Simple repetitive DNA sequences from primates: Compilation and analysis

Simple repeats composed of tandemly repeated units 1–6 nucleotides (nt) long have been extracted from a selected set of primate genomic DNA sequences. Of the 501 theoretically possible, different types of repeats only 67 were present in the analyzed database in at least two different size ranges over 12 nt. They include all simple repeats known to be polymorphic in the primate genome. A list of moderately expanding and nonexpanding oligonucleotide patterns has also been included. Furthermore, we have compiled statistical data with emphasis on the overall variability of the most abundant 67 types of repeats. We have demonstrated that the expandability of at least some simple repeats may be affected by the overall base composition and by flanking sequences. In particular, the occurrence of tandemly repeated CAG and GCC triplets in exons positively correlates with their G+C content. We also noted that in the vicinity of Alu sequences tetrameric repeats are more abundant than in the total genomic DNA. This paper can be used as a comprehensive guide in identification of the most abundant and potentially polymorphic simple repeats. It is also of broader significance as a step toward understanding the contribution of flanking sequences and the overall sequence composition to variability of simple repeats. Correspondence to: J. Jurka     

A study of the evolution of repeated DNA sequences in primates and the existence of a new class of repetitive sequences in primates.

A new class of lowly repetitive DNA sequences has been detected in the primate genome. The renaturation rate of this sequence class is practically indistinguishable from the renaturation rate of single-copy sequences. Consequently, this lowly repetitive sequence class has not been previously observed in DNA renaturation rate studies. This new sequence class is significant in that it might occupy a major fraction of the primate genome.Based on a study of the thermal stabilities of DNA heteroduplexes constructed from human DNA and either bonnet monkey or galago DNAs, we are able to compare the relative mutation rates of repetitive and single-copy sequences in the primate genome. We find that the mutation rate of short, interspersed repetitive sequences is either less than or approximately equal to the mutation rate of single-copy sequences. This implies that the base sequence of these repetitive sequences is important to their biological function.We also find that numerous mutations have accumulated in interspersed repeated sequences since the divergence of galago and human. These mutations are only recognizable because they occur at specific sites in the repeated sequence rather than at random sites in the sequence. Although interspersed repetitive sequences from human and galago can readily cross-hybridize, these site-specific mutations identify them as being two distinct classes. In contrast, far fewer site-specific mutations have occurred since the divergence of human and monkey.     

Mitochondrial DNA sequences of primates: Tempo and mode of evolution

Summary We cloned and sequenced a segment of mitochondrial DNA from human, chimpanzee, gorilla, orangutan, and gibbon. This segment is 896 bp in length, contains the genes for three transfer RNAs and parts of two proteins, and is homologous in all 5 primates. The 5 sequences differ from one another by base substitutions at 283 positions and by a deletion of one base pair. The sequence differences range from 9 to 19% among species, in agreement with estimates from cleavage map comparisons, thus confirming that the rate of mtDNA evolution in primates is 5 to 10 times higher than in nuclear DNA. The most striking new finding to emerge from these comparisons is that transitions greatly outnumber transversions. Ninety-two percent of the differences among the most closely related species (human, chimpanzee, and gorilla) are transitions. For pairs of species with longer divergence times, the observed percentage of transitions falls until, in the case of comparisons between primates and non-primates, it reaches a value of 45. The time dependence is probably due to obliteration of the record of transitions by multiple substitutions at the same nucleotide site. This finding illustrates the importance of choosing closely related species for analysis of the evolutionary process. The remarkable bias toward transitions in mtDNA evolution necessitates the revision of equations that correct for multiple substitutions at the same site. With revised equations, we calculated the incidence of silent and replacement substitutions in the two protein-coding genes. The silent substitution rate is 4 to 6 times higher than the replacement rate, indicating strong functional constraints at replacement sites. Moreover, the silent rate for these two genes is about 10% per million years, a value 10 times higher than the silent rate for the nuclear genes studied so far. In addition, the mean substitution rate in the three mitochondrial tRNA genes is at least 100 times higher than in nuclear tRNA genes. Finally, genealogical analysis of the sequence differences supports the view that the human lineage branched off only slightly before the gorilla and chimpanzee lineages diverged and strengthens the hypothesis that humans are more related to gorillas and chimpanzees than is the orangutan.Abbreviations mtDNA mitochondrial DNA - bp base pair - URF unidentified reading frame     

Molecular and cytological characterization of repetitive DNA sequences in Brassica

Summary We isolated three different repetitive DNA sequences from B. campestris and determined their nucleotide sequences. In order to analyze organization of these repetitive sequences in Brassica, Southern blot hybridization and in situ hybridization with metaphase chromosomes were performed. The sequence cloned in the plasmid pCS1 represented a middle repetitive sequence present only in B. campestris and not detected in closely related B. Oleracea. This sequence was localized at centromeric regions of six specific chromosomes of B. campestris. The second plasmid, pBT4, contained a part of the 25S ribosomal RNA gene, and its copy number was estimated to be 1,590 and 1,300 per haploid genome for B. campestris and B. oleracea, respectively. In situ hybridization with this sequence showed a clear signal at the NOR region found in the second largest chromosome of B. Campestris. The third plasmid, pBT11, contained a 175-bp insert that belongs to a major family of tandem repeats found in all the Brassica species. This sequence was detected at centromeric regions of all the B. campestris chromosomes. Our study indicates that in situ hybridization with various types of repetitive sequences should give important information on the evolution of repetitive DNA in Brassica species.     

