The R-C-E-F blood group system of chimpanzees: Serology and genetics

Six chimpanzee alloimmune antibodies define 20 phenotypes of the R-C-E-F blood group system, the counterpart of the human Rh system. Of the several specificities of this system, the R^c constitutes the crucial link with human Rh since the reactions of some chimpanzee alloimmune anti-R^c sera with human red cells parallel those obtained with human anti-Rh_o reagents. Reciprocally, properly absorbed human anti-Rh_o sera detect R^c specificity on chimpanzee red cells. Tests with large panels of human monoclonal anti-D antibodies confirm the notion of shared epitopes between human alloantigen Rh_o(D) and chimpanzee alloantigen R^c.     

Anti-human red cell monoclonal antibodies produced by macaque-mouse heterohybridomas: their reactivity with human and nonhuman primate erythrocytes.

Eighteen monoclonal antibodies (Mabs) against human red blood cells (RBCs) produced by macaque mouse heterobybridomas gave uniformly positive reactions with all human samples except for some with particular null phenotypes. Based on reactions with latter cells, the human antigenic targets of 11 antibodies could be identified: six were specific for glycophorin-related antigens (Wr(b), En(a), Ge4), and each of the live remaining antibodies showed one of the following specificities: CD55, CD44, CD59, Kell, and Rh proteins. Four Mabs recognized the Vc antigen of the chimpanzee V-A-B-D system. Six macaque Mabs detected polymorphisms in chimpanzee, gorilla, orangutan, and gibbon that did not correspond to any known blood group in these animals, while other Mabs gave monomorphic reactions with ape RBCs. The reagents produced by macaque hybridomas are useful tools not only for human blood grouping tests, but also for tracing the relationships among blood group antigens of man and anthropoid apes.     

Sequence,evolution and ligand binding properties of mammalian Duffy antigen/receptor for chemokines

The Duffy antigen/receptor for chemokine, DARC, acts as a widely expressed promiscuous chemokine receptor and as the erythrocyte receptor for Plasmodium vivax. To gain insight into the evolution and structure/function relations of DARC, we analyzed the binding of anti-human Fy monoclonal antibodies (mAbs) and human chemokines to red blood cells (RBCs) from 11 nonhuman primates and two nonprimate mammals, and we elucidated the structures of the DARC genes from gorilla, gibbon, baboon, marmoset, tamarin, night monkey and cattle. CXCL-8 and CCL-5 chemokine binding analysis indicated that the promiscuous binding profile characteristic of DARC is conserved across species. Among three mAbs that detected the Fy6 epitope by flow cytometric analysis of human and chimpanzee RBCs, only one reacted with night monkey and squirrel monkey. Only chimpanzee RBCs bound a significant amount of the anti-Fy3 mAb. Fy3 was also poorly detected on RBCs from gorilla, baboon and rhesus monkey, but not from new world monkeys. Alignment of DARC homologous sequences allowed us to construct a phylogenetic tree in which all branchings were in accordance with current knowledge of primate phylogeny. Although DARC was expected to be under strong internal and external selection pressure, in order to maintain chemokine binding and avoid Plasmodium vivax binding, respectively, our present study did not provide arguments in favor of a selection pressure on the extracellular domains involved in ligand specificity. The amino acid variability of DARC-like polypeptides was found to be well correlated with the hydrophylicity indexes, with the highest divergence on the amino-terminal extracellular domain. Analysis of the deduced amino acid sequences highlighted the conservation of some amino acid residues, which should prove to be critical for the structural and functional properties of DARC.     

