120 independent clones was constructed and characterized. The fosmid vector is similar to the cosmid in average insert size of ca. 40 kb but contains the F factor for replication, and it is more resistant to recombination. This clone library represents about 3.7 times coverage of the gorilla genome. A simple screening system by PCR was established, and we successfully found 9 clones that cover the entire Hox A gene cluster of the gorilla genome. This gorilla fosmid DNA library is a useful resource for comparative genomics of human and apes.

Published

2003

9. The place of Neandertals in the evolution of hominid patterns of growth and development.

Author

Thompson JL and Nelson AJ

Subjects

Adolescent, Africa, Animals, Child, Child, Preschool, Europe, Female, Gorilla gorilla genetics, Gorilla gorilla growth & development, Hominidae genetics, Humans, Infant, Male, Paleodontology, Paleontology, Biological Evolution, Bone and Bones anatomy & histology, Hominidae growth & development

Abstract

This study uses the two developmental fields of dental maturation and femoral growth to determine if the pattern of growth and development in Neandertals (archaic Homo sapiens) was intermediate between that of Homo erectus and recent modern humans. Specimens used in the analysis included Neandertals and Upper Palaeolithic early modern Homo sapiens from Europe and individuals from two recent modern human populations. Ontogenetic data for the H. erectus adolescent KNM-WT 15000 and for Gorilla gorilla were included for comparison. Previous reports have indicated that H. erectus demonstrates a pattern of ontogeny characterized by earlier and more rapid linear growth than in modern humans. Results reported here demonstrate that Upper Paleolithic early modern Homo sapiens display a growth trajectory indistinguishable from that of recent modern humans. The pattern of Neandertal ontogeny is not intermediate between the pattern displayed in H. erectus and the derived pattern seen in the modern reference samples and the early modern H. sapiens sample. The Neandertal growth trajectory is consistent with either slow linear growth or advanced dental development., (Copyright 2000 Academic Press.)

Published

2000

10. Molecular cytogenetic resources for chromosome 4 and comparative analysis of phylogenetic chromosome IV in great apes.

Author

Marzella R, Viggiano L, Miolla V, Storlazzi CT, Ricco A, Gentile E, Roberto R, Surace C, Fratello A, Mancini M, Archidiacono N, and Rocchi M

Subjects

Animals, Centromere ultrastructure, Chromosome Inversion, Chromosome Painting, Chromosomes, Artificial, Yeast, Evolution, Molecular, Genetic Markers, Humans, Hybrid Cells, Macaca mulatta genetics, Sequence Tagged Sites, Species Specificity, Chromosomes genetics, Chromosomes, Human, Pair 4 genetics, Gorilla gorilla genetics, Pan troglodytes genetics, Phylogeny, Pongo pygmaeus genetics

Abstract

We have generated a panel of 55 somatic cell hybrids retaining fragments of human chromosome 4. Each hybrid has been characterized cytogenetically by FISH and molecularly by 37 STSs, evenly spaced along the chromosome. The panel can be exploited to map subregionally DNA sequences on chromosome 4 and to generate partial chromosome paints useful in the characterization of chromosomal rearrangements involving this chromosome. Furthermore, a panel of 84 YACs mapping on chromosome 4 has been characterized by FISH. A subset of this panel is recognized by STSs used in the somatic cell hybrid characterization. In this way a correlation between the genetic and the physical maps can be established. These resources have been used to investigate the conservation of the phylogenetic chromosome IV in great apes. The results indicate that all the pericentric inversions that differentiate chromosome IV in these species are distinct and that one of the breakpoints frequently lies very close to the centromere. In 4 instances, the YAC containing the breakpoint was identified. The breakpoint in IVq of PTR and MMU lies in the same YAC, suggesting that this breakpoint has been utilized twice in the evolutionary history of this chromosome., (Copyright 2000 Academic Press.)

