Patterns of DNA-Sequence Divergence Between <Emphasis Type="Italic">Drosophila miranda</Emphasis> and <Emphasis Type="Italic">D. pseudoobscura</Emphasis>

Contrary to the classical view, a large amount of non-coding DNA seems to be selectively constrained in Drosophila and other species. Here, using Drosophila miranda BAC sequences and the Drosophila pseudoobscura genome sequence, we aligned coding and non-coding sequences between D. pseudoobscura and D. miranda, and investigated their patterns of evolution. We found two patterns that have previously been observed in comparisons between Drosophila melanogaster and its relatives. First, there is a negative correlation between intron divergence and intron length, suggesting that longer non-coding sequences may contain more regulatory elements than shorter sequences. Our other main finding is a negative correlation between the rate of non-synonymous substitutions (d _N) and codon usage bias (F _op), showing that fast-evolving genes have a lower codon usage bias, consistent with strong positive selection interfering with weak selection for codon usage.     

Correlated Evolution of Synonymous and Nonsynonymous Sites in <Emphasis Type="Italic">Drosophila</Emphasis>

Recent work has shown that Drosophila melanogaster genes with fast-evolving nonsynonymous sites have lower codon usage bias. This pattern has been attributed to interference between positive selection at nonsynonymous sites and weak selection on codon usage. Here we have looked for this correlation in a much larger and less biased dataset, comprising 630 gene pairs from D. melanogaster and D. yakuba. We confirmed that there is a negative correlation between the rate of nonsynonymous substitutions (d_N) and codon bias in D. melanogaster. We then tested the interference hypothesis and other alternative explanations, including one involving gene expression. We found that d_N indeed correlates with the level of gene expression. Given that gene expression is a strong determinant of codon bias, the relationship between d_N and codon bias might be a by-product of gene expression. However, our tests show that none of the hypotheses we consider seem to explain the data fully.This article contains online supplementary material.Reviewing Editor: Dr. John Huelsenbeck     

A New Test for Selection Applied to Codon Usage in Drosophila simulans and D. mauritiana

In many organisms, synonymous codon usage is biased by a history of natural selection. However, codon bias, itself, does not indicate that selection is ongoing; it may be a vestige of past selection. Simple statistical tests have been devised to infer ongoing selection on codon usage by comparing the derived state frequency spectra at polymorphic sites segregating either derived preferred codons or derived unpreferred codons; if selection is effective, the frequency of derived states should be higher in the former. We propose a new test that uses the inferred degree of preference, essentially calculating the correlation of derived state frequency and the difference in preference between the derived and the ancestral states; the correlation should be positive if selection is effective. When implementing the test, derived and ancestral states can be assigned by parsimony or on the basis of relative probability. In either case, statistical significance is estimated by a simple permutation test. We explored the statistical power of the test by sampling polymorphism data from 14 loci in 16 strains of D. simulans, finding that the test retains 80% power even when quite a few of the data are discarded. The power of the test likely reflects better use of multiple features of the data, combining population frequencies of polymorphic variants and quantitative estimates of codon preferences. We also applied this novel test to 14 newly sequenced loci in five strains of D. mauritiana, showing for the first time ongoing selection on codon usage in this species.     

两种梧桐叶绿体基因组密码子使用偏性分析

为了分析美丽梧桐、云南梧桐叶绿体基因组密码子的使用偏性,该研究通过筛选美丽梧桐、云南梧桐叶绿体基因组中各52条蛋白编码序列,并利用CodonW、CUSP和SPSS软件对其密码子使用模式及偏性进行了分析。结果表明:(1)美丽梧桐、云南梧桐的GC含量分别为38.12%、38.05%,表明叶绿体基因组内富含A/T碱基。(2)有效密码子数(ENC)范围为36.91～56.46、36.55～58.04,表明多数密码子偏性较弱。(3)相对同义密码子(RSCU)分析显示,RSCU1的密码子各有29个,其中28个以A、U结尾。(4)中性绘图显示,GC_3与GC_(12)的相关性不显著,回归曲线斜率分别为0.195和0.304,说明密码子偏好性主要受到自然选择的影响。(5) ENC-plot分析中大部分基因分布于曲线的周围和下方,ENC比值多分布于-0.04～0.10之间,表明突变会影响密码子偏性的形成。此外,17、18个密码子分别被鉴定为美丽梧桐、云南梧桐的最优密码子。以上结果说明美丽梧桐、云南梧桐叶绿体基因组的密码子使用偏性可能受选择和突变共同作用,且使用模式较为相似,但具有一定的差异,可能与适应环境的进化机制有关。     

