Variation In Base Composition Research Articles

Mitochondrial DNA variation, phylogenetic relationships, and evolution of four mediterranean genera of soles (soleidae, pleuronectiformes).

To increase knowledge about the systematics and evolution of Mediterranean soles, we assessed mitochondrial DNA variation, molecular phylogeny, and evolution in eight species from the genera Solea, Microchirus, Monochirus, and Buglossidium by large ribosomal subunit (16S) and cytochrome b (cytb) sequence analysis. Relevant molecular features are the great variation of base composition among species at the third codon in cytb and the heterogeneity of the nucleotide substitution rate. Phylogenies recovered using 16S nucleotide and cytb amino acid sequences agree with those based on morphology in assessing monophyly of Solea species and ancestry of Buglossidium luteum, but they are against the intergeneric differentiation of Microchirus and Monochirus. Conversely, phylogenetic trees based on cytb nucleotide sequences yielded relationships among taxa regardless of their evolutionary histories. The incongruities between morphological and molecular issues suggest the need for reassessing the systematic value of some morphological characters. Approximate estimates of the divergence time of Mediterranean soleid lineages range from 40 to 13 Mya (Oligocene-Miocene), indicating an ancient origin for the group.

Dynamically Heterogenous Partitions and Phylogenetic Inference: An Evaluation of Analytical Strategies with Cytochrome b and ND6 Gene Sequences in Cranes

Debates over whether molecular sequence data should be partitioned for phylogenetic analysis often confound two types of heterogeneity among partitions. We distinguish historical heterogeneity (i.e., different partitions have different evolutionary relationships) from dynamic heterogeneity (i.e., different partitions show different patterns of sequence evolution) and explore the impact of the latter on phylogenetic accuracy and precision with a two-gene, mitochondrial data set for cranes. The well-established phylogeny of cranes allows us to contrast tree-based estimates of relevant parameter values with estimates based on pairwise comparisons and to ascertain the effects of incorporating different amounts of process information into phylogenetic estimates. We show that codon positions in the cytochrome b and NADH dehydrogenase subunit 6 genes are dynamically heterogenous under both Poisson and invariable-sites + gamma-rates versions of the F84 model and that heterogeneity includes variation in base composition and transition bias as well as substitution rate. Estimates of transition-bias and relative-rate parameters from pairwise sequence comparisons were comparable to those obtained as tree-based maximum likelihood estimates. Neither rate-category nor mixed-model partitioning strategies resulted in a loss of phylogenetic precision relative to unpartitioned analyses. We suggest that weighted-average distances provide a computationally feasible alternative to direct maximum likelihood estimates of phylogeny for mixed-model analyses of large, dynamically heterogenous data sets.

Sequencing of prototype viruses in the Venezuelan equine encephalitis antigenic complex

The 5′ nontranslated region (5′NTR) and nonstructural region nucleotide sequences of nine enzootic Venezuelan equine encephalitis (VEE) virus strains were determined, thus completing the genomic RNA sequences of all prototype strains. The full-length genomes, representing VEE virus antigenic subtypes I–VI, range in size from 11.3 to 11.5 kilobases, with 48–53% overall G+C contents. Size disparities result from subtype-related differences in the number and length of direct repeats in the C-terminal nonstructural protein 3 (nsP3) domain coding sequence and the 3′NTR, while G+C content disparities are attributable to strain-specific variations in base composition at the wobble position of the polyprotein codons. Highly-conserved protein components and one nonconserved protein domain constitute the VEE virus replicase polyproteins. Approximately 80% of deduced nsP1 and nsP4 amino acid residues are invariant, compared to less than 20% of C-terminal nsP3 domain residues. In two enzootic strains, C-terminal nsP3 domain sequences degenerate into little more than repetitive serine-rich blocks. Nonstructural region sequence information drawn from a cross-section of VEE virus subtypes clarifies features of alphavirus conserved sequence elements and proteinase recognition signals. As well, whole-genome comparative analysis supports the reclassification of VEE subtype-variety IF and subtype II viruses.

Mutation pressure, natural selection, and the evolution of base composition in Drosophila.