Published

2000

11. DNA archives and our nearest relative: the trichotomy problem revisited.

Author

Satta Y, Klein J, and Takahata N

Subjects

Alleles, Animals, Computer Simulation, Databases, Factual, Globins genetics, Humans, Models, Biological, Muramidase genetics, Probability, Protamines genetics, Protein Precursors genetics, Repetitive Sequences, Amino Acid, Sequence Homology, Nucleic Acid, Gorilla gorilla genetics, Pan troglodytes genetics, Phylogeny

Abstract

Ever since Thomas H. Huxley correctly identified the chimpanzee and the gorilla as the two closest relatives of the human, the problem of the relationship among the three species ("the trichotomy problem") has remained unresolved. Comparative morphology and other classical methods of biological investigation have failed to answer definitively whether the chimpanzee or the gorilla is the closest relative of the human species. DNA sequences, both mitochondrial and nuclear, too, have provided equivocal solutions, depending on the region of the genome analyzed. Random sorting of ancestral allelic lineages, sequence convergence, and sequence exchanges between alleles or duplicated loci have been identified as likely factors confounding the interpretation of the interrelationships among the three species. In the present study most of these difficulties are overcome by identifying evolutionary causes that might potentially provide misleading information. Altogether, 45 loci consisting of 46, 855 bp are analyzed. About 60% of the loci and approximately the same proportion of phylogenetically informative sites support the human-chimpanzee clade. The remaining 40% of loci and sites support the two alternatives equally. It is demonstrated that, while incompatibility between loci can be explained by random sorting of allelic lineages, incompatibility within loci must be attributed largely to the joint effect of recombination and genetic drift. The trichotomy problem can be properly addressed only within this framework., (Copyright 2000 Academic Press.)

Published

2000

12. Evolution of a HOXB6 intergenic region within the great apes and humans.

Author

Deinard A and Kidd K

Subjects

Animals, Gorilla gorilla classification, Gorilla gorilla genetics, Hominidae classification, Humans, Multigene Family, Pan troglodytes classification, Pan troglodytes genetics, Polymerase Chain Reaction, Pongo pygmaeus classification, Pongo pygmaeus genetics, Evolution, Molecular, Genes, Homeobox, Homeodomain Proteins genetics, Hominidae genetics, Introns, Phylogeny

Abstract

Data accumulated over the past decade from several loci suggest that nonhuman primates have a greater amount of intraspecific genetic variation relative to humans. In phylogenetic reconstructions among primates that are based on genetic data, therefore, it becomes essential to adequately sample the population(s) being analyzed. Inadequate sampling may not only underestimate variation within any given population, but such an underestimate may confound any phylogenetic or population-specific conclusions implied by the data. Here we present inter- and intraspecific data on the molecular evolution of an approximately 1.0 kb intergenic HOXB6 sequence among humans, common chimpanzees, pygmy chimpanzees, gorillas and orangutans. To date, this study represents the most comprehensive investigation of a noncoding nuclear locus among the great apes and humans that examines the nature and amount of intraspecific variation in DNA sequences. Not only do these HOXB6 data continue to support earlier findings that Homo sapiens sapiens has less genetic variation than any great ape species (Ruano et al., 1992; Deinard & Kidd, 1995), but they strongly suggest that a high level of genetic polymorphism existed within the common ancestor of the African ape clade (Homo-Pan-Gorilla). Despite detecting two nucleotide substitutions linking Pan and Homo, we caution against concluding that the HOXB6 data definitively support a Homo-Pan clade to the exclusion of Gorilla. Rather, we believe that taking into consideration the level of genetic polymorphism that is likely to have existed within the common ancestor, the most prudent conclusion that can be made from all available data, including morphological, karyotypic and genetic data, may be that speciation among Homo-Pan-Gorilla is best represented by a "trichotomy"., (Copyright 1999 Academic Press.)

Published

1999

13. A long terminal repeat of the human endogenous retrovirus ERV-9 is located in the 5' boundary area of the human beta-globin locus control region.

Author

Long Q, Bengra C, Li C, Kutlar F, and Tuan D

Subjects

Animals, Base Sequence, Chloramphenicol O-Acetyltransferase genetics, Chloramphenicol O-Acetyltransferase metabolism, Conserved Sequence, Enhancer Elements, Genetic, Gorilla gorilla genetics, Humans, Molecular Sequence Data, Promoter Regions, Genetic, Racial Groups genetics, Recombinant Proteins genetics, Recombinant Proteins metabolism, Retroelements, Reverse Transcriptase Polymerase Chain Reaction, Sequence Analysis, DNA, Transcription, Genetic, Endogenous Retroviruses genetics, Erythrocytes physiology, Globins genetics, Terminal Repeat Sequences genetics