Codon usage bias: causative factors,quantification methods and genome‐wide patterns: with emphasis on insect genomes

Codon usage bias refers to the phenomenon where specific codons are used more often than other synonymous codons during translation of genes, the extent of which varies within and among species. Molecular evolutionary investigations suggest that codon bias is manifested as a result of balance between mutational and translational selection of such genes and that this phenomenon is widespread across species and may contribute to genome evolution in a significant manner. With the advent of whole‐genome sequencing of numerous species, both prokaryotes and eukaryotes, genome‐wide patterns of codon bias are emerging in different organisms. Various factors such as expression level, GC content, recombination rates, RNA stability, codon position, gene length and others (including environmental stress and population size) can influence codon usage bias within and among species. Moreover, there has been a continuous quest towards developing new concepts and tools to measure the extent of codon usage bias of genes. In this review, we outline the fundamental concepts of evolution of the genetic code, discuss various factors that may influence biased usage of synonymous codons and then outline different principles and methods of measurement of codon usage bias. Finally, we discuss selected studies performed using whole‐genome sequences of different insect species to show how codon bias patterns vary within and among genomes. We conclude with generalized remarks on specific emerging aspects of codon bias studies and highlight the recent explosion of genome‐sequencing efforts on arthropods (such as twelve Drosophila species, species of ants, honeybee, Nasonia and Anopheles mosquitoes as well as the recent launch of a genome‐sequencing project involving 5000 insects and other arthropods) that may help us to understand better the evolution of codon bias and its biological significance.     

Nonneutral GC3 and Retroelement Codon Mimicry in Phytophthora

Phytophthora is a genus entirely comprised of destructive plant pathogens. It belongs to the Stramenopila, a unique branch of eukaryotes, phylogenetically distinct from plants, animals, or fungi. Phytophthora genes show a strong preference for usage of codons ending with G or C (high GC3). The presence of high GC3 in genes can be utilized to differentiate coding regions from noncoding regions in the genome. We found that both selective pressure and mutation bias drive codon bias in Phytophthora. Indicative for selection pressure is the higher GC3 value of highly expressed genes in different Phytophthora species. Lineage specific GC increase of noncoding regions is reminiscent of whole-genome mutation bias, whereas the elevated Phytophthora GC3 is primarily a result of translation efficiency-driven selection. Heterogeneous retrotransposons exist in Phytophthora genomes and many of them vary in their GC content. Interestingly, the most widespread groups of retroelements in Phytophthora show high GC3 and a codon bias that is similar to host genes. Apparently, selection pressure has been exerted on the retroelement’s codon usage, and such mimicry of host codon bias might be beneficial for the propagation of retrotransposons. Reviewing Editor: Dr. Yves van de Peer     

Codon usage in twelve species of <Emphasis Type="Italic">Drosophila</Emphasis>

Background  

Codon usage bias (CUB), the uneven use of synonymous codons, is a ubiquitous observation in virtually all organisms examined. The pattern of codon usage is generally similar among closely related species, but differs significantly among distantly related organisms, e.g., bacteria, yeast, and Drosophila. Several explanations for CUB have been offered and some have been supported by observations and experiments, although a thorough understanding of the evolutionary forces (random drift, mutation bias, and selection) and their relative importance remains to be determined. The recently available complete genome DNA sequences of twelve phylogenetically defined species of Drosophila offer a hitherto unprecedented opportunity to examine these problems. We report here the patterns of codon usage in the twelve species and offer insights on possible evolutionary forces involved.     

槲蕨属叶绿体基因组密码子偏好性分析

叶绿体基因组密码子偏好性使用模式往往影响基因表达效率,为促进药用植物叶绿体基因工程的发展,提高槲蕨药用品质,该研究以川滇槲蕨、栎叶槲蕨和槲蕨三个近缘药用植物为材料,使用CodonW、CUSP和SPSS等软件分析其叶绿体基因组编码基因密码子使用偏好性,筛选出三个物种的最优密码子。结果表明:川滇槲蕨、栎叶槲蕨和槲蕨叶绿体基因组的有效密码子数(ENC)范围分别为40.10~61、40.33~61和40.15~61,其密码子偏好性较弱;ndhE、rpl22、rpl14、rpl20、ccsA、rps4和rpl16编码基因的ENC值差异较大,表明近缘物种中,部分基因的密码子偏好性存在一定差异;三个物种编码基因的ENC频数集中于-0.1~0.1之间,说明槲蕨属基因密码子偏好性主要受到突变的影响。川滇槲蕨12个最优密码子有6个和栎叶槲蕨相同,分别是UCU、ACU、GCU、CAA、AAA和GAU;栎叶槲蕨10个最优密码子有2个和槲蕨相同,分别是UUA和AUU,而川滇槲蕨与槲蕨无相同的最优密码子。该研究结果可为槲蕨属药用植物基因工程中外源基因的改良及其表达奠定基础。     

