Showing papers in "Molecular Biology and Evolution in 1985"

Codon usage and tRNA content in unicellular and multicellular organisms.

Abstract: Choices of synonymous codons in unicellular organisms are here reviewed, and differences in synonymous codon usages between Escherichia coli and the yeast Saccharomyces cerevisiae are attributed to differences in the actual populations of isoaccepting tRNAs. There exists a strong positive correlation between codon usage and tRNA content in both organisms, and the extent of this correlation relates to the protein production levels of individual genes. Codon-choice patterns are believed to have been well conserved during the course of evolution. Examination of silent substitutions and tRNA populations in Enterobacteriaceae revealed that the evolutionary constraint imposed by tRNA content on codon usage decelerated rather than accelerated the silent-substitution rate, at least insofar as pairs of taxonomically related organisms were examined. Codon-choice patterns of multicellular organisms are briefly reviewed, and diversity in G+C percentage at the third position of codons in vertebrate genes--as well as a possible causative factor in the production of this diversity--is discussed.

A new method for estimating synonymous and nonsynonymous rates of nucleotide substitution considering the relative likelihood of nucleotide and codon changes.

Abstract: A new method is proposed for estimating the number of synonymous and nonsynonymous nucleotide substitutions between homologous genes. In this method, a nucleotide site is classified as nondegenerate, twofold degenerate, or fourfold degenerate, depending on how often nucleotide substitutions will result in amino acid replacement; nucleotide changes are classified as either transitional or transversional, and changes between codons are assumed to occur with different probabilities, which are determined by their relative frequencies among more than 3,000 changes in mammalian genes. The method is applied to a large number of mammalian genes. The rate of nonsynonymous substitution is extremely variable among genes; it ranges from 0.004 X 10(-9) (histone H4) to 2.80 X 10(-9) (interferon gamma), with a mean of 0.88 X 10(-9) substitutions per nonsynonymous site per year. The rate of synonymous substitution is also variable among genes; the highest rate is three to four times higher than the lowest one, with a mean of 4.7 X 10(-9) substitutions per synonymous site per year. The rate of nucleotide substitution is lowest at nondegenerate sites (the average being 0.94 X 10(-9), intermediate at twofold degenerate sites (2.26 X 10(-9)). and highest at fourfold degenerate sites (4.2 X 10(-9)). The implication of our results for the mechanisms of DNA evolution and that of the relative likelihood of codon interchanges in parsimonious phylogenetic reconstruction are discussed.

The small-subunit ribosomal RNA gene sequences from the hypotrichous ciliates Oxytricha nova and Stylonychia pustulata.

Abstract: We have determined the complete nucleotide sequence of the small-subunit ribosomal RNA genes for the ciliate protozoans Stylonychia pustulata and Oxytricha nova. The sequences are homologous and sufficiently similar that these organisms must be closely related. In a phylogeny inferred from comparisons of several eukaryotic small-subunit ribosomal RNAs, the divergence of the ciliates from the eukaryotic line of descent is seen to coincide with the radiation of the plants, the animals, and the fungi. This radiation is preceded by the divergence of the slime mold, Dictyostelium discoideum.

Methods for computing the standard errors of branching points in an evolutionary tree and their application to molecular data from humans and apes.

Abstract: Statistical methods for computing the standard errors of the branching points of an evolutionary tree are developed. These methods are for the unweighted pair-group method-determined (UPGMA) trees reconstructed from molecular data such as amino acid sequences, nucleotide sequences, restriction-sites data, and electrophoretic distances. They were applied to data for the human, chimpanzee, gorilla, orangutan, and gibbon species. Among the four different sets of data used, DNA sequences for an 895-nucleotide segment of mitochondrial DNA (Brown et al. 1982) gave the most reliable tree, whereas electrophoretic data (Bruce and Ayala 1979) gave the least reliable one. The DNA sequence data suggested that the chimpanzee is the closest and that the gorilla is the next closest to the human species. The orangutan and gibbon are more distantly related to man than is the gorilla. This topology of the tree is in agreement with that for the tree obtained from chromosomal studies and DNA-hybridization experiments. However, the difference between the branching point for the human and the chimpanzee species and that for the gorilla species and the human-chimpanzee group is not statistically significant. In addition to this analysis, various factors that affect the accuracy of an estimated tree are discussed.