Abstract

Transcription of the human beta-like globin genes in erythroid cells is regulated by the far-upstream locus control region (LCR). In an attempt to define the 5' border of the LCR, we have cloned and sequenced 5 kb of new upstream DNA. We found an LTR retrotransposon belonging to the ERV-9 family of human endogenous retroviruses in the apparent 5' boundary area of the LCR. This ERV-9 LTR contains an unusual U3 enhancer region composed of 14 tandem repeats with recurrent GATA, CACCC, and CCAAT motifs. This LTR is conserved in human and gorilla, indicating its evolutionary stability in the genomes of the higher primates. In both recombinant constructs and the endogenous human genome, the LTR enhancer and promoter activate the transcription of cis-linked DNA preferentially in erythroid cells. Our findings suggest the possibility that this LTR retrotransposon may serve a relevant host function in regulating the transcription of the beta-globin LCR., (Copyright 1998 Academic Press.)

Published

1998

14. Molecular definition of pericentric inversion breakpoints occurring during the evolution of humans and chimpanzees.

Author

Nickerson E and Nelson DL

Subjects

Animals, Chromosome Banding, Chromosome Breakage, Chromosomes, Artificial, Yeast, Chromosomes, Human, Pair 12, Chromosomes, Human, Pair 4, Chromosomes, Human, Pair 9, Gorilla gorilla genetics, Humans, In Situ Hybridization, Fluorescence, Karyotyping, Pongo pygmaeus genetics, Chromosome Inversion, Chromosome Mapping, Evolution, Molecular, Hominidae genetics, Pan troglodytes genetics

Abstract

High-resolution G-banding analysis has demonstrated remarkable morphological conservation of the chromosomes of the Hominidae family members (humans, chimpanzees, gorillas, and orangutans), with the most notable differences between the genomes appearing as changes in heterochromatin distribution and pericentric inversions. Pericentric inversions may have been important for the establishment of reproductive isolation and speciation of the hominoids as they diverged from a common ancestor. Here the previously published primate karyotype comparisons, coupled with the resources of the Human Genome Project, have been used to identify pericentric inversion breakpoints seen when comparing the human karyotype to that of chimpanzee. Yeast artificial chromosome (YAC) clones were used to detect, by fluorescence in situ hybridization, five evolutionary pericentric inversion breakpoints present on the chimpanzee chromosome equivalents of human chromosomes 4, 9, and 12. In addition, two YACs from human 12p that detect a breakpoint in chimpanzee detect a similar rearrangement in gorilla.

Published

1998

15. Variation in tooth morphology of Gorilla gorilla.

Author

Uchida A

Subjects

Animals, Dentition, Female, Gorilla gorilla genetics, Male, Sex Characteristics, Species Specificity, Gorilla gorilla anatomy & histology, Tooth anatomy & histology

Abstract

Gorilla gorilla exemplifies a species that shows considerable variation in habitat, behaviour, genetic structure and morphology. This study examines variation of dental morphology in gorillas. Despite the marked size dimorphism, there are no significant shape differences between the sexes within subspecies. Differences in dental morphology, including tooth cusp proportions between the western G. g. gorilla and the eastern G. g. beringei are considerable. Although more similar to G. g. beringei than to the western G. g. gorilla, G. g. graueri also shows distinct morphological features. This indicates that the morphology of G. g. graueri is not merely intermediate, and genetic isolation between the two eastern subspecies could have had a substantial influence. Such extensive variation in dental morphology in Gorilla gorilla can be considered to be the result of an interesting combination of factors, including local dietary adaptations.

Published

1998

16. Structural organization of multiple alphoid subsets coexisting on human chromosomes 1, 4, 5, 7, 9, 15, 18, and 19.

Author

Finelli P, Antonacci R, Marzella R, Lonoce A, Archidiacono N, and Rocchi M

Subjects

Animals, Chromatin ultrastructure, Chromosomes, Human, Pair 1 genetics, Chromosomes, Human, Pair 15 genetics, Chromosomes, Human, Pair 18 genetics, Chromosomes, Human, Pair 19 genetics, Chromosomes, Human, Pair 4 genetics, Chromosomes, Human, Pair 5 genetics, Chromosomes, Human, Pair 7 genetics, Chromosomes, Human, Pair 9 genetics, DNA Probes, Gorilla gorilla genetics, Humans, In Situ Hybridization, Interphase, Metaphase, Pan troglodytes genetics, Chromosome Mapping, Chromosomes, Human genetics, DNA, Satellite genetics