Lineage-Specific Homogenization of the Polyubiquitin Gene Among Human and Great Apes

Ubiquitin is a highly conserved protein, and is encoded by a multigene family among eukaryote species. The polyubiquitin genes, UbB and UbC, comprise tandem multiple ubiquitin coding units without a spacer region or intron. We determined nucleotide sequences for the UbB and UbC of human, chimpanzee, gorilla, and orangutan. The ubiquitin repeat number of UbB was constant (3) in human and great apes, while that of UbC varied: 6 to 11 for human, 10 to 12 for chimpanzee, 8 for gorilla, and 10 for orangutan. The heterogeneity of the repeat number within closely related hominoid species suggests that a lineage-specific unequal crossover and/or gene duplication occurred. A marked homogenization of UbC occurred in gorilla with a low level of synonymous difference (p_s). The homogenization of UbC also occurred in chimpanzee and less strikingly in human. The first and last ubiquitin coding units of UbC were clustered independently between species, and less affected by homogenization during the hominoid evolution. Therefore, the homogenization of ubiquitin coding units is likely due to an unequal crossing-over inside the ubiquitin units. The lineage-specific homogenization of UbC among closely related species suggests that concerted evolution has a key role in the short-term evolution of UbC.     

A comparison of TSPY genes from Y-chromosomal DNA of the great apes and humans: Sequence,evolution, and phylogeny

The genes for testis-specific protein Y (TSPY) were sequenced from chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla), orangutan (Pongo pygmaeus), and baboon (Papio hamadryas). The sequences were compared with each other and with the published human sequence. Substitutions were detected at 144 of the 755 nucleotide positions compared. In overviewing five sequences, one deletion in human, four successive nucleotide insertions in orangutan, and seven deletions/insertions in baboon sequence were noted. The present sequences differed from that of human by 1.9% (chimpanzee), 4.0% (gorilla), 8.2% (orangutan), and 16.8% (baboon), respectively. The phylogenetic tree constructed by the neighbor-joining method suggests that human and chimpanzee are more closely related to each other than either of them is to gorilla, and this result is also supported by maximum likelihood and strict consensus maximum parsimony trees. The number of nucleotide substitutions per site between human and chimpanzee, gorilla, and orangutan for TSPY intron were 0.024, 0.048, and 0.094, respectively. The rates of nucleotide substitutions per site per year were higher in the TSPY intron than in the TSPY exon, and higher in the TSPY intron than in the ZFY (Zinc Finger Y) intron in human and apes. © 1996 Wiley-Liss, Inc.     

Examination of hominid evolution by DNA sequence homology

Hominoid phylogeny was investigated in terms of unique DNA sequence homologies. In comparisons from the human standpoint the ΔTe₅₀ DNA values were Man 0, chimpanzee 0·7, gorilla 1·4, gibbon 2·7, orangutan 2·9, and African green monkey 5·7. In comparisons from the orangutan standpoint the ΔTe₅₀ DNA values were orangutan 0, chimpanzee 1·8, Man 1·9, gorilla 2·3, gibbon 2·4 and African green monkey 4·3. These results indicate that chimpanzee and gorilla are cladistically closer to Man than to orangutan and other primates, and that gorilla DNA may have diverged slightly more from the ancestral state than chimpanzee or human DNA. Comparisons from chimpanzee and gorilla DNA standpoints are needed to achieve a more definitive picture of hominoid phylogeny.     

Comparative studies on an antigenicity of plasma proteins from humans and apes by ELISA: a close relationship of chimpanzee and human

1. Antigenic differences between human and ape plasma proteins were quantitatively investigated by enzyme-linked immunosorbent assay (ELISA) using antisera against human and chimpanzee plasmas. 2. With anti-human plasma serum, both the chimpanzee and gorilla were very close to the human, although the chimpanzee was slightly closer to the human than to the gorilla; relative immunological distance (relative ID) of the chimpanzee was 71, while that of the gorilla was 74. 3. With anti-chimpanzee plasma serum, the chimpanzee was found to be closely related to the human; relative ID of the chimpanzee was 58, while that of the gorilla was 75. 4. From these a molecular phylogeny for humans and apes was deduced; among living apes, the chimpanzee is the most closely related species to the human.     