Statistical methods of DNA sequence analysis: detection of intragenic recombination or gene conversion.

Abstract: Simple but exact statistical tests for detecting a cluster of associated nucleotide changes in DNA are presented. The tests are based on the linear distribution of a set of s sites among a total of n sites, where the s sites may be the variable sites, sites of insertion/deletion, or categorized in some other way. These tests are especially useful for detecting gene conversion and intragenic recombination in a sample of DNA sequences. In this case, the sites of interest are those that correspond to particular ways of splitting the sequences into two groups (e.g., sequences A and D vs. sequences B, C, and E-J). Each such split is termed a phylogenetic partition. Application of these methods to a well-documented case of gene conversion in human gamma-globin genes shows that sites corresponding to two of the three observed partitions are significantly clustered, whereas application to hominoid mitochondrial DNA sequences--among which no recombination is expected to occur--shows no evidence of such clustering. This indicates that clustering of partition-specific sites is largely due to intragenic recombination or gene conversion. Alternative hypotheses explaining the observed clustering of sites, such as biased selection or mutation, are discussed.

Significance of nucleotide sequence alignments: a method for random sequence permutation that preserves dinucleotide and codon usage.

Abstract: The similarity of two nucleotide sequences is often expressed in terms of evolutionary distance, a measure of the amount of change needed to transform one sequence into the other. Given two sequences with a small distance between them, can their similarity be explained by their base composition alone? The nucleotide order of these sequences contributes to their similarity if the distance is much smaller than their average permutation distance, which is obtained by calculating the distances for many random permutations of these sequences. To determine whether their similarity can be explained by their dinucleotide and codon usage, random sequences must be chosen from the set of permuted sequences that preserve dinucleotide and codon usage. The problem of choosing random dinucleotide and codon-preserving permutations can be expressed in the language of graph theory as the problem of generating random Eulerian walks on a directed multigraph. An efficient algorithm for generating such walks is described. This algorithm can be used to choose random sequence permutations that preserve (1) dinucleotide usage, (2) dinucleotide and trinucleotide usage, or (3) dinucleotide and codon usage. For example, the similarity of two 60-nucleotide DNA segments from the human beta-1 interferon gene (nucleotides 196-255 and 499-558) is not just the result of their nonrandom dinucleotide and codon usage.

Reverse transcription in the eukaryotic genome: retroviruses, pararetroviruses, retrotransposons, and retrotranscripts.

Abstract: Recent studies indicate that > 10% of the human and mouse genome appears to consist of integrated DNA copies of RNA molecules. These sequences include retroviruses, retrovirus-like DNAs, retrotransposons, and retrotranscripts and represent more than 500,000 separate integration events. The nature of the enzymes used for the reverse transcription from RNA to DNA and for integration of the DNA copies into chromosomal DNA is unknown. A major evolutionary effect of these integrations would have been mutation. Thus, present-day organisms are those that survived this mutational load.

A comparative description of mitochondrial DNA differentiation in selected avian and other vertebrate genera.

Abstract: Levels of mitochondrial DNA (mtDNA) sequence divergence between species within each of several avian (Anas, Aythya, Dendroica, Melospiza, and Zonotrichia) and nonavian (Lepomis and Hyla) vertebrate genera were compared. An analysis of digestion profiles generated by 13-18 restriction endonucleases indicates little overlap in magnitude of mtDNA divergence for the avian versus nonavian taxa examined. In 55 interspecific comparisons among the avian congeners, the fraction of identical fragment lengths (F) ranged from 0.26 to 0.96 (F = 0.46), and, given certain assumptions, these translate into estimates of nucleotide sequence divergence (p) ranging from 0.007 to 0.088; in 46 comparisons among the fish and amphibian congeners, F values ranged from 0.00 to 0.36 (F = 0.09), yielding estimates of P greater than 0.070. The small mtDNA distances among avian congeners are associated with protein-electrophoretic distances (D values) less than approximately 0.2, while the mtDNA distances among assayed fish and amphibian congeners are associated with D values usually greater than 0.4. Since the conservative pattern of protein differentiation previously reported for many avian versus nonavian taxa now appears to be paralleled by a conservative pattern of mtDNA divergence, it seems increasingly likely that many avian species have shared more recent common ancestors than have their nonavian taxonomic counterparts. However, estimates of avian divergence times derived from mtDNA- and protein-calibrated clocks cannot readily be reconciled with some published dates based on limited fossil remains. If the earlier paleontological interpretations are valid, then protein and mtDNA evolution must be somewhat decelerated in birds. The empirical and conceptual issues raised by these findings are highly analogous to those in the long-standing debate about rates of molecular evolution and times of separation of ancestral hominids from African apes.