Abstract

FISH experiments on metaphase chromosomes, interphase nuclei, and extended chromatin were performed to investigate the structural organization of alphoid subsets coexisting on human chromosomes 1, 4, 5, 7, 9, 15, 18, and 19. Results indicate that multiple subsets present on chromosomes 5, 7, 15, 18, and 19 are organized in structurally distinct and contiguous domains, while those on chromosomes 4 and 9 give perfectly overlapping signals. Chromosome 1 shows a peculiar organization: probe pAL1, specific for this chromosome, detects two distinct domains separated by the subset identified by probe pZ5.1. The order along the chromosome of alphoid subsets lying on chromosomes 5, 7, 15, 18, and 19, organized in distinct blocks, has also been established. The relationship between the structural organization of these alphoid sequences and their evolutionary history in great apes is discussed.

Published

1996

17. Mitochondrial DNA diversity in gorillas.

Author

Garner KJ and Ryder OA

Subjects

Animals, Base Sequence, Humans, Molecular Sequence Data, Phylogeny, Sequence Homology, Nucleic Acid, Species Specificity, DNA, Mitochondrial genetics, Genetic Variation, Gorilla gorilla genetics

Abstract

A highly variable portion of the mitochondrial DNA control region was sequenced in 63 free-living and captive gorillas including representatives of the three recognized subspecies. This region has proven useful for evaluation of relative levels of genetic variability in populations, for clarification of the subspecies identity of a wild population, and for examination of the phylogenetic relationships of the three subspecies. The eastern lowland (Gorilla gorilla graueri) and mountain gorilla (Gorilla gorilla beringei) sequences are distinct but closely related, with low variability within each subspecies. Two currently isolated populations of mountain gorillas, one in the Virungas Volcanoes region and the other in the Bwindi Forest, are indistinguishable using this mitochondrial DNA region for comparison. The subspecies identity of the Bwindi Forest group has previously been debated. Mitochondrial D-loop DNA variability within the western lowland gorillas (Gorilla gorilla gorilla) is very high. The genetic distance between the most divergent gorilla sequences is approximately as great as the distance between sequences of chimpanzees (Pan troglodytes) and bonobos (Pan paniscus).

Published

1996

18. The ZNF75 zinc finger gene subfamily: isolation and mapping of the four members in humans and great apes.

Author

Villa A, Strina D, Frattini A, Faranda S, Macchi P, Finelli P, Bozzi F, Susani L, Archidiacono N, Rocchi M, and Vezzoni P

Subjects

Amino Acid Sequence, Animals, Base Sequence, Cattle, Chromosome Mapping, Conserved Sequence, DNA Primers, DNA-Binding Proteins biosynthesis, Gorilla gorilla genetics, Horses, Humans, Kruppel-Like Transcription Factors, Male, Mammals, Mice, Molecular Sequence Data, Pan troglodytes genetics, Polymerase Chain Reaction, Pseudogenes, Sequence Homology, Amino Acid, Sequence Homology, Nucleic Acid, Transcription Factors biosynthesis, Chromosomes, Human, Pair 12, Chromosomes, Human, Pair 16, Chromosomes, Human, Pair 17, DNA-Binding Proteins genetics, Multigene Family, Pongo pygmaeus genetics, Transcription Factors genetics, Zinc Fingers genetics

Abstract

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.

Published

1996

19. Divergence time and population size in the lineage leading to modern humans.

Author

Takahata N, Satta Y, and Klein J

Subjects

Animals, Base Sequence, Gene Frequency, Gorilla gorilla genetics, Humans, Likelihood Functions, Models, Genetic, Pan troglodytes genetics, Phylogeny, Predictive Value of Tests, Species Specificity, Time Factors, Evolution, Molecular, Genetics, Population, Hominidae genetics, Population Density

Abstract

We have developed maximum likelihood (ML) methods for comparisons of nucleotide sequences from unlinked genomic regions. In the case of a single species, the ML method primarily estimates the effective population size (Ne) under both constant size and abrupt expansion conditions. In the case of two or three species, the ML method simultaneously estimates the species divergence time and the effective size of ancestral populations. This allows us to trace the evolutionary history of the human population over the past several million years (my). Available sequences at human autosomal loci indicate Ne = 10,000 in the Late Pleistocene, a figure concordant with the results obtained from mitochondrial DNA sequence and allele-frequency data analysis, and there is no indication of population expansion. The ML analysis of two species shows that humans diverged from chimpanzees 4.6 my ago and that the human and chimpanzee clade diverged from the gorilla 7.2 my ago. Furthermore, the effective population size of humans more than 4.6 my ago is nearly 10 times larger than Ne of modern humans. The effective population size in the human lineage does not seem to have remained constant over the past several million years. The ML model for three species predicts slightly different, but consistent results to those obtained by the two-species analysis.