Genome sequencing in a number of taxa has revealed variation in nucleotide composition both among regions of the genome and among functional classes of sites in DNA. Mutational biases, biased gene conversion, and natural selection have been proposed as causes of this variation. Here, we review patterns of base composition in Drosophila DNA. Nucleotide composition in Drosophila melanogaster varys regionally, and base composition is correlated between introns and exons. Drosophila species also show striking patterns of non-random codon usage. Patterns of synonymous codon usage and the biochemistry of translation suggest that natural selection may act at 'silent' sites. A relationship between recombination rates and codon usage and comparisons of the evolutionary dynamics of silent mutations within and between species support natural selection discriminating among synonymous codons. The causes of regional base composition variation are less clear. Progress in functional studies of non-coding DNA, further investigations of genome patterns, and statistical tests based on evolutionary theory will lead to a greater understanding of the contributions of mutational processes and natural selection in patterning genome-wide nucleotide composition.

Prokaryotic Genome Evolution as Assessed by Multivariate Analysis of Codon Usage Patterns

This study analyzed the codon usage patterns in three completely sequenced prokaryotic genomes. The major influences on codon usage biases were identified. It was predicted that most of the as yet unidentified open reading frames will be shown to encode functional proteins. It was also shown that translational selection in Mycoplasma genitalium has been unable to overcome the effects of random genetic drift. The dual influences of mutational pressure and translational selection are at play in the genomes of Haemophilia influenzae and Methanococcus jannaschii. In addition, there is considerable variation in base composition around the genome of M. genitalium, and this variation is gradual. These data support the theory that regional variation in base composition can be attributed to alterations in the dNTP pool during DNA replication.

Mitochondrial COI sequences in mites: evidence for variations in base composition.

Studies of mitochondrial DNA sequences in a variety of animals have shown important differences between phyla, including differences in the genetic codes used, and varying constraints on base composition. In that respect, little is known of mites, an important and diversified group. We sequenced a portion (340 nt) of the cytochrome oxidase subunit I (COI) encoding gene in twenty species of phytophagous mites belonging to nine genera of the two families Tetranychidae and Tenuipalpidae. The mitochondrial genetic code used in mites appeared to be the same as in insects. As is generally also the case in insects, the mite sequences were very rich in A + T (75% on average), especially at the third codon position (94%). However, important variations of base composition were observed among mite species, one of them showing as little as 69% A + T. Variations of base composition occur mostly through synonymous transitions, and do not have detectable effects on polypeptide evolution in this group.

Selection on silent sites in the rodent H3 histone gene family.

Selection promoting differential use of synonymous codons has been shown for several unicellular organisms and for Drosophila, but not for mammals. Selection coefficients operating on synonymous codons are likely to be extremely small, so that a very large effective population size is required for selection to overcome the effects of drift. In mammals, codon-usage bias is believed to be determined exclusively by mutation pressure, with differences between genes due to large-scale variation in base composition around the genome. The replication-dependent histone genes are expressed at extremely high levels during periods of DNA synthesis, and thus are among the most likely mammalian genes to be affected by selection on synonymous codon usage. We suggest that the extremely biased pattern of codon usage in the H3 genes is determined in part by selection. Silent site G + C content is much higher than expected based on flanking sequence G + C content, compared to other rodent genes with similar silent site base composition but lower levels of expression. Dinucleotide-mediated mutation bias does affect codon usage, but the affect is limited to the choice between G and C in some fourfold degenerate codons. Gene conversion between the two clusters of histone genes has not been an important force in the evolution of the H3 genes, but gene conversion appears to have had some effect within the cluster on chromosome 13.

Complete DNA sequence of yeast chromosome XI.

The complete DNA sequence of the yeast Saccharomyces cerevisiae chromosome XI has been determined. In addition to a compact arrangement of potential protein coding sequences, the 666,448-base-pair sequence has revealed general chromosome patterns; in particular, alternating regional variations in average base composition correlate with variations in local gene density along the chromosome. Significant discrepancies with the previously published genetic map demonstrate the need for using independent physical mapping criteria.