Evolution of influenza virus genes.

Abstract: The nucleotide sequences of the eight different influenza A virus segments (genes) were compared among 14 different subtypes. These comparisons demonstrate the presence of molecular clocks in the viral genes; they accumulated both silent and amino acid-changing substitutions at approximately constant rates with respect to time during evolution. In addition, comparison of the rates of evolution among the eight viral genes, excluding the P2 gene, revealed a rapid and roughly equal rate of silent substitution for different genes. The P2 gene exception is explained as the result of recombination (reassortment) between distantly related strains. The rate of amino acid-changing substitution differs greatly from gene to gene. The rate of silent substitution was estimated to be 1.1 X 10(-2)/site/year on the average--that is, about 2 X 10(6) times higher than eukaryotic gene equivalents, which is remarkable. Strain A/USSR/90/77 was shown to evolve with a rate that is similar to those of other strains but to behave as if replication was frozen during a certain period (Nakajima et al. 1978). The frozen period was estimated to be 25 yr on the basis of the molecular clock. A similar analysis revealed another example of frozen replication--in this case, apparently for a period of about 9 yr--in a duck strain, A/duck/Ontario/77.

Biochemical differentiation in bile duct cestodes and their marsupial hosts.

Abstract: Isozyme electrophoresis was used to assess possible cospeciation of parasites (cestodes of the Progamotaenia festiva complex) and their hosts (Australian diprotodont marsupials) and to compare the extent of interspecific genetic diversity of the parasites and their hosts. On the basis of morphology, there are three species in the complex, although electrophoresis revealed 14 distinct genetic types, most of which were host specific, although there were three cases of apparent host switching. The evolutionary relationships among the parasites were only partially concordant with those among the hosts. Moreover, the extent of electrophoretic diversity among the parasites was much higher than that among hosts.

Dehalogenase genes of Pseudomonas putida PP3 on chromosomally located transposable elements.

Abstract: Pseudomonas putida PP3 utilizes halogenated alkanoic acids (HAA) such as 2,2-DCPA as its sole carbon and energy sources. Spontaneous HHA- mutants, isolated by selection for resistance to the toxic analogs monochloroacetic acid and dichloroacetic acid, arose at frequencies several orders of magnitude higher than expected for spontaneous mutations. Analysis of the five classes of mutants isolated suggested that the dehalogenase and HAA permease genes were on chromosomally located transposable elements and that the spontaneous mutations involved excision of these elements. This suggestion was confirmed by the observation that one of the elements can transpose to a target DNA molecule. The frequency of the excision event was strongly influenced by environmental conditions. Possible relationships between expression of cryptic genes and their location on transposable elements are discussed.

The phylogeny of the hominoid primates: a statistical analysis of the DNA-DNA hybridization data.

Abstract: Sibley and Ahlquist compared the single-copy nuclear DNA sequences of the hominoid primates using DNA-DNA hybridization. From this data set they estimated a phylogeny that clusters man and chimpanzees using a distance Wagner procedure. However, no assessment of statistical confidence in this estimated phylogeny was made, despite the fact that their data set contains internal inconsistencies concerning the correct branching order. This paper presents a modification of Pielou's Q-statistic that allows one to make nonparametric tests of phylogenetic relationship from distance data. The results of this analysis indicate that the estimated phylogeny of Sibley and Ahlquist is without statistical significance owing to the internal inconsistencies of the data set. A survey and additional analyses of other types of molecular data indicate that the phylogeny that clusters chimpanzees and gorillas and has the human lineage splitting off earlier is statistically consistent with all the molecular data (including the DNA-DNA hybridization data), whereas the phylogeny estimated by Sibley and Ahlquist can be rejected at the 5% level using the data on restriction-endonuclease sites in the mitochondrial genome.

Biochemical pathways in prokaryotes can be traced backward through evolutionary time.