Published

1995

20. Alu repeats: a source for the genesis of primate microsatellites.

Author

Arcot SS, Wang Z, Weber JL, Deininger PL, and Batzer MA

Subjects

Animals, Base Sequence, Cell Line, DNA Primers, Gorilla gorilla genetics, Hominidae genetics, Humans, Hylobates genetics, Molecular Sequence Data, Pan troglodytes genetics, Polymerase Chain Reaction methods, Pongo pygmaeus genetics, Sequence Homology, Nucleic Acid, Chromosome Mapping, DNA, Satellite genetics, Primates genetics, Repetitive Sequences, Nucleic Acid

Abstract

As a result of their abundance, relatively uniform distribution, and high degree of polymorphism, microsatellites and minisatellites have become valuable tools in genetic mapping, forensic identity testing, and population studies. In recent years, a number of microsatellite repeats have been found to be associated with Alu interspersed repeated DNA elements. The association of an Alu element with a microsatellite repeat could result from the integration of an Alu element within a preexisting microsatellite repeat. Alternatively, Alu elements could have a direct role in the origin of microsatellite repeats. Errors introduced during reverse transcription of the primary transcript derived from an Alu "master" gene or the accumulation of random mutations in the middle A-rich regions and oligo(dA)-rich tails of Alu elements after insertion and subsequent expansion and contraction of these sequences could result in the genesis of a microsatellite repeat. We have tested these hypotheses by a direct evolutionary comparison of the sequences of some recent Alu elements that are found only in humans and are absent from nonhuman primates, as well as some older Alu elements that are present at orthologous positions in a number of nonhuman primates. The origin of "young" Alu insertions, absence of sequences that resemble microsatellite repeats at the orthologous loci in chimpanzees, and the gradual expansion of microsatellite repeats in some old Alu repeats at orthologous positions within the genomes of a number of nonhuman primates suggest that Alu elements are a source for the genesis of primate microsatellite repeats.

Published

1995

21. Hominoid phylogeny estimated by model selection using goodness of fit significance tests.

Author

Czelusniak J and Goodman M

Subjects

Animals, Base Sequence, Gorilla gorilla genetics, Humans, Hylobates genetics, Models, Statistical, Molecular Sequence Data, Pan troglodytes genetics, Pongo pygmaeus genetics, Probability, Sequence Homology, Nucleic Acid, Stochastic Processes, Biological Evolution, Haplorhini genetics, Hemoglobins genetics, Hominidae genetics, Models, Genetic, Phylogeny, Primates genetics

Abstract

Phylogeny estimation from nucleotide sequence data may be thought of as a problem of choosing between different evolutionary models that vary with the branching pattern of the phylogeny and with the stochastic process of nucleotide sequence change occurring on the branches of the phylogenetic tree. Thus, each evolutionary model consists of both a particular stochastic process and a particular phylogeny. Such models produce multinomial distributions of nucleotide character patterns. As first suggested by Cavalli-Sforza and Edwards [Evolution 21: 550-570 (1967)] the distribution of patterns expected under each model can be compared to the actual observed distribution of patterns by a goodness of fit statistic such as the loglikelihood ratio G2 or Pearson's X2 after the numerical parameters for the model have been chosen to minimize the respective statistic. For each evolutionary model, the probability P of getting a value of the goodness of fit statistic greater than the observed value is computed. A very small P value means that either a rare event has occurred or that the model is false. Employing for each of 16 models a stochastic process which has 12 parameters to describe the mode of nucleotide change on each branch of each putative phylogenetic tree, we examined all 15 unrooted dichotomously branching arrangements of orthologous noncoding sequences from the gamma hemoglobin genomic region of the five hominoids (gibbon, orangutan, gorilla, chimpanzee, and human) plus the branching arrangement with a trichotomous separation of gorilla, chimpanzee, and human. Of these 16 models, all had P values less than 0.01, except for the arrangement of human joined by chimpanzee, in turn joined by gorilla, and then orangutan and gibbon. This analysis allows convincing claims to be made about hominoid phylogenetic relationships by testing the applicability of the assumed stochastic process for nucleotide sequence evolution at the same time as testing the inferred phylogenetic branching arrangement.