Molecular evolution of chloroplast DNA sequences

Comparative data on the evolution of chloroplast genes are reviewed. The chloroplast genome has maintained a similar structural organization over most plant taxa so far examined. Comparisons of nucleotide sequence divergence among chloroplast genes reveals marked similarity across the plant kingdom and beyond to the cyanobacteria (blue-green algae). Estimates of rates of nucleotide substitution indicate a synonymous rate of 1.1 x 10(-9) substitutions per site per year. Noncoding regions also appear to be constrained in their evolution, although addition/deletion events are common. There have also been evolutionary changes in the distribution of introns in chloroplast encoded genes. Relative to mammalian mitochondrial DNA, the chloroplast genome evolves at a conservative rate.      

The evolution of repetitive DNA sequences in sea urchins.

Molecular hybridization of nuclear DNAs has been employed to study the evolution of the repetitive DNA sequences in four species of sea urchin. The data show that relative to S. purpuratus there has been approximately 0.1% sequence divergence per million years in the repetitive DNA sequences of S. droebachiensis, S. franciscanus, and L. pictus. These results confirm that repetitive DNA sequences are strongly conserved during evolution. However, comparison of the extent of base pair mismatch in the repetitive DNA heteroduplexes formed at Cot 20 with those formed at Cot 200 during the hybridization of S. purpuratus and L. pictus DNAs reveals that highly repetitive sequences of sea urchins may diverge more rapidly than do the more moderately repetitive sequences.     

Molecular cytogenetic characterization of telomere-specific repetitive DNA sequences in Rana rugosa

We performed a molecular cloning of the glutamic oxaloacetic transaminase (GOT1) gene from R. rugosa, and determined its chromosomal location. This gene was reportedly localized near the sex-determining region of the ZW sex chromosomes in the frog Buergeria buergeri; however, the GOT1 gene was mapped to the distal end of chromosome 9 in R. rugosa using a GOT1 cDNA FISH probe. This was also the case when a 46.3?kb genomic clone containing exon 8 and 9 and the 3'-neighboring region of the GOT1 gene, designated clone B, was used as probe. However, weak signals were also detected at the telomeric ends of other autosomes and the Z sex chromosome, and near the centromeric region of the W sex chromosome. To intensify the signals, we used eight internal fragments in clone B and applied them to chromosome mapping. Consequently, only two fragments containing repeated sequence blocks produced hybridization signals; those signals were observed on autosomes and ZW sex chromosomes. The 3'-neighboring region contained two types of repeated sequence elements: a 41?bp element, designated 41-REL, localized to telomeric ends of autosomes and a 31?bp element, designated 31-REL, localized to telomeric ends of all autosomes and the ZW sex chromosomes, and also near the centromere on the W long arm. The results collectively suggest that the two repeated sequence elements were independently amplified around the chromosomal telomeres in R. rugosa, indicating that they will be useful cytogenetic markers for studying karyotypic evolution-especially the W chromosome differentiation-in this species.     

Molecular characterization of repetitive DNA sequences from a B chromosome

In the parasitic waspNasonia vitripennis, certain males carry a B chromosome, called PSR (paternal sex ratio), which causes the compaction and subsequent loss of the paternal chromosomes in fertilized eggs. BecauseNasonia are haplo-diploid, this leads to the production of all-male broods. Three families (PSR2, PSR18, PSR22) of related, tandemly repetitive DNAs were shown to be present solely on the PSR chromosome. These three families shared two conserved, palindromic ANA sequences, which may play a role in either PSR function or amplification of the tandem arrays. The tandem repeat family NV79 was determined to be present on the PSR chromosome as well as on at least one of the A chromosomes. This shared repeat as well as two repeat families (NV85, NV126) that were localized on the A chromosomes were detected in two sibling species ofN. vitripennis. NV79 and NV126 were also found in the more distantly related species,Trichomalopsis dubius.by H.F. Willard     

Diversity and evolution of four dispersed repetitive DNA sequences in the genus Secale

We present the first characterization of 360 sequences in six species of the genus Secale of both cultivated and wild accessions. These include four distinct kinds of dispersed repetitive DNA sequences named pSc20H, pSc119.1, pSaO5(411), and pSaD15(940) belonging to the Revolver family. During the evolution of the genus Secale from wild to cultivated accessions, the pSaO5(411)-like sequences became shorter mainly because of the deletion of a trinucleotide tandem repeating unit, the pSc20H-like sequences displayed apparent homogenization in cultivated rye, and the second intron of Revolver became longer. In addition, the pSc20H-, pSc119.1-, and pSaO5(411)-like sequences cloned from wild rye and cultivated rye could be divided into two large clades. No single case of the four kinds of repetitive elements has been inherited by each Secale accession from a lone ancestor. It is reasonable to consider the vertical transmission of the four repetitive elements during the evolution of the genus Secale. The pSc20H- and pSaO5(411)-like sequences showed evolutionary elimination at specific chromosomal locations from wild species to cultivated species. These cases imply that different repetitive DNA sequences have played different roles in the chromosome development and genomic evolution of rye. The present study adds important information to the investigations dealing with characterization of dispersed repetitive elements in wild and cultivated rye.     