Abstract: For the first time, a credible prokaryotic phylogenetic tree is being assembled by Woese and others using quantitative sequence analysis of oligonucleotides in the highly conservative rRNA. This provides an evolutionary scale against which the evolutionary steps that led to the arrangement and regulation of contemporary biochemical pathways can be measured. This paper presents an emerging evolutionary picture of aromatic amino acid biosynthesis within a large superfamily assemblage of prokaryotes that is sufficiently developed to illustrate a new perspective that will be applicable to many other biochemical pathways.

Tempo and mode of concerted evolution in the L1 repeat family of mice.

Abstract: A 300-bp DNA sequence has been determined for 30 (10 from each of three species of mice) random isolates of a subset of the long interspersed repeat family L1. From these data we conclude that members of the L1 family are evolving in concert at the DNA sequence level in Mus domesticus, Mus caroli, and Mus platythrix. The mechanism responsible for this phenomenon may be either duplicative transposition, gene conversion, or a combination of the two. The amount of intraspecies divergence averages 4.4%, although between species base substitutions accumulate at the rate of approximately 0.85%/Myr to a maximum divergence of 9.1% between M. platythrix and both M. domesticus and M. caroli. Parsimony analysis reveals that the M. platythrix L1 family has evolved into a distinct clade in the 10-12 Myr since M. platythrix last shared a common ancestor with M. domesticus and M. caroli. The parsimony tree also provides a means to derive the average half-life of L1 sequences in the genome. The rates of gain and loss of individual copies of L1 were estimated to be approximately equal, such that approximately one-half of them turn over every 3.3 Myr.

Evolution of transposable elements: an IS10 insertion increases fitness in Escherichia coli.

Abstract: Strains of Escherichia coli carrying Tn10, a transposon consisting of two IS10 insertion sequences flanking a segment encoding for a tetracycline-resistance determinant, gain a competitive advantage in chemostat cultures. All Tn10-bearing strains that increase in frequency during competition have a new IS10 insertion that is found in the same location in the genome of those strains. We mapped, by a gradient of transmission, the position of the new IS10 insertion. We examined 11 isolates whose IS10 insertion was deleted by recombinational crossing-over, and in all cases the competitive fitness of the isolates was decreased. These results show that the IS10-generated insertion increases fitness in chemostat cultures. We named the insertion fit::IS10 and suggest that transposable elements may speed the rate of evolution by promoting nonhomologous recombination between preexisting variations within a genome and thereby generating adaptive variation.

The rate of molecular evolution of alpha-fetoprotein approaches that of pseudogenes.

Abstract: We conducted the present study in an attempt to correlate function with the rate of molecular evolution for serum albumin and alpha-fetoprotein. We found a high rate of silent substitution (between 5 X 10(-9) and 7 X 10(-9)/site/year) for both the albumin and alpha-fetoprotein genes, perhaps the highest so far reported for an expressed nuclear gene. The rates of effective substitution and amino acid changes were also very high, but in contrast to silent substitutions, they are higher for alpha-fetoprotein than for albumin by approximately 70%. For alpha-fetoprotein, the rate of effective substitution (1.5 X 10(-9)/site/year) may be approaching that for nonfunctional pseudogenes (about 3 X 10(-9)/site/year). Evolutionary divergence was also estimated at the amino acid level. It was found that the rate of change of alpha-fetoprotein (55% amino acids replaced in 100 Myr) approaches that of the fastest-evolving fibrinopeptides (92% amino acids replaced in 100 Myr). This high rate may indicate that alpha-fetoprotein can tolerate a great deal of molecular variation without its function being impaired in the process. Albumin evolves at a slower rate (39% amino acids replaced in 100 Myr), although still faster than either hemoglobin (17% amino acids replaced in 100 Myr) or cytochrome c (5% amino acids replaced in 100 Myr). The slower evolutionary rate may indicate that albumin has more refined functional specifications and hence can tolerate fewer mutational changes. The latter conclusion remains, however, to be reconciled with the condition of inherited analbuminemia, where a virtually complete absence of albumin produces surprisingly few symptoms.

Evolutionary change of restriction cleavage sites and phylogenetic inference for man and apes.