Published

1995

22. Comparative mapping of human alphoid sequences in great apes using fluorescence in situ hybridization.

Author

Archidiacono N, Antonacci R, Marzella R, Finelli P, Lonoce A, and Rocchi M

Subjects

Animals, Cell Line, Chromosome Mapping, Gorilla gorilla genetics, Humans, Image Processing, Computer-Assisted, In Situ Hybridization, Fluorescence, Male, Pan troglodytes genetics, Species Specificity, Centromere genetics, DNA, Satellite genetics, Hominidae genetics, Phylogeny, Repetitive Sequences, Nucleic Acid

Abstract

Twenty-seven human alphoid DNA probes have been hybridized in situ to metaphase spreads of the common chimpanzee (PTR), the pigmy chimpanzee (PPA), and the gorilla (GGO) to investigate the evolutionary relationship between the centromeric regions of the great ape chromosomes. The surprising results showed that the vast majority of the probes did not recognize their corresponding homologous chromosomes. Alphoid sequences belonging to the suprachromosomal family 1 (chromosomes 1, 3, 5, 6, 7, 10, 12, 16, and 19) yielded very heterogeneous results: some probes gave intense signals, but always on nonhomologous chromosomes; others did not produce any hybridization signal. Almost all probes belonging to the suprachromosomal family 2 (chromosomes 2, 4, 8, 9, 13, 14, 15, 18, 20, 21, and 22) recognized a single chromosome: chromosome 11 (phylogenetic IX) in PTR and PPA and chromosome 19 (phylogenetic V) in GGO. Localization of probes of suprachromosomal family 3 (chromosomes 1, 11, 17, and X) was found to be substantially conserved in PTR and PPA, but not in GGO. Probe pDMX1, specific for the human X chromosome, was the only sequence detecting its corresponding chromosome in all three species. PPA chromosomes I, IIp, IIq, IV, V, VI, and XVIII were never labeled, even under low-stringency hybridization conditions, by the 27 alphoid probes used in this study. These results, with particular reference to differences found in the two related species PTR and PPA, suggest that alphoid centromeric sequences underwent a very rapid evolution.

Published

1995

23. Relative size and evolution of the germline repertoire of T-cell receptor beta-chain gene segments in nonhuman primates.

Author

Charmley P, Keretan E, Snyder K, Clark EA, and Concannon P

Subjects

Animals, Base Sequence, Blotting, Southern, Chromosome Mapping, Chromosomes, Human, Pair 7, Chromosomes, Human, Pair 9, DNA Probes, DNA Restriction Enzymes, Female, Gorilla gorilla genetics, Hominidae genetics, Humans, Introns, Macaca genetics, Macaca nemestrina genetics, Male, Molecular Sequence Data, Multigene Family, Polymerase Chain Reaction, Polymorphism, Restriction Fragment Length, Pongo pygmaeus genetics, Restriction Mapping, Sequence Homology, Nucleic Acid, T-Lymphocytes immunology, Biological Evolution, Primates genetics, Receptors, Antigen, T-Cell, alpha-beta genetics

Abstract

The mammalian T-cell receptor (TCR) gene complexes exist as multiple tandemly arrayed gene segments that have apparently arisen by gene duplication mechanisms. A study of the number of TCR germline gene segments in several primate species might provide insight into the relative rate and patterns of gene duplication and deletion within these gene complexes. DNA probes from the TCR beta-chain variable (TCRBV) region gene segment subfamilies 1 through 25 and the constant region gene segment were sequentially hybridized under low stringency to Southern blots containing genomic DNA of human, gorilla, orangutan, and pig-tailed macaque. The number of gene members in each subfamily was estimated from the number of hybridizing DNA fragments. The results show apparent examples of both TCRB V gene duplication and deletion since speciation of the Hominoids from Cercopithecoid (Old World) primates. For one putative duplication/deletion event involving six TCRBV gene segments, derivation and comparison of germline DNA sequence from macaque and human as well as Southern blot analysis of additional primates demonstrated that this event was a duplication that occurred after the divergence of the family Pongidae (Greater Apes) from Hylobatidae (Lesser Apes). Southern blot analysis of multiple pig-tailed macaques and their offspring suggests a degree of DNA sequence variability in these gene segments similar to that observed in humans. An appreciation of the size and variability of each TCRBV subfamily will be useful when considering the DNA primers and probes necessary to measure the relative usage of these TCRBV genes as part of the immune response in these nonhuman primates.

