The phylogeny of the hominoid primates, as indicated by DNA-DNA hybridization

The spider monkey psi eta-globin gene and surrounding sequences: recent or ancient insertions of LINEs and SINEs?

A phylogenetic comparison of the psi eta-globin DNA sequence of the spider monkey (Ateles geoffroyi) to orthologous sequences from other primates provides evidence for an evolutionarily recent (less than 17 million years ago (MYA] insertion of a truncated L1 LINE (long interspersed repetitive element). An Alu SINE (short interspersed element), found 3 kb downstream of the poly(A) addition site, arose less than 40 MYA subsequent to the divergence of platyrrhinies (New World monkeys) from catarrhines (humans, apes, and Old World monkeys). Another Alu element, which appears in the catarrhines 588 bp upstream from the psi eta gene, is absent in Ateles, thus placing its possible time of insertion between 20 and 40 MYA. Alignment of the Ateles psi eta sequence with orthologous hominoid sequences (M. M. Miyamoto, J. L. Slightom, and M. Goodman, 1987, Science 238: 369-373) provides unequivocal evidence against the view (J. H. Schwartz, 1987, "The Red Ape: Orang-utans and Human Origins," Houghton Mifflin, Boston, MA) that the orangutan forms a monophyletic group with human. Furthermore, a critical analysis of potential sources of homoplasy (i.e., parallel evolution) reaffirms a Homo-Pan monophyletic clade (Miyamoto et al., 1987). Reconstruction of primate psi eta sequence phylogeny suggests Ateles and Aotus shared a common ancestor only 16 +/- 1.5 MYA. Finally, the results show a mutation rate of 1.7 +/- 0.2 x 10(-9) mutations site-1 year-1 during the evolution of the Ateles psi eta-globin region since the divergence of catarrhines from platyrrhinies.(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular systematics of higher primates: genealogical relations and classification

We obtained 5' and 3' flanking sequences (5.4 kilobase pairs) from the psi eta-globin gene region of the rhesus macaque (Macaca mulatta) and combined them with available nucleotide data. The completed sequence, representing 10.8 kilobase pairs of contiguous noncoding DNA, was compared to the same orthologous regions available for human (Homo sapiens, as represented by five different alleles), common chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla), and orangutan (Pongo pygmaeus). The nucleotide sequence for Macaca mulatta provided the outgroup perspective needed to evaluate better the relationships of humans and great apes. Pairwise comparisons and parsimony analysis of these orthologues clearly demonstrated (i) that humans and great apes share a high degree of genetic similarity and (ii) that humans, chimpanzees, and gorillas form a natural monophyletic group. These conclusions strongly favor a genealogical classification for higher primates consisting of a single family (Hominidae) with two subfamilies (Homininae for Homo, Pan, and Gorilla and Ponginae for Pongo).

HLA-A and B polymorphisms predate the divergence of humans and chimpanzees

Major histocompatibility complex (MHC) glycoproteins bind processed fragments of proteins and present them to the receptors of T lymphocytes. The extraordinary polymorphism of class I MHC molecules in man (HLA-A, B and C) and mouse (H-2 K, D and L) poses many questions concerning their diversification and evolution. Comparison of allelic sequences within a species suggests diversity is generated by the assortment of point mutations into varied combinations by mechanisms of recombination and gene conversion. We have now compared class I MHC alleles in two closely related species: humans (Homo sapiens) and chimpanzees (Pan troglodytes). Chimpanzee homologues of HLA-A, HLA-B and a non-classical gene have been identified. No features distinguishing human and chimpanzee alleles could be found. Individual HLA-A or B alleles are more closely related to individual chimpanzee alleles than to other HLA-A or B alleles. These results show that a considerable proportion of contemporary HLA-A and B polymorphism existed before divergence of the chimpanzee and human lines. The stability of the polymorphism indicates that hyper-mutational mechanisms are not necessary to account for HLA-A, B and C diversity.

Sources and evolution of human Alu repeated sequences

Alu repeated sequences arising in DNA of the human lineage during about the last 30 million years are closely similar to a modern consensus. Alu repeats arising at earlier times share correlated blocks of differences from the current consensus at diagnostic positions in the sequence. Using these 26 positions, we can recognize four subfamilies and the older ones are each successively closer to the 7SL sequence. It appears that there has existed a series of conserved genes that are the primary sources of the Alu repeat family, presumably through retroposition. These genes have probably replaced each other in overlapping relays during the evolution of primates.