Abstract: A mathematical theory for the evolutionary change of restriction endonuclease cleavage sites is developed, and the probabilities of various types of restriction-site changes are evaluated. A computer simulation is also conducted to study properties of the evolutionary change of restriction sites. These studies indicate that parsimony methods of constructing phylogenetic trees often make erroneous inferences about evolutionary changes of restriction sites unless the number of nucleotide substitutions per site is less than 0.01 for all branches of the tree. This introduces a systematic error in estimating the number of mutational changes for each branch and, consequently, in constructing phylogenetic trees. Therefore, parsimony methods should be used only in cases where nucleotide sequences are closely related. Reexamination of Ferris et al.'s data on restriction-site differences of mitochondrial DNAs does not support Templeton's conclusions regarding the phylogenetic tree for man and apes and the molecular clock hypothesis. Templeton's claim that Nei and Li's method of estimating the number of nucleotide substitutions per site is seriously affected by parallel losses and loss-gains of restriction sites is also unsupported.

Homogenization of geographical variants at the nontranscribed spacer of rDNA in Drosophila mercatorum.

Abstract: rDNA nontranscribed spacer (NTS) lengths of Drosophila mercatorum have been measured in individuals from several geographic regions. Individuals from the different geographic subpopulations share some length fragments but are in general distinct. The length differences, both within and between individuals, arise from different copy numbers of a 250-bp repeating unit that is localized to one part of the NTS. In addition to the length differences caused by the 250-bp repeat, there is a Y chromosome (male)-specific length variant elsewhere in the NTS that is approximately 70 bp shorter than the NTS fragment from the X chromosome. Sexual dimorphism seems to be present in all Drosophila. Also, D. mercatorum has fewer NTS length variants per individual than does D. melanogaster while possessing comparable levels of restriction-site polymorphism. The mechanisms that may cause this pattern of variation are selection, gene conversion, and unequal recombination.

Chimpanzee fetal G gamma and A gamma globin gene nucleotide sequences provide further evidence of gene conversions in hominine evolution.

Abstract: The fetal globin genes G gamma and A gamma from one chromosome of a chimpanzee (Pan troglodytes) were sequenced and found to be closely similar to the corresponding genes of man and the gorilla. These genes contain identical promoter and termination signals and have exons 1 and 2 separated by the conserved short intron 1 (122 bp) and exons 2 and 3 separated by the more rapidly evolving, larger intron 2 (893 bp and 887 bp in chimpanzee G gamma and A gamma, respectively). Each intron 2 has a stretch of simple sequence DNA (TG)n serving possibly as a "hot spot" for recombination. The two chimpanzee genes encode polypeptide chains that differ only at position 136 (glycine in G gamma and alanine in A gamma) and that are identical to the corresponding human chains, which have aspartic acid at position 73 and lysine at 104 in contrast to glycine and arginine at these respective positions of the gorilla A gamma chain. Phylogenetic analysis by the parsimony method revealed four silent (synonymous) base substitutions in evolutionary descent of the chimpanzee G gamma and A gamma codons and none in the human and gorilla codons. These Homininae (Pan, Homo, Gorilla) coding sequences evolved at one-tenth the average mammalian rate for nonsynonymous and one-fourth that for synonymous substitutions. Three sequence regions that were affected by gene conversions between chimpanzee G gamma and A gamma loci were identified: one extended 3' of the hot spot with G gamma replaced by the A gamma sequence, another extended 5' of the hot spot with A gamma replaced by G gamma, and the third conversion extended from the 5' flanking to the 5' end of intron 2, with G gamma replaced here by the A gamma sequence. A conversion similar to this third one has occurred independently in the descent of the gorilla genes. The four previously identified conversions, labeled C1-C4 (Scott et al. 1984), were substantiated with the addition of the chimpanzee genes to our analysis (C1 being shared by all three hominines and C2, C3, and C4 being found only in humans). Thus, the fetal genes from all three of these hominine species have been active in gene conversions during the descent of each species.

Sequence of the ebgA gene of Escherichia coli: comparison with the lacZ gene.

Abstract: We have sequenced the ebgA (evolved beta-galactosidase) gene of Escherichia coli K12. The sequence shows 50% nucleotide identity with the E. coli lacZ gene, demonstrating that the two genes are related by descent from a common ancestral gene. Comparison of the two sequences suggests that the ebgA gene has recently been under selection. A significant excess of identical, rather than synonymous, codons used to encode identical amino acids at the same positions in the aligned sequences implies that some form of selection is operating directly at the DNA level. This selection is independent of, and in addition to, selection based on codon usage or on function of the gene products.

Gene regulatory divergence among species estimated by altered developmental patterns in interspecific hybrids.