Gorilla and orangutan c-myc nucleotide sequences: Inference on hominoid phylogeny

The nucleotide sequences of the gorilla and orangutan myc loci have been determined by the dideoxy nucleotide method. As previously observed in the human and chimpanzee sequences, an open reading frame (ORF) of 188 codons overlapping exon 1 could be deduced from the gorilla sequence. However, no such ORF appeared in the orangutan sequence.The two sequences were aligned with those of human and chimpanzee as hominoids and of gibbon and marmoset as outgroups of hominoids. The branching order in the evolution of primates was inferred from these data by different methods: maximum parsimony and neighborjoining.Our results support the view that the gorilla lineage branched off before the human and chimpanzee diverged and strengthen the hypothesis that chimpanzee and gorilla are more related to human than is orangutan. Correspondence to: F. Galibert     

Serum cholinesterase activities and inhibition profiles of nonhuman primates

Serum cholinesterase activities and inhibition profiles of 169 chimpanzees, 15 gorillas, 26 orangutans, seven gibbons, and 12 rhesus monkeys were determined. Mean values of activities against benzoylcholine (μmols/min/ml) and dibucaine, fluoride, and Ro 2-0683 numbers (percentage inhibition of benzoylcholine hydrolysis) are: chimpanzee, 2.276, 80, 64, and 97; gorilla, 9.403, 82, 71, and 96; orangutan, 0.747, 94, 6, and 98; gibbon, 0.071, 89, 7, and 94; and rhesus monkey, 0.859, 95, 10, and 99, respectively. Sernylan numbers were determined of the last 100 chimpanzee serums collected and of each of the gorilla, orangutan, gibbon, and rhesus monkey serums. Mean values of Sernylan numbers are: chimpanzee, 80; gorilla, 81; orangutan, 95; gibbon, 94; and rhesus monkey, 96. The chimpanzee and the gorilla have dibucaine, fluoride, Ro 2-0683, and Sernylan numbers within the range found in men who are homozygotes for the usual cholinesterase (genotype E₁^uE₁^u). No cholinesterase variant was found in any chimpanzee or gorilla. The orangutan, gibbon, and rhesus monkey have inhibition profiles that resemble one another, with higher dibucaine and Sernylan numbers and much lower fluoride numbers than the chimpanzee or the gorilla. The results of the inhibition tests suggest that the African apes, chimpanzee and gorilla, are related more closely to man than are the Asian apes, orangutan and gibbon.     

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

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.     

Molecular evolution of IgG subclass among nonhuman primates: implication of differences in antigenic determinants among Apes

The cross-reactivity of five different rabbit polyclonal antibodies to human IgG and IgG subclass (IgG1, IgG2, IgG3, and IgG4) was determined by competitive ELISA with nine nonhuman primate species including five apes, three Old World monkeys, and one New World monkey. As similar to those previously reported, the reactivity of anti-human IgG antibody with plasma from different primate species was closely related with phylogenic distance from human. Every anti-human IgG subclass antibody showed low cross-reactivity with plasma from Old World and New World monkeys. The plasma from all apes except for gibbons (Hylobates spp.) showed 60 to 100% of cross-reactivity with anti-human IgG2 and IgG3 antibodies. On the other hand, chimpanzee (Pan troglodytes andPan paniscus) and orangutan (Pongo pygmaeus) plasma showed 100% cross-reactivity with anti-human IgG1 antibody, but gorilla (Gorilla gorilla) and gibbon plasma showed no cross-reactivity. The chimpanzee and gorilla plasma cross-reacted with anti-human IgG4 antibody at different reactivity, 100% in chimpanzee and 50% in gorilla, but no cross-reactivity was observed in orangutan and gibbon plasma. These results suggest the possibilities that the divergence of “human-type” IgG subclasses might occur at the time of divergence ofHomo sapience fromHylobatidae, and that the molecular evolution of IgG1 as well as IgG4 is different from that of IgG2 and IgG3 in great apes, this is probably caused by different in development of immune function in apes during the course of evolution.     