DNA base modification inChlorella

The nuclear DNA base composition of 26 strains of green algae belonging to the Chlorococcales was analysed by reversed-phase high-performance liquid chromatography (HPLC). 5-Methyldeoxycytidine was the only modified nucleoside detected in addition to the standard nucleosides deoxyadenosine, deoxycytidine, deoxyguanosine and deoxythymidine. The amount of 5-methyldeoxycytidine varied from 1·5 mol% to 12·0 mol% and was correlated with the deoxyguanosine + deoxycytidine (G + C) content of the DNA. No significant influence of deoxycytidine methylation on the thermal stability of the DNA double strand was found. The variation of DNA base composition previously observed within the genus Chlorella and, in particular, within C. sorokiniana, could not be explained by the influence of variable amounts of modified bases on the DNA melting temperature from which the G + C contents were derived.

Nucleotide composition as a driving force in the evolution of retroviruses.

All complete retrovirus sequences in the GenEMBL database were examined with the goal of assessing possible relationships between the nucleotide composition of retroviral genomes, the amino acid composition of retroviral proteins, and evolutionary strategies used by retroviruses. The results demonstrated that the genome of each viral lineage has a characteristic base composition and that the variations between groups are related to retroviral phylogeny. By analogy to microbial species, we suggest that the variations arise from group-specific patterns of directional mutations where the bias can be exerted on any of the four nucleotides. It is most likely that the mutational patterns are introduced during reverse transcription, and a direct participation of reverse transcriptase in the process is suspected. A straightforward strategy was used to analyze the compositional relationship between nucleotides and encoded amino acids. The procedure entailed calculations of amino acid frequencies from nucleotide content and the comparison of the calculated values to the observed amino acid frequencies in retroviruses. The results revealed an excellent correspondence between variation in genomic base composition and variation in amino acid composition of proteins with the compositional differences extending into all major coding regions of the viruses. Because of the magnitude and dispersion of these effects, and because of the nonconservative nature of many of the substitutions between groups with different genomic biases, we suggest that the variations in protein composition driven by biased nucleotide frequencies are an important factor in shaping the characteristic phenotypes of the different viral lineages. A clue to the nature of the evolutionary forces that are responsible for the generation of nucleotide biases was provided by the observation that viruses with radically different base frequencies most often inhabit the same cell type. This observation, along with analysis of amino acid and nucleotide replacement patterns between and within reverse transcriptase sequences from the various groups, permitted us to advance a model for the evolution of retroviruses. According to the model, speciation could initiate when daughter virions from a single progenitor vary in the direction of their mutational bias. These variations would exert a pleiotropic effect on the frequencies of nucleotides in all viral genes and consequently on the frequencies of amino acids in the encoded proteins. The variants with the most extreme compositional differences would have a selective advantage because their different precursor requirements would enable them to occupy different ecological niches within a single cell.(ABSTRACT TRUNCATED AT 400 WORDS)

Whole-cell Protein Patterns, DNA Base Compositions and Coenzyme Q Types in the Yeast Genus Cryptococcus Kützing and Related Taxa

A numerical analysis was performed on one-dimensional whole-cell protein electrophoretic fingerprints of 90 strains belonging to the basidiomycetous anamorphic genus Cryptococcus and presumably related taxa in the genera Filobasidium and Tremella . A significant protein electrophoretic heterogeneity was observed within the species Cryptococcus albidus , C. humicola , C. laurentii and C. luteolus . This heterogeneity in protein profiles was confirmed by considerable variations in DNA base composition. A high similarity in protein profiles was confirmed by identical DNA base compositions and coenzyme Q types for some strains of C. albidus var. albidus and the strains studied of C. kuetzingii . Synonymy was also suggested for the type strain of C. elinovii and the strains studied of C. teneus . A close relatedness was demonstrated for one strain of C. luteolus and two strains of C. laurentii . Strains of Filobasidium floriforme and Cryptococcus ater , showing highly similar protein patterns, were characterized by an analogous range of mol% G+C content and an identical ubiquinone type. For the reference strains studied of the genus Tremella the data suggest close relationships between respectively Tremella coalescens and T. mesenterica , T. fuciformis and T. samoensis , and T. encephala and T. subanomala . There were no indications for a close phylogenetic relatedness between species of the genera Tremella and Cryptococcus .

Codon usage in Caenorhabditis elegans: delineation of translational selection and mutational biases.