Phylogeny and molecular evolution in primates

Statistical methods for estimating the branching order and the branching dates from DNA sequence data, taking into account of the rate variation among lineages, are reviewed. An application of the methods to data from primates suggests that chimpanzee is the closest relative of man, and further suggests that these two species diverged about 4-5 million years ago.     

DNA of Akodon (Rodentia, Cricetidae). II. Molecular hybridization of repetitive DNA sequences

Interspecies repetitive DNA homology was studied in akodont rodents related at generic and suprageneric levels. The homology was determined by taking the species Akodon molinae as the reference species. The 3H-DNA/DNA hybridization on filters showed a closer relationship between A. molinae and A. azarae, A. dolores and A. mollis than between A. molinae and Bolomys obscurus. These data agree with the taxonomical ranking of the species. The quantity and quality of the hybrid DNAs were measured by investigating their thermal stabilities and subsequent comparison to the results obtained on the reference species. These data indicate high similitude between the repetitive DNA of A. dolores and A. molinae. Increasing differences were shown to occur in the repetitive DNA of A. mollis, B. obscurus and A. azarae, respectively. Since these results coincide with the G-banding homologies and differ slightly from the taxonomical rank, it is speculated that the divergency between the DNA of A. molinae and A. azarae is the result of a differential process of DNA amplification which is not related to the phylogenetical distance separating the two species.     

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.     

Differentiation trees,a junk DNA molecular clock,and the evolution of neoteny in salamanders

Obligate neotenic salamanders die if forced to metamorphose. We suggest that this can be explained by assuming: 1) their “excess” DNA is “junk” DNA; 2) the “adult” specifying portion of the DNA becomes junk DNA and is available for repeated duplication. This suggests a “new” junk DNA molecular clock. We obtain remarkable agreement in “predicting” the amount of DNA per nucleus in present day non-obligate neotene salamanders from this molecular clock. These observatons are consistent with the idea that the development of these animals is describable in terms of differentiation trees whose branches (gene cascades) corresponding to adult somatic tissues accumulate deleterious mutations over evolutionary time. We show that the amount of DNA per nucleus increases linearly with the phylogenetic age of salamander families. The lack of constraints by natural selection, on unused adult branches, may account for the large amount of so-called “junk DNA” in obligate neotenic salamanders. The effects of this excess DNA, via increased cell size, suggest a positive feedback, ecophysiological explanation for such junk DNA: adaptation to cool water environments is enhanced by the lower metabolism associated with more DNA, larger cells and slower developmental time.     

Structure and evolution of a family of interspersed repetitive DNA sequences inCaenorhabditis elegans

Summary The structure of three members of a repetitive DNA family from the genome of the nematodeCaenorhabditis elegans has been studied. The three repetitive elements have a similar unitary structure consisting of two 451-bp sequences in inverted orientation separated by 491 bp, 1.5 kb, and 2.5 kb, respectively. The 491-bp sequence separating the inverted 451-bp sequences of the shortest element is found adjacent to one of the repeats in the other two elements as well. The combination of the three sequences we define as the basic repetitive unit. Comparison of the nucleotide sequences of the three elements has allowed the identification of the one most closely resembling the primordial repetitive element. Additionally, a process of co-evolution is evident that results in the introduction of identical sequence changes into both copies of the inverted sequence within a single unit. Possible mechanisms are discussed for the homogenization of these sequences. A direct test of one possible homogenization mechanism, namely homologous recombination between the inverted sequences accompanied by gene conversion, shows that recombination between the inverted repeats does not occur at high frequency.     

The evolution of the long and short repetitive DNA sequences in sea urchins.

The rates of evolution of purified long and short repetitive DNA sequences were examined by hybridisation analysis between the DNAs from several species of sea urchins. We find that the rates of nucleotide substitution are very comparable within mutually retained sequences for the two classes of repetitive DNA. The loss of hybridisable sequences between species also occurs at similar rates among both the short and long repetitive DNA sequences. Between species that separated less than 50 million years ago, hybridisable short repetitive sequences are lost all through the spectrum of reiteration frequencies. The long repeats contain a few sequences which are highly conserved within all of the species examined, and which amount to approximately 1% of the total genome. The short repetitive class, on the other hand, does not seem to contain any such highly conserved elements. The long repetitive sequences internally appear to contain short 'units' of reiteration, which may comprise families within the long repetitive class. We find no evidence to indicate that the majority of long and short repetitive sequences evolve by different mechanisms or at different rates.