Comparative study of urinary reproductive hormones in great apes

Urinary estrone conjugates (E₁C), pregnanediol-3-glucuronide (PdG), and follicle-stimulating hormone (FSH) were determined by enzyme immunoassays (EIAs) during the normal menstrual cycle in the orangutan, gorilla, chimpanzee, and bonobo. Furthermore, the data were compared to those levels in the human and long-tailed macaque. The results showed a typical preovulatory E₁C surge and postovulatory increase in PdG in all species. The pattern of E₁C during the menstrual cycle in the great apes more closely resembled the human than do the long-tailed macaque. A major difference of E₁C pattern between these species appeared in the luteal phase. In the great apes and the human, E₁C exhibited two peaks, the first peak detected at approximately mid cycle and the second peak detected during the luteal phase. On the other hand, in the long-tailed macaque, increase of E₁C in the luteal phase was small or nonexistent. The gorilla, chimpanzee, and bonobo exhibited similar PdG trends. The orangutan excreted one tenth less PdG than these species during the luteal phase. The long-tailed macaque also excreted low levels of PdG. The patterns of FSH in orangutan, chimpanzee, bonobo and long-tailed macaque showed a marked mid-cycle rise and an early follicular phase rise, similar to those in the human. Comparing similar taxa, a large difference was found in FSH of gorilla; there were three peaks during the menstrual cycle. Thus, there is considerable species variation in the excretion of these hormones during the menstrual cycle and comparative studies could be approached with a single method. The methods and baseline data presented here provide the basis for a practical approach to evaluation and monitoring of ovarian events in the female great apes. Electronic Publication     

Multiple recombinational events in primate immunoglobulin epsilon and alpha genes suggest closer relationship of humans to chimpanzees than to gorillas

Summary Immunoglobulin epsilon and alpha genes of chimpanzee and gorilla were isolated and their structures were compared with their human counterparts. Multiple deletions and duplications seem to have happened in both genes during hominoid evolution; the chimpanzee had deleted the entire C₂ gene after its divergence. In addition, the length of the C₁ hinge region of gorilla is distinct from those of chimpanzee and humans. Structural homology of the epsilon and alpha genes suggests that humans are evolutionarily closer to chimpanzees than to gorillas.     

Primary Immunization of Rh-negative Volunteers

To determine the best method for the production of high-titre anti-D serum primary immunization was carried out in two groups of Rh-negative male volunteers with washed group O R₂R₂ cells. The first group of six men were given 5 ml. of packed cells, and the second group of five men were given 0·5 ml. of packed cells, in each instance by intravenous injection. Only one individual in each group failed to develop anti-D following the primary inoculation, and it has been concluded that 0·5 ml. of packed R₂R₂ cells is probably a satisfactory dose for this purpose.There was a delay of several weeks before anti-D could be shown to have developed. The initial antibodies which appeared in the serum comprised 7S γG immunoglobulins, with, in about half the cases, a minor 19S γM component.     

Evolution of glycophorin A in the hominoid primates studied with monoclonal antibodies, and description of a sialoglycoprotein analogous to human glycophorin B in chimpanzee

Comparison of human and primate erythrocyte membrane sialoglycoproteins showed that common chimpanzee, dwarf chimpanzee, gorilla, orangutan, and gibbon have major periodic acid Schiff-positive proteins resembling human glycophorin A (GPA) monomer and dimer in electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gels. Immunoperoxidase staining of Western blots with monoclonal antibodies to human GPA showed that these primate bands express some GPA antigenic determinants. A new sialoglycoprotein analogous to human glycophorin B (GPB) was detected in common chimpanzee. Although human MN blood group phenotype results from an amino acid polymorphism of GPA, Western blots showed that in chimpanzee sialoglycoprotein (GPAch) always expresses the M blood group, whereas chimpanzee sialoglycoprotein (GPBch) expresses either the N blood group or a null phenotype. This result explains the detection of M and MN, but not of N, blood group phenotypes in chimpanzee. GPBch has higher apparent m.w. than human GPB, is present in the erythrocyte membrane in greater quantity than human GPB, and contains trypsin cleavage site(s) and the 10F7 determinant (both found on human GPA but not GPB). Expression of human GPA antigenic determinants was consistent with the phylogeny of the hominoid primates; common and dwarf chimpanzee expressed most of the determinants tested, gorilla and orangutan an intermediate number, and gibbon and siamang the least. Of the GPA antigenic determinants examined, the MN blood group determinants were most consistently expressed during evolution of the hominoid primates. The results suggested that variability in expression of GPA antigenic determinants between species was due to both differences in amino acid sequence and glycosylation.     