Synonymous codon usage varies considerably among Caenorhabditis elegans genes. Multivariate statistical analyses reveal a single major trend among genes. At one end of the trend lie genes with relatively unbiased codon usage. These genes appear to be lowly expressed, and their patterns of codon usage are consistent with mutational biases influenced by the neighbouring nucleotide. At the other extreme lie genes with extremely biased codon usage. These genes appear to be highly expressed, and their codon usage seems to have been shaped by selection favouring a limited number of translationally optimal codons. Thus, the frequency of these optimal codons in a gene appears to be correlated with the level of gene expression, and may be a useful indicator in the case of genes (or open reading frames) whose expression levels (or even function) are unknown. A second, relatively minor trend among genes is correlated with the frequency of G at synonymously variable sites. It is not yet clear whether this trend reflects variation in base composition (or mutational biases) among regions of the C.elegans genome, or some other factor. Sequence divergence between C.elegans and C.briggsae has also been studied.

Regional base composition variation along yeast chromosome III: evolution of chromosome primary structure.

The recent determination of the complete sequence of chromosome III from the yeast Saccharomyces cerevisiae allows, for the first time, the investigation of the long range primary structure of a eukaryotic chromosome. We have found that, against a background G+C level of about 35%, there are two regions (one in each chromosome arm) in which G+C values rise to over 50%. This effect is seen in silent sites within genes, but not in noncoding intergenic sequences. The variation in G+C content is not related to differential selection of synonymous codons, and probably reflects mutational biases. That the intergenic regions do not exhibit the same phenomenon is particularly interesting, and suggests that they are under substantial constraint. The yeast chromosome may be a model of the structure of the human genome, since there is evidence that it is also a mosaic of long regions of different base compositions, reflected in wide variation of G+C content at silent sites among genes. Two possible causes of this regional effect, replication timing, and recombination frequency, are discussed.

HeT-A, a transposable element specifically involved in "healing" broken chromosome ends in Drosophila melanogaster.

Eight terminally deleted Drosophila melanogaster chromosomes have now been found to be "healed." In each case, the healed chromosome end had acquired sequence from the HeT DNA family, a complex family of repeated sequences found only in telomeric and pericentric heterochromatin. The sequences were apparently added by transposition events involving no sequence homology. We now report that the sequences transposed in healing these chromosomes identify a novel transposable element, HeT-A, which makes up a subset of the HeT DNA family. Addition of HeT-A elements to broken chromosome ends appears to be polar. The proximal junction between each element and the broken chromosome end is an oligo(A) tract beginning 54 nucleotides downstream from a conserved AATAAA sequence on the strand running 5' to 3' from the chromosome end. The distal (telomeric) ends of HeT-A elements are variably truncated; however, we have not yet been able to determine the extreme distal sequence of a complete element. Our analysis covers approximately 2,600 nucleotides of the HeT-A element, beginning with the oligo(A) tract at one end. Sequence homology is strong (greater than 75% between all elements studied). Sequence may be conserved for DNA structure rather than for protein coding; even the most recently transposed HeT-A elements lack significant open reading frames in the region studied. Instead, the elements exhibit conserved short-range sequence repeats and periodic long-range variation in base composition. These conserved features suggest that HeT-A elements, although transposable elements, may have a structural role in telomere organization or maintenance.

HeT-A, a transposable element specifically involved in "healing" broken chromosome ends in Drosophila melanogaster.

Eight terminally deleted Drosophila melanogaster chromosomes have now been found to be "healed." In each case, the healed chromosome end had acquired sequence from the HeT DNA family, a complex family of repeated sequences found only in telomeric and pericentric heterochromatin. The sequences were apparently added by transposition events involving no sequence homology. We now report that the sequences transposed in healing these chromosomes identify a novel transposable element, HeT-A, which makes up a subset of the HeT DNA family. Addition of HeT-A elements to broken chromosome ends appears to be polar. The proximal junction between each element and the broken chromosome end is an oligo(A) tract beginning 54 nucleotides downstream from a conserved AATAAA sequence on the strand running 5' to 3' from the chromosome end. The distal (telomeric) ends of HeT-A elements are variably truncated; however, we have not yet been able to determine the extreme distal sequence of a complete element. Our analysis covers approximately 2,600 nucleotides of the HeT-A element, beginning with the oligo(A) tract at one end. Sequence homology is strong (greater than 75% between all elements studied). Sequence may be conserved for DNA structure rather than for protein coding; even the most recently transposed HeT-A elements lack significant open reading frames in the region studied. Instead, the elements exhibit conserved short-range sequence repeats and periodic long-range variation in base composition. These conserved features suggest that HeT-A elements, although transposable elements, may have a structural role in telomere organization or maintenance.