Abstract: Disturbances in the schedules of gene expression in developing interspecific fish hybrids have been used to draw inferences about the extent of gene regulatory divergence between species and about the degree to which this gene regulatory divergence is correlated with structural gene divergence, as estimated by genetic distance. Sperm from each of 10 different species representing six genera within the family Centrarchidae was used to fertilize eggs of the Florida largemouth bass (Micropterus salmoides floridanus). The genetic distances (D; Nei 1978) between the parental species used to form the hybrids ranged from 0.133 to 0.974. The developmental success and temporal patterns of gene expression of each of the hybrids were compared with those of the Florida largemouth bass. As the genetic distance between the paternal species and the Florida largemouth bass increased, there was a general decline in developmental success in the hybrid embryos as demonstrated by the observed reductions in the percentage of hatching and by progressively earlier and more extensive morphological abnormalities. Concomitantly, progressively more marked alterations in developmental schedules of expression of 15 enzyme loci occurred in the hybrids as the genetic distance between parental species increased. However, observed deviations from this trend for a few species may represent an uncoupling of the rates and modes of evolution of structural genes from those for genes regulating developmental processes.

On the PAM matrix model of protein evolution.

Abstract: The internal consistency of the PAM matrix model of protein evolution is here investigated. The 1 PAM matrix has been constructed from amino acid replacements observed in closely related sequences. Such replacements are of two types, those that do not require an intermediate amino acid replacement and those that do. The second type of replacement must generally be produced by a repetition of the first. This allows data on the first type to be used in predicting data on the second type so that some elements of the 1 PAM matrix may be used to predict others. A discrepancy of more than two orders of magnitude is found between the predictions and the data when this is carried out. This is partly accounted for by an error in constructing the matrix. However, it also seems necessary that the basic model be modified. Several possibilities are considered. One of these is to incorporate a site-dependent spectrum of mutabilities associated with each amino acid.

Cross-hybridizing snake satellite, Drosophila, and mouse DNA sequences may have arisen independently.

Abstract: Previous reports have interpreted hybridization between snake satellite DNA and DNA clones from a variety of distant taxonomic groups as evidence for evolutionary conservation, which implies common ancestry (homology) and/or convergence (analogy) to produce the cross-hybridizing sequences. We have isolated 11 clones from a genomic library of Drosophila melanogaster, using a cloned 2.5-kb snake satellite probe of known nucleotide sequence. We have also analysed published sequence data from snakes, mice, and Drosophila. These data show that (1) all of the cross-hybridization between the snake, fly, and mouse clones can be accounted for by the presence of either of two tandem repeats, [GATA]n and [GACA]n and (2) these tandem repeats are organized differently among the different species. We find no evidence that these sequences are homologous apart from the existence of the simple repeat itself, although their divergence from a common ancestral sequence cannot be ruled out. The sequences contain a variety of homogeneous clusters of tandem repeats of CATA, GA, TA, and CA, as well as GATA and GACA. We suggest that these motifs may have arisen by a self-accelerating process involving slipped-strand mispairing of DNA. Homogeneity of the clusters might simply be the result of a rate of accumulation of tandem repeats that exceeds that of other mutations.

Nearly identical allelic distributions of xanthine dehydrogenase in two populations of Drosophila pseudoobscura.

Abstract: In a previous study, Keith (1983) showed by sequential gel electrophoresis of the esterase-5 protein in Drosophila pseudoobscura that a highly polymorphic locus with many alleles can have very similar frequency distributions in populations separated by 500 km. The present work studies another highly polymorphic locus, xanthine dehydrogenase, in the same California population samples, using the same technique to distinguish allelic classes. Twelve electromorphs were found in one population and 15 in the other. Both populations shared a single very frequent (approximately 60%) allele, as well as five other alleles in low but similar frequencies. In addition, each population had an array of unique alleles present only once in one population sample but absent in the other. A statistical test against the stationary distribution for neutral alleles shows that, if the populations are at equilibrium, then purifying selection is operating on xanthine dehydrogenase. The extremely close similarity in frequency distributions of the alleles between populations for both the xanthine dehydrogenase and esterase-5 loci, despite differences in allele frequency distribution between loci, strongly emphasizes the importance of migration in influencing genic diversity in these populations.

Structure and organization of the bovine beta-globin genes.