Calibration of the change in thermal stability of DNA duplexes and degree of base pair mismatch

One method of determining the degree of base pair divergence between two sources of DNA (different strains, species, etc.) is to determine the decrease in thermal stability of hybrid duplex DNA due to mismatching of base pairs. Attempts to calibrate the change in median melting temperature (delta Tm) to base pair mismatch have led to conflicting results. We have studied the delta Tm between DNAs of known sequence over a range of from 0.55% to 7.2% base pair mismatch. The relationship of delta Tm and percent base pair mismatch is remarkably linear over this range with a correlation coefficient greater than 0.98. A delta Tm of 1 degree C corresponds to 1.7% base pair mismatch. This conversion is higher than that usually assumed and, therefore, rates of DNA evolution estimated by DNA-DNA hybridization studies are likely faster than previously thought.

Sequence analyses of herpesviral enzymes suggest an ancient origin for human sexual behavior

Comparison of the amino acid sequences of the deoxythymidine kinases of herpes simplex (HSV) and of marmoset herpes viruses (MHV) suggests a divergence time of 8 to 10 million years ago for HSV-1 and -2. Like MHV, HSV-1 and -2 cause local infections in their natural hosts, and direct contact between two individuals during the brief period of infectivity is needed for transmission. Because B virus, a nearer relative of HSV, depends on both oral and genital routes of transmission, we postulate that ancestral HSV (aHSV) was similar, and that for HSV-1 and -2 to diverge, genital and oral sites had to become microbiologically somewhat isolated from each other, while oral--oral and genital--genital contact had to be facilitated to maintain both aHSV strains. We propose that acquisition of continual sexual attractiveness by the ancestral human female and the adoption of close face-to-face mating, two hallmarks of human sexual behavior, provided the conditions for the divergence.

Stone agers in the fast lane: chronic degenerative diseases in evolutionary perspective

From a genetic standpoint, humans living today are Stone Age hunter-gatherers displaced through time to a world that differs from that for which our genetic constitution was selected. Unlike evolutionary maladaptation, our current discordance has little effect on reproductive success; rather it acts as a potent promoter of chronic illnesses: atherosclerosis, essential hypertension, many cancers, diabetes mellitus, and obesity among others. These diseases are the results of interaction between genetically controlled biochemical processes and a myriad of biocultural influences--lifestyle factors--that include nutrition, exercise, and exposure to noxious substances. Although our genes have hardly changed, our culture has been transformed almost beyond recognition during the past 10,000 years, especially since the Industrial Revolution. There is increasing evidence that the resulting mismatch fosters "diseases of civilization" that together cause 75 percent of all deaths in Western nations, but that are rare among persons whose lifeways reflect those of our preagricultural ancestors.

Varicella in a gorilla

Naturally occurring varicella was observed in a young gorilla in captivity. The isolate was demonstrated to be varicella-zoster virus by restriction enzyme analysis.

On the molecular evolutionary clock

The conceptual framework surrounding the origin of the molecular evolutionary clock and circumstances of this origin are described. In regard to the quest for the best available molecular clocks, a return to protein clocks is conditionally recommended. On the basis of recent data and certain considerations, it is pointed out that the realm of neutrality in evolution is probably less extensive than is now commonly thought, in the three distinct senses of the term neutrality--neutrality as nonfunctionality of mutations, neutrality as equifunctionality of mutations, and neutrality as a mode of fixation of mutations. The possibility is raised that complex sets of interacting components forming a system that is bounded with respect to its environment may quite generally display an intrinsic trend to a quasi-clockwise evolutionary behavior.