Published

1995

24. Differences in hypervariability within the retinoblastoma gene in the great apes.

Author

Chidambaram A, Law JC, and Ferrell RE

Subjects

Animals, Base Sequence, Blotting, Southern, DNA, Genetic Variation, Humans, Introns, Molecular Sequence Data, Polymerase Chain Reaction, Recombination, Genetic, Repetitive Sequences, Nucleic Acid, Genes, Retinoblastoma, Gorilla gorilla genetics, Pan troglodytes genetics, Pongo pygmaeus genetics

Published

1992

25. Comparative anatomy of the primate major histocompatibility complex DR subregion: evidence for combinations of DRB genes conserved across species.

Author

Kasahara M, Klein D, Vincek V, Sarapata DE, and Klein J

Subjects

Animals, Base Sequence, Biological Evolution, Cell Line, Cosmids, DNA, Haplotypes, Humans, Molecular Sequence Data, Multigene Family, Phylogeny, Restriction Mapping, Species Specificity, Gorilla gorilla genetics, HLA-DR Antigens genetics

Abstract

The class II region of the human major histocompatibility complex (HLA) is made up of three major subregions designated DR, DQ, and DP. With the aim of gaining an insight into the evolution and stability of DR haplotypes, a total of 63 cosmid clones were isolated from the DR subregion (Gogo-DR) of a western lowland gorilla. All but one of these cosmid clones were found to fall into two clusters. The larger cluster, A, was defined by 41 overlapping cosmid clones and contained a DRB gene segment made up of exons 4 through 6 and four DRB genes, designated Gogo-DRB6, Gogo-DRB5*01, Gogo-DRB8, and Gogo-DRB3*01. The total length of this cluster was approximately 180 kb. The second cluster, B, encompassed a contiguous DNA stretch of approximately 145 kb and was composed of 21 overlapping cosmid clones. Cluster B contained three DRB genes, designated Gogo-DRB1*08, Gogo-DRB2, and Gogo-DRB3*02. One cosmid clone (WP1-9) containing a DRB pseudogene could not be linked to either cluster A or B. Neither the organization of cluster A nor that of cluster B was identical to that of known HLA-DR haplotypes. However, two gorilla DRB genes, Gogo-DRB6 and Gogo-DRB5*01, the human counterparts of which are linked in the HLA-DR2 haplotype, were found to be located next to each other in cluster A. The arrangement of the Gogo-DRB genes in cluster B, which is presumed to be the gorilla DR8 haplotype, was similar to that of HLA-DR3/DR5/DR6 haplotypes and to that of the presumed ancestral HLA-DR8 haplotype.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1992

26. A human moderately repeated Y-specific DNA sequence is evolutionarily conserved in the Y chromosome of the great apes.

Author

Guttenbach M, Müller U, and Schmid M

Subjects

Animals, Chromosome Banding, Female, Humans, Karyotyping, Male, Nucleic Acid Hybridization, Phylogeny, Sequence Homology, Nucleic Acid, Species Specificity, Genetic Markers, Gorilla gorilla genetics, Pan troglodytes genetics, Pongo pygmaeus genetics, Repetitive Sequences, Nucleic Acid, Y Chromosome

Abstract

Evolutionary conservation of the human-derived moderately repeated Y-specific DNA sequence Y-190 (DYZ5) was investigated in the chimpanzee, orangutan, and gorilla. Southern blot analysis showed the presence of the sequence in the Y chromosome of all great apes. Pulsed-field gel electrophoresis and in situ hybridization revealed that the repeat is organized in one major block and confined to a small region of the Y chromosome of the three species. DYZ5 was assigned to the proximal short arm of the Y chromosome of the chimpanzee and orangutan and to the long arm of the Y chromosome of the gorilla. In light of its evolutionary conservation, DYZ5 may have an as yet undetermined structural function in the Y chromosome.