Abstract: Genomic clones spanning the entire cow beta-globin gene locus have been isolated and characterized. These clones demonstrate that the linkage of embryonic-like (epsilon) genes and pseudogenes (psi) to the previously described fetal (gamma) and adult (beta) genes is as follows: 5'-epsilon 3-epsilon 4-psi 3-beta-epsilon 1-epsilon 2-psi 1-psi 2-gamma-3'. Present data indicate that, like that of the goat, the fetal and adult genes arose via block duplication of an ancestral four-gene set: epsilon-epsilon-psi-beta. This duplication event preceded the divergence of cows and goats, which occurred greater than or equal to 18-20 Myr ago. However, cows do not have the additional four-gene block containing a preadult/stress globin gene (beta C). Furthermore, the cow fetal cluster contains an extra beta-like pseudogene, which apparently arose by a small-scale duplication. The fixation of this duplication may indicate a possible evolutionary role for pseudogenes.

Generation time and the rate of molecular evolution.

Abstract: The importance of generation time in determining the rate of molecular evolution has long been at issue. Resolution of this question has important consequences both for the validity of the neutral theory (as formulated by Kimura 1983) and for the use of molecular data in systematics. Wu and Li (1985) performed two tests based on comparative analyses of the DNA sequences of a variety of mammalian genes, the results of which, they argue, show clear evidence of a generation-time effect. In the first “relative rate” test the numbers of nucleotide substitutions were compared between homologous genes in humans (a long generation-time species) and “reference-species” with the numbers in the same genes between mice or rats (short generation-time species) and the same reference species. The reference species used were dogs, rabbits, pigs, cows, and goats. The results (summarized in table 1) show that for all categories of nucleotide sites the number of substitutions per site, averaged over 12 genes, was greater in the mousereference comparison than in the human-reference comparison. It is argued that this shows that there has been a faster rate of substitution in the shorter-generation-time rodent lineage, than in the longer-generation-time human lineage. In conducting the test, Wu and Li assumed that rodents and humans are more closely related to each other than either is, on average, to the reference species. This pattern of relationship (fig. 1 a) implies the following approximate numbers of substitutions (at the fourfold degenerate sites) in the three branches of the phylogenetic tree: reference species, 0.2; humans, 0.2; rodents, 0.4. Since the number of substitutions in the human and reference-species branches are approximately the same but the reference-species branch is longer than the human branch, this implies that the order of substitution rates among the three lineages has been: rodents > humans > reference. (The fourfold degenerate sites are used here to illustrate the point, which applies equally to the other kinds of sites.) The relative order of generation times among the three lineages, on the other hand, is: rodents < reference < human, there being approximately an order of magnitude difference between each adjacent pair. Thus, when all three lineages under this phylogenetic scheme are considered, there appears to be variation in substitution rate, but this variation is not adequately explained by variation in generation time. Wu and Li (1985) suggest that this test does not depend on any knowledge of the divergence times of the species. This is true of absolute divergence times, but the test depends critically on a knowledge of relative divergence times. The phylogeny in figure la is by no means firmly supported by the fossil record. Most of the major mammalian divergences occurred during the late Cretaceous and the Paleocene. However, the mammalian fossil record during this period is poor, and the relative order of divergences is not clear. An alternative pattern of relationship among the species (figure lb), one that places humans closer to the reference species than to rodents, can explain the variation in substitution rate among the three branches as resulting from variation in the lengths of the branches. In other words, if the data are analyzed in the context of a different, equally feasible, phylogenetic scheme, they can be taken as evidence that substitutions have occurred at a constant rate that is independent of generation time.

Evolution of the mouse beta-globin genes: a recent gene conversion in the Hbbs haplotype.