沙枣叶绿体全基因组序列及其使用密码子偏性分析

该研究以2株野生沙枣(Elaeagnus angustifolia Linn.)嫩枝经温室水培后的嫩叶为材料,采用CTAB法分别提取总DNA,并利用第二代测序技术进行总DNA从头测序,组装后得到2株沙枣叶绿体基因组全序列,并详细分析了其蛋白质编码基因密码子使用的偏好性及其原因,为沙枣叶绿体基因工程和分子系统进化等研究奠定基础。结果显示:(1)组装得到沙枣叶绿体基因组序列全长150 546 bp,由长度为81 113 bp的长单拷贝(LSC)区域和25 494 bp的短单拷贝(SSC)区域,以及1对分隔开它们的长18 445 bp的反向重复序列(IRS)组成;注释共得到132个基因,包括86个蛋白编码基因、38个tRNA基因和8个rRNA基因。(2)沙枣叶绿体基因组蛋白编码基因密码子的第三位碱基GC含量(GC_3)为28.47%,明显低于整个叶绿体基因组GC含量(37%),也低于第一位(GC_1)和第二位(GC_2)碱基的GC含量,说明密码子对AT碱基结尾有偏好性;其中, UCU、CCU、UGU、GCU、CUU、GAU、UCA和UAA为最优密码子。(3)同义密码子相对使用频率(RSCU)分析发现,影响密码子使用模式的因素并不单一,密码子的偏好性受到突变、选择及其他因素的共同影响,并且自然选择表达引起的序列差异比突变对密码子偏好性的影响要显著;中性绘图分析、有效密码子数(ENC-plot)分析和奇偶偏好性(PR2-plot)分析表明,沙枣叶绿体基因组使用密码子的偏性受选择的影响更大。(4)通过最大似然法、最大简约法和贝叶斯方法对胡颓子科6个物种和1个枣的叶绿体基因序列构建系统发育树,与它们使用密码子偏性聚类的结果一致,表明叶绿体基因组使用密码子偏性与物种的亲缘关系相关。     

Selection on Codon Usage for Error Minimization at the Protein Level

Given the structure of the genetic code, synonymous codons differ in their capacity to minimize the effects of errors due to mutation or mistranslation. I suggest that this may lead, in protein-coding genes, to a preference for codons that minimize the impact of errors at the protein level. I develop a theoretical measure of error minimization for each codon, based on amino acid similarity. This measure is used to calculate the degree of error minimization for 82 genes of Drosophila melanogaster and 432 rodent genes and to study its relationship with CG content, the degree of codon usage bias, and the rate of nucleotide substitution. I show that (i) Drosophila and rodent genes tend to prefer codons that minimize errors; (ii) this cannot be merely the effect of mutation bias; (iii) the degree of error minimization is correlated with the degree of codon usage bias; (iv) the amino acids that contribute more to codon usage bias are the ones for which synonymous codons differ more in the capacity to minimize errors; and (v) the degree of error minimization is correlated with the rate of nonsynonymous substitution. These results suggest that natural selection for error minimization at the protein level plays a role in the evolution of coding sequences in Drosophila and rodents.Reviewing Editor: Dr. Massimo Di Giulio     

Codon Usage by Transposable Elements and Their Host Genes in Five Species

We compared the codon usage of sequences of transposable elements (TEs) with that of host genes from the species Drosophila melanogaster, Arabidopsis thaliana, Caenorhabditis elegans, Saccharomyces cerevisiae, and Homo sapiens. Factorial correspondence analysis showed that, regardless of the base composition of the genome, the TEs differed from the genes of their host species by their AT-richness. In all species, the percentage of A + T on the third codon position of the TEs was higher than that on the first codon position and lower than that in the noncoding DNA of the genomes. This indicates that the codon choice is not simply the outcome of mutational bias but is also subject to selection constraints. A tendency toward higher A + T on the third position than on the first position was also found in the host genes of A. thaliana, C. elegans, and S. cerevisiae