Conservation of intronic minisatellite polymorphisms in the SCK1/SHC2 gene of Hominidae

The neuronally expressed Shc adaptor homolog SCK1/SHC2 gene contains an unusually high number of minisatellites. In humans, twelve different minisatellite sequences are located in introns of SCK1/SHC2 and ten of them are highly polymorphic. Here we used primers developed for humans to screen ten intronic loci of SCK1/SHC2 in chimpanzee and gorilla, and undertook a comprehensive analysis of the genomic sequence to address the evolutionary events driving these variable repeats. All ten loci amplified in chimpanzee and gorilla contained hypervariable and low-variability minisatellites. The human polymorphic locus TR1 was monomorphic in chimpanzee and gorilla, but we detected polymorphic alleles in these apes for the human monomorphic TR7 locus. When we examined the repeat size among these hominoids, there was no consistent variation by length from humans to great apes. In spite of the inconsistent evolutionary dynamics in repeat length variation, exon 16 was highly conserved between humans and great apes. These results suggest that non-coding intronic minisatellites do not show a consistent evolutionary paradigm but evolved with different patterns among each minisatellite locus. These findings provide important insight for minisatellite conservation during hominoid evolution.     

Phylogenetic isolation of a human alu flounder gene: Drift to new subfamily identity

A severe bottleneck in the size of the PV Alu subfamily in the common ancestor of human and gorilla has been used to isolate an Alu source gene. The human PV Alu subfamily consists of about one thousand members which are absent in gorilla and chimpanzee DNA. Exhaustive library screening shows that there are as few as two PV Alus in the gorilla genome. One is gorilla-specific, i.e., absent in the orthologous loci in both human and chimpanzee, suggesting the independent retrotranspositional activity of the PV subfamily in the gorilla lineage. The second of these two gorilla PV Alus is present in both human and chimpanzee DNAs and is the single PV Alu known to precede the radiation of these three species. The orthologous Alu in gibbon DNA resembles the next older Alu subfamily. Thus, this Alu locus is originally templated by a non-PV source gene and acquired characteristic PV sequence variants by mutational drift in situ, consequently becoming the first member and presumptive founder of this PV subfamily. Correspondence to: C.W. Schmid     

Gorilla society: What we know and don't know

Science is fairly certain that the gorilla lineage separated from the remainder of the hominoid clade about eight million years ago, 2 , 4 and that the chimpanzee lineage and hominin clade did so about a million years after that. 1 , 2 However, just this year, 2007, it was discovered that although the human head louse separated from the congeneric chimpanzee body louse (Pediculus) around the same time as the chimpanzee and hominin lineages split, 3 the human pubic louse apparently split from its sister species, the congeneric gorilla louse, Pthirus, 4.5 million years after their host lineages split. 3 No tested explanations exist for the discrepancy. Much is known about hominin evolution, but much remains to be discovered. The same is true of primate socioecology in general and gorilla socioecology in particular.     

Gorilla RH-like genes and antigens

 It has been previously shown that most of the human IgG monoclonal D-specific antibodies define a polymorphism in the gorilla consisting of two phenotypes: D^gor-positive and D^gor-negative. By quantitative indirect immunofluorescence assay and quantitative immunoblotting it was evaluated that the number of D^gor antigenic sites per gorilla red cell varies from a level equivalent to that observed for human RhD-positive cells to a level eight times higher. By immunoblotting with a rabbit reagent specific for the carboxylic end of human Rh-polypeptides it was demonstrated that RBCs from all gorillas, whatever their D^gor phenotype, possess 33000 relative molecular mass Rh-like polypeptides. The expression of the D^gor antigen was shown to be associated with the presence of three polymorphic bands defined by Southern blot using a human exon 4 RHCE probe, and to a length polymorphism of gorilla intron 3 evidenced by polymerase chain reaction. By contrast, the expression of the D^gor antigen was not associated to the length polymorphism of gorilla intron 4 which is related to the presence or absence of an Alu-Sx element in intron 4, paralleling the situation observed in human. These results confirmed the presence in the gorilla genome of at least two RH-like genes, one of which being responsible for D^gor polymorphism. The phylogenesis of the human and gorilla RH genes is discussed in light of the comparison of intron 4 sequences. Received: 23 March 1998 / Revised: 18 June 1998