Base compositional structure of genomes

We model the base compositional structure of the human and Escherichia coli genomes. Three particular properties are first quantified: (1) There is a significant tendency for any region of either genome to have a strand-symmetric base composition. (2) The variation in base composition from region to region, within each genome, is very much larger than expected from common homogeneous stochastic models. (3) A given local base composition tends to persist over a scale of at least kilobases ( E. coli) or tens of kilobases (human). Multidomain stochastic models from the literature are reviewed and sharpened. In particular, quantitative measurements of the third property lead us to suggest a significant shift in the style of domain models, in which the variation of A + T content with position is modeled by a random walk with frequent small steps rather than with large quantum jumps. As an application, we suggest a way to reduce the amount of computation in the assembly of large sequences from sequences of randomly chosen fragments.

Co-polymer tracts in eukaryotic, prokaryotic, and organellar DNA

Large variations in DNA base composition and noticeable strand asymmetries are known to occur between different organisms and within different regions of the genomes of single organisms. Apparently such composition and sequence biases occur to fulfill structural rather than informational requirements. Here we report the wide occurrence of a more subtle biasing of DNA sequence that can have structural consequences: an increase or a suppression of the number of long tracts of two-base co-polymers. Strong biases were observed when the DNA sequences of the longest eukaryotic, prokaryotic, and organellar entries in the GenBank data base (totaling 773 kilobases) were analyzed for the number of occurrences of tracts of the two-base co-polymers (A,T)n, (G,C)n, and (A,C)n as a function of tract length. (The expression (A,T)n is used here to denote an uninterrupted tract, n nucleotides in length, of A and T bases in any proportion or order, terminated at each end by a G or C residue.) Characteristic differences are also observed in tract biases of eukaryotic vs. prokaryotic organisms.

Variation in nuclear DNA base composition (mol % G + C) in three orders of marine green algae

Variation in nuclear DNA base composition (mol % G + C) in three orders of marine green algae

Directional mutation pressure and neutral molecular evolution.

A quantitative theory of directional mutation pressure proposed in 1962 explained the wide variation of DNA base composition observed among different bacteria and its small heterogeneity within individual bacterial species. The theory was based on the assumption that the effect of mutation on a genome is not random but has a directionality toward higher or lower guanine-plus-cytosine content of DNA, and this pressure generates directional changes more in neutral parts of the genome than in functionally significant parts. Now that DNA sequence data are available, the theory allows the estimation of the extent of neutrality of directional mutation pressure against selection. Newly defined parameters were used in the analysis, and two apparently universal constants were discovered. Analysis of DNA sequence has revealed that practically all organisms are subject to directional mutation pressure. The theory also offers plausible explanations for the large heterogeneity in guanine-plus-cytosine content among different parts of the vertebrate genome.

DNA content and base composition of human chromosomes

The relative DNA content and base composition of the 24 human chromosomes have been measured by flow cytometry. Isolated human metaphase chromosomes flowing through a finely focused laser beam were analyzed singly at a rate of 200 per s. The relative chromosomal fluorescence of the DNA specific dye propidium iodide correlated strongly ( r = 0.99) with the DNA-based human karyotype determined by image cytometry. The relative fluorescence of chromosomes stained with the dye combination Hoechst 33258 (AT binding specificity) and chromomycin A 3 (GC binding specificity) was compared with independent measurements of chromosomal base composition. The results correlated positively with quinacrine brightness ( r = 0.88) and autoradiographic determination of base-specific radioactive DNA precursor incorporation ( r = 0.55). The larger chromosomes were found to have a higher AT content than the average base composition of total human genomic DNA and the smaller chromosomes a higher GC content. Hoechst-chromomycin fluorescence depends primarily on chromosomal variation in base composition, but may also be influenced by chromosome-specific classes of repetitive DNA.