Man's place in Hominoidea as inferred from molecular clocks of DNA

Divergence dates among primates were estimated by molecular clock analysis of DNA sequence data. A molecular clock of eta-globin pseudogene was calibrated by setting the date of divergence between Catarrhini and Platyrrhini at 38 million years (Myr) ago. The clock gave dates of 25.3 +/- 2.4, 11.9 +/- 1.7, 5.9 +/- 1.2, and 4.9 +/- 1.2 Myr ago ( +/- refers to standard error) for the separation of rhesus monkey, orangutan, gorilla, and chimpanzee, respectively, from the line leading to humans. In placing confidence intervals of the estimates in a robust way, a bootstrap method was used. The 95% confidence intervals are 20.5-29.5, 9.0-14.8, 4.1-7.8, and 3.1-7.0 Myr ago for the separation of rhesus monkey, orangutan, gorilla, and chimpanzee, respectively. By a molecular clock dating of the Prosimii-Anthropoidea splitting, it was suggested that the evolutionary rate of the eta-globin gene was high early in primate evolution and subsequently decreased in the line of Anthropoidea. And, by a relative rate test using bootstrap sampling, the possibility of further decrease of the rate (more than 10%) in the line of Hominoidea compared with that of Cercopithecoidea was suggested. Therefore, the above dating of the splittings within Hominoidea may be biased slightly toward younger dates. On the other hand, mitochondrial DNA (mtDNA) seems to have evolved in mammals with a more uniform rate than the eta-globin gene. The ratio of the dates of orangutan splitting to chimpanzee splitting is larger for the mtDNA clock than that for the eta-globin clock, suggesting the possibilities of mtDNA introgression among the early hominids and the early African apes, and/or of mtDNA polymorphism within the common ancestral species of orangutan and the African apes that obscures the date of the true species separation of orangutans.

A simple quantitative model of the molecular clock

We present the ideas, and their motivation, at the basis of a simple model of nucleic acid evolution: the stationary Markov process, or Markov clock. After a brief review of its relevant mathematical properties, the Markov clock is applied to nucleotide sequences from mitochondrial and nuclear genes of different species. Particular emphasis is given to the necessity of carrying out a correct statistical analysis, which allows us to check quantitatively the applicability of our model. We find evidence that the Markov clock ticks in many different processes, and that its limitations can be understood in terms of a simple idea that we call the "base-drift" hypothesis. This hypothesis correlates the deviations from the stationarity of the Markov process to the evolutionary distance dAB(p) of two species A and B, relative to the process P. We conclude by discussing the implications of our findings for future work.

Molecular clocks and evolutionary relationships: possible distortions due to horizontal gene flow

This paper discusses recent evidence suggesting that genetic information from one species occasionally transfers to another remotely related species. Besides addressing the issue of whether or not the molecular data are consistent with a wide-spread influence of horizontal gene transfer, the paper shows that horizontal gene flow would not necessarily preclude a linear molecular clock or change the rate of molecular evolution (assuming the neutral allele theory). A pervasive influence of horizontal gene transfer is more than just consistent with the data of molecular evolution, it also provides a unique explanation for a number of possibly conflicting phylogenies and contradictory clocks. This phenomenon might explain why some protein clocks are linear while the superoxide dismutase clock is not, how the molecular data on the phylogeny of apes and Australian song birds are not necessarily in conflict with those based on morphology, and, finally, why the mycoplasmas have an accelerated molecular clock.

Estimation of hominoid phylogeny from a DNA hybridization data set

Analysis of the expanded data set of Sibley and Ahlquist (1987) on primate phylogeny using a maximum likelihood mixed model analysis of variance method shows that there is significant evidence for resolving the Homo-Pan-Gorilla trifurcation in favor of a Homo-Pan clade. The resulting tree is close to that estimated by Sibley and Ahlquist (1984). The mixed model can be used to test a number of hypotheses about the existence of components of variance and the linearity of the relationship between branch length and expected distance. No evidence is found that there is a variance component for extract, or for the individual from which the extract was taken. A variance component for experiment does seem to exist, presumably arising as a result of error of measurement of the common standard from which all values in the same experiment were subtracted. There is significant evidence that the relationship between total branch length between species and their expected distances is nonlinear, or else that the measurement error on larger distances is greater than on smaller ones. Allowing for the nonlinearity might cause one to infer the time of distant common ancestors as less remote than the measured hybridization values would imply if used directly.