Published

1992

27. Immunoglobulin CH gene family in hominoids and its evolutionary history.

Author

Kawamura S and Ueda S

Subjects

Animals, Base Sequence, Blotting, Southern, Genes, Immunoglobulin, Gorilla gorilla genetics, Haplorhini immunology, Humans, Hylobates genetics, Macaca fascicularis genetics, Molecular Sequence Data, Pan troglodytes genetics, Pongo pygmaeus genetics, Pseudogenes genetics, Biological Evolution, Haplorhini genetics, Immunoglobulin Constant Regions genetics, Immunoglobulin Heavy Chains genetics, Multigene Family genetics

Abstract

The organization of the human immunoglobulin CH gene suggests that a gene duplication involving the C gamma-C gamma-C epsilon-C alpha region has occurred during evolution. We previously showed that both chimpanzee and gorilla have two 5'-C epsilon-C alpha-3', as in human, and that orangutan, gibbon, and Old World monkeys have one C epsilon gene and one, two, and one C alpha gene(s), respectively. In addition to these clustered CH genes, there is one processed C epsilon pseudogene in each species. The present study revealed that orangutan and crab-eating macaque (an Old World monkey) both have one 5'-C epsilon-C alpha-3' and that gibbon has two 5'-C epsilon-C alpha-3', one C epsilon gene of which is completely deleted. By Southern analysis, the number of C gamma genes in all the nonhuman hominoids was estimated to be four to five, as in human, in comparison with two for crab-eating macaque. The C mu and C delta genes were estimated to be present as single copies in both hominoids and crab-eating macaque. Furthermore, it was proved that there are two copies of the C epsilon 5'-flanking region in both the orangutan and the gibbon genomes. These results show that gene duplication including the C gamma-C gamma-C epsilon-C alpha genes occurred in the common ancestor of hominoids and that subsequent deletion of the C epsilon gene (in orangutan, including one of the C alpha genes) occurred independently in each hominoid species.

Published

1992

28. Structure of the gorilla alpha-fetoprotein gene and the divergence of primates.

Author

Ryan SC, Zielinski R, and Dugaiczyk A

Subjects

Amino Acid Sequence, Animals, Base Sequence, Binding Sites, Exons, Genes, Humans, Molecular Sequence Data, Poly A, Promoter Regions, Genetic, Repetitive Sequences, Nucleic Acid, Restriction Mapping, Sequence Homology, Nucleic Acid, Genetic Variation, Gorilla gorilla genetics, alpha-Fetoproteins genetics

Abstract

The sequence of the gorilla alpha-fetoprotein gene, including 869 base pairs of the 5' flanking region and 4892 base pairs of the 3' flanking region (24,607 in total), was determined from two overlapping lambda phage clones. The sequence extends 18,846 base pairs from the Cap site to the polyadenylation site, and it reveals that the gene is composed of 15 exons, which are symmetrically placed within three domains of alpha-fetoprotein. The deduced polypeptide chain is composed of a 19-amino-acid leader peptide, followed by 590 amino acids of the mature protein. The RNA polymerase II binding site, TATAAAA, and the promoter element, CCAAC, are positioned at -21 and -65 from the Cap site, respectively. The polyadenylation signal, AATAAA, is located in the last exon, which is untranslated. The sequence for the gorilla alpha-fetoprotein gene was compared with that of the previously published human alpha-fetoprotein gene (P. E. M. Gibbs, R. Zielinski, C. Boyd, and A. Dugaiczyk, 1987, Biochemistry 26: 1332-1343). Four types of repetitive sequence elements were found in identical positions in both species. However, one Alu and one Xba DNA repeat within introns 4 and 7, respectively, of the human gene are absent from orthologous positions in the gorilla. The Alu and the Xba DNA repeats probably emerged in the human genome after the human/gorilla divergence and became established novelties in the human lineage. There are 363/21,523 mutational changes between human and gorilla, amounting to 1.69% DNA divergence between the two primate species. The value of 1.69% is lower than the 2.27% obtained from melting temperatures of hybrids between human and gorilla genomic DNA (C. G. Sibley and J. E. Ahlquist, 1984, J. Mol. Evol. 26: 99-121). At the protein level, Homo sapiens differs from Gorilla gorilla only at 4 of 609 amino acid positions (0.66%) in the alpha-fetoprotein sequence. This difference signifies a lower rate of molecular divergence for the alpha-fetoprotein gene in primates, as compared to rodents.

Published

1991