Abstract: We have determined the complete nucleotide sequence of the two nonallelic adult beta-globin genes of the C57BL/10 mouse. These genes, designated beta s and beta t, show a sequence similarity of 99.6% over the region bordered by the translational start and stop codons. Both beta s and beta t encode functional polypeptide chains that are identical. A comparison of the C57BL/10 beta-globin haplotype, Hbbs, with that of the BALB/c mouse, Hbbd, suggests that the two haplotypes have distinct evolutionary histories. The two adult beta-globin genes of the Hbbd haplotype, beta dmaj and beta dmin, are 16% divergent at the nucleotide level and encode distinct polypeptides that are synthesized in differing amounts. Our analysis indicates that a gene correction mechanism has been operating on the Hbbs chromosome to keep beta s and beta t evolving in concert, whereas on the Hbbd chromosome, beta dmin has diverged considerably from beta dmaj. We suggest that gene conversion is responsible for the maintained similarity of the Hbbs genes. Furthermore, we attribute the divergence of the Hbbd genes in part to the absence of a region of simple-sequence DNA within the large intervening sequence of beta dmin. We propose that this region of DNA plays a role in facilitating gene conversion. The deletion of this area in beta dmin introduced a block of nonhomology between the beta dmaj-beta dmin gene pair and thus may have inhibited further gene correction within the Hbbd haplotype.

Sequence of the ebgR gene of Escherichia coli: evidence that the EBG and LAC operons are descended from a common ancestor.

Abstract: The sequence of ebgR, the gene that encodes the EBG repressor, was determined. There is 44% DNA sequence identity between ebgR and lacI, the gene that encodes the LAC repressor. There is also 25% identity between the amino acid sequence of lacI and the deduced amino acid sequence of ebgR. The sequence of 596 bp distal to ebgA, the structural gene for EBG beta-galactosidase, was also determined. Within that region there were two sequences, 74 and 100 bp long, that showed 46% and 50% identity, respectively, to sequences in the first 600 bp of lacY, the structural gene for the lactose permease. The organization and direction of transcription of the repressor and structural genes of the two operons are identical. Taken together with the homology between ebgA and lacZ (as demonstrated in the companion article in this issue), this provides strong evidence that the EBG and LAC operons are descended from a common ancestor. The map position of these two operons supports the notion that these operons diverged following a genome duplication event in an ancestor of Escherichia coli.

The tetracycline repressor of pSC101.

Abstract: We have determined the nucleotide sequence of the gene for the repressor of the pSC101 tetracycline resistance element (tetR). The repressor gene is transcribed divergently from the gene that encodes the resistance protein and encodes a putative protein of 219 amino acids. The genetic organizations of the three major types of bacterial tetracycline resistance elements thus appear to be equivalent, even though they do not show substantial nucleic acid similarity. The pSC101 repressor protein is 80% identical with the Tn 1721 repressor over its N-terminal 150 residues, whereas the C-termini of the two species are only 35% identical. Examination of the nucleic acid sequences of the regions between the two divergent promoters suggests a model in which two dimers of the tetracycline repressor molecule interact at two adjacent dyad repeats. The dimers may interact with each other, thus strengthening their grip on the operator, and affect transcription of the repressor gene. Comparison of the tetracycline (Tet) repressor with the lambda repressor suggests that the N-terminal region of the Tet repressor forms a helix-turn-helix structure and interacts with DNA in the major groove. The region of the Tet repressor implicated in DNA binding shows significant sequence similarity to a region of histone H4, suggesting that the histone may bind to DNA by means of a similar structural motif.

The adaptation of enzymes to temperature: catalytic characterization of glucosephosphate isomerase homologues isolated from Mytilus edulis and Isognomon alatus, bivalve molluscs inhabiting different thermal environments.

Abstract: Homologues of glucosephosphate isomerase (GPI, EC 5.3.1.9) were purified to homogeneity and kinetically characterized from Mytilus edulis and Isognomon alatus, two bivalve molluscs experiencing contrasting thermal environments. The enzyme isolated from I. alatus functions at warmer temperatures (25-35 C) than GPI from M. edulis, a species that inhabits colder marine littoral habitats (5-20 C). The former exhibits apparent first-order (with respect to substrate) catalytic rate constants ( Vm,,/KM) in vitro that become progressively greater than the mussel enzyme as the assay temperature is raised. Apparent zero-order catalytic rate constants (I’,,,) are relatively less differentiated. Catalytic efficiency, defined as the rate at which a catalytic event occurs in either reaction direction for reference standard states (substrate concentrations), is greater for the enzyme from the tropical species (I. alatus) at all realistic combinations of temperature and substrate concentration except for the lowest temperatures and highest substrate concentrations, where the GPI from the boreal/temperate M. edulis is more efficient. This pattern of catalytic divergence appears to be due primarily to differentiation in V,,,/K, . These results and other published data are reviewed and shown to be inconsistent with claims that adaptation of enzymes to higher cell temperatures requires a loss in catalytic efficiency.