DNA turnover and the molecular clock

Many detailed studies on the mechanisms by which different components of eukaryotic nuclear genomes have diverged reveal that the majority of sequences are seemingly not passively accumulating base substitutions in a clocklike manner solely determined by laws of diffusion at the population level. It appears that variation in the rates, units, biases, and gradients of several DNA turnover mechanisms are contributing to the course of DNA divergence. Turnover mechanisms have the potential to retard, maintain, or accelerate the rate of DNA differentiation between populations. Furthermore, examples are known of coding and noncoding DNA subject to the simultaneous operation of several turnover mechanisms leading to complex patterns of fine-scale restructuring and divergence, generally uninterpretable using selection and/or neutral drift arguments in isolation. Constancy in the rate of divergence, where observed over defined periods of time, could be a reflection of constancy in the rates and units of turnover. However, a consideration of the generally large disparity between rates of turnover and mutation reveals that DNA clocks, which would be independently driven by turnover in separate genomic components, would tend to be episodic. The utility of any given DNA sequence for measuring time and species relationships, like individual proteins, is proportional to the extent to which all contributing forces to the evolution of the sequence, internal and external, are understood.

Very slightly deleterious mutations and the molecular clock

The model of very slightly deleterious mutations was examined from the standpoint of population genetics in relation to the molecular evolutionary clock. The distribution of selection coefficients of mutants (in terms of amino acid changes) with small effect is thought to be continuous around zero, with an average negative value. The variance of selection coefficients depends upon environmental diversity and hence on total population size of a species. By considering various examples of amino acid substitutions, the average and standard error of selection coefficients and the reciprocal of population size are assumed to have similar values. The model predicts negative correlation between evolutionary rate and population size. This effect is expected to be partially cancelled with the generation time effect of intrinsic mutation rate. Implications of this prediction on the molecular evolutionary clock are discussed.

DNA hybridization evidence of hominoid phylogeny: results from an expanded data set

The living hominoids are human, the two species of chimpanzees, gorilla, orangutan, and nine species of gibbons. The cercopithecoids (Old World monkeys) are the sister group of the hominoids. A consensus about the phylogeny of the hominoids has been reached for the branching order of the gibbons (earliest) and the orangutan (next earliest), but the branching order among gorilla, chimpanzees, and human remains in contention. In 1984 we presented DNA-DNA hybridization data, based on 183 DNA hybrids, that we interpreted as evidence that the branching order, from oldest to most recent, was gibbons, orangutan, gorilla, chimpanzees, and human. In the present paper we report on an expanded data set totaling 514 DNA hybrids, which supports the branching order given above. The ranges for the datings of divergence nodes are Old World monkeys, 25-34 million years (Myr) ago; gibbons, 16.4-23 Myr ago; orangutan, 12.2-17 Myr ago; gorilla, 7.7-11 Myr ago; chimpanzees-human, 5.5-7.7 Myr ago. The possible effects of differences in age at first breeding are discussed, and some speculations about average genomic rates of evolution are presented.

Phylogenetic relations of humans and African apes from DNA sequences in the psi eta-globin region

Sequences from the upstream and downstream flanking DNA regions of the psi eta-globin locus in Pan troglodytes (common chimpanzee), Gorilla gorilla (gorilla), and Pongo pygmaeus (orangutan, the closest living relative to Homo, Pan, and Gorilla) provided further data for evaluating the phylogenetic relations of humans and African apes. These newly sequenced orthologs [an additional 4.9 kilobase pairs (kbp) for each species] were combined with published psi eta-gene sequences and then compared to the same orthologous stretch (a continuous 7.1-kbp region) available for humans. Phylogenetic analysis of these nucleotide sequences by the parsimony method indicated (i) that human and chimpanzee are more closely related to each other than either is to gorilla and (ii) that the slowdown in the rate of sequence evolution evident in higher primates is especially pronounced in humans. These results indicate that features (for example, knuckle-walking) unique to African apes (but not to humans) are primitive and that even local molecular clocks should be applied with caution.

Evolution of homologous sequences on the human X and Y chromosomes, outside of the meiotic pairing segment

A sequence isolated from the long arm of the human Y chromosome detects a highly homologous locus on the X. This homology extends over at least 50 kb of DNA and is postulated to be the result of a transposition event between the X and Y chromosomes during recent human evolution, since homologous sequences are shown to be present on the X chromosome alone in the chimpanzee and gorilla.

Evolution of four human Y chromosomal unique sequences

Four cloned unique sequences from the human Y chromosome, two of which are found only on the Y chromosome and two of which are on both the X and Y chromosomes, were hybridized to restriction enzyme-treated DNA samples of a male and a female chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla), and pig-tailed macaque (Macaca nemestrina); and a male orangutan (Pongo pygmaeus) and gibbon (Hylobates lar). One of the human Y-specific probes hybridized only to male DNA among the humans and great apes, and thus its Y linkage and sequence similarities are conserved. The other human Y-specific clone hybridized to male and female DNA from the humans, great apes, and gibbon, indicating its presence on the X chromosome or autosomes. Two human sequences present on both the X and Y chromosomes also demonstrated conservation as indicated by hybridization to genomic DNAs of distantly related species and by partial conservation of restriction enzyme sites. Although conservation of Y linkage can only be demonstrated for one of these four sequences, these results suggest that Y-chromosomal unique sequence genes do not diverge markedly more rapidly than unique sequences located on other chromosomes. However, this sequence conservation may in part be due to evolution while part of other chromosomes.

Recent insertion of an Alu sequence in the beta-globin gene cluster of the gorilla

We present the nucleotide sequence of a new Alu family member that lies between the delta- and beta-globin genes in gorilla DNA. The sequence exhibits 91% similarity with a consensus sequence of the Alu family. It is flanked by a perfect repetition of a 16-nucleotide target sequence and terminates with 24 adenylic residues. As this sequence is absent at this locus in other primate DNAs, its insertion occurred less than 8 million years ago, thus supporting the idea that Alu sequences are still mobile elements in the hominoid genome.

An evaluation of the molecular clock hypothesis using mammalian DNA sequences

A statistical analysis of extensive DNA sequence data from primates, rodents, and artiodactyls clearly indicates that no global molecular clock exists in mammals. Rates of nucleotide substitution in rodents are estimated to be four to eight times higher than those in higher primates and two to four times higher than those in artiodactyls. There is strong evidence for lower substitution rates in apes and humans than in monkeys, supporting the hominoid slowdown hypothesis. There is also evidence for lower rates in humans than in apes, suggesting a further rate slowdown in the human lineage after the separation of humans from apes. By contrast, substitution rates are nearly equal in mouse and rat. These results suggest that differences in generation time or, more precisely, in the number of germline DNA replications per year are the primary cause of rate differences in mammals. Further, these differences are more in line with the neutral mutation hypothesis than if the rates are the same for short- and long-living mammals.

Genetic structure of Neisseria meningitidis populations in relation to serogroup, serotype, and outer membrane protein pattern

The genetic structure of populations of Neisseria meningitidis was examined by an analysis of electrophoretically demonstrable allelic variation at 15 genes encoding enzymes in 650 isolates of eight serogroups (A, B, C, W135, X, Y, Z, and 29E) and 38 nonserogroupable isolates. A total of 331 distinctive multilocus genotypes (electrophoretic types, ETs) was identified, among which mean genetic diversity per locus (H = 0.547) was greater than in Escherichia coli and other bacterial species thus far studied. The intercontinental distribution of some ETs and the recovery of organisms of identical genotype over periods of many years strongly suggest that the genetic structure of N. meningitidis is basically clonal as a consequence of low rates of recombination of chromosomal genes. Variation among strains in serogroup, serotype, and the electrophoretic pattern of the major outer membrane proteins has little relationship to the complex structure of populations revealed by enzyme electrophoresis, which involves 14 major lineages of clones diverging from one another at genetic distances greater than 0.50. Genetic diversity among ETs of isolates of the same serogroup was, on average, 84% of that in the total sample. Clones of serogroup A were unusual in being genotypically less heterogeneous than those of other serogroups and in forming a single phylogenetic group. Isolates of the same serotype or outer membrane protein pattern were also highly heterogeneous; on average, 87 and 97%, respectively, of the total species diversity was represented by ETs of the same serotype or outer membrane protein.

Evolutionary relationships of the Chinese hamster X chromosome and autosomes: a comparison using solution hybridization techniques

The evolutionary relationships of Chinese hamster X chromosome and autosome DNA sequences were compared by solution hybridization techniques. Chinese hamster X chromosome tracer was prepared by radiolabeling DNA from chromosomes isolated by fluorescence-activated sorting. Radiolabeled Chinese hamster total genomic DNA, approximately 90% of which is of autosome origin, was used as autosome tracer. Each tracer was mixed with excess driver DNA of Chinese hamster, Syrian hamster, rat, rabbit, cat, cow, or human origin. Reaction mixtures were melted and allowed to reassociate to an equivalent CoT of 12,000, under conditions which permitted 35% mismatch in DNA duplexes. Both the extent of duplex formation (the normalized percentage hybridization or NPH) and the average thermal stability of the duplexes formed (melting temperature or Tm) were measured; these values were used to compare the evolutionary relatedness of tracer and driver DNAs. The pattern of evolutionary relatedness revealed by comparing either the Tm or NPH values obtained with different drivers was the same for X chromosome and autosome DNA and was consistent with the phylogeny of the species examined. Although NPH and Tm values for X chromosome and autosome tracers differed, differences fell within the range of experimental error. The results of these studies provide no evidence for differential conservation of Chinese hamster X chromosome sequences, suggesting that the constraints on the mammalian X chromosome which act to maintain its gene linkage group intact do not markedly reduce the extent to which its sequences diverge during evolution.

A molecular phylogeny of the hominoid primates as indicated by two-dimensional protein electrophoresis

A molecular phylogeny for the hominoid primates was constructed by using genetic distances from a survey of 383 radiolabeled fibroblast polypeptides resolved by two-dimensional electrophoresis (2DE). An internally consistent matrix of Nei genetic distances was generated on the basis of variants in electrophoretic position. The derived phylogenetic tree indicated a branching sequence, from oldest to most recent, of cercopithecoids (Macaca fascicularis), gibbon-siamang, orangutan, gorilla, and human-chimpanzee. A cladistic analysis of 240 electrophoretic characters that varied between ape species produced an identical tree. Genetic distance measures obtained by 2DE are largely consistent with those generated by other molecular procedures. In addition, the 2DE data set appears to resolve the human-chimpanzee-gorilla trichotomy in favor of a more recent association of chimpanzees and humans.

DNA polymorphisms in human population studies: a review

The use of restriction endonucleases and DNA probes to expand the range of informative polymorphisms should be of immense value in the study of human populations. To date, this approach has been only minimally used, but results are available for markers in the major histocompatibility complex and the globin gene clusters. In addition, isolated studies using other probes have been published. The ease of the techniques involved, the rate at which new DNA polymorphisms are being found and the range of information provided should ensure that use of this approach expands rapidly.

Evidence that the recently discovered theta 1-globin gene is functional in higher primates

A new subfamily of the alpha-globin-like family has recently been identified in higher primates, rabbit, galago and possibly the horse. One member of this subfamily, theta 1, is downstream from the adult alpha 1-globin gene. In orang-utan, but not in rabbit or galago, the theta 1-gene appears to be structurally intact, suggesting that it may be functional in this species. The orang-utan theta 1-gene possesses initiation and termination codons, and the predicted polypeptide differs from the orang-utan alpha 1-globin by 55 amino acids. The upstream promoter boxes CCAAT and ATA are present, although approximately 150 base pairs (bp) farther upstream than in the alpha 1-gene. This structural difference in the promoter between the orang-utan theta 1- and alpha 1-genes has led Proudfoot to speculate that the theta 1-gene may be inactive. We have now cloned the theta 1- and alpha 1-globin genes from the olive baboon, and have compared their sequences with those of orang-utan. The unique promoter structure of the orang-utan theta 1-gene is highly conserved in baboon, although the orang-utan and baboon diverged nearly 30 million years ago. The coding sequences of the two theta 1-genes differ by only 6.3% with 22 out of 27 nucleotide substitutions being codon third position silent changes. These data support the view that the theta 1-gene has been functional in the baboon, orang-utan, and by implication, in man. We also estimate that the duplication event generating the theta 1- and alpha-globin-like subfamilies may have occurred as much as 260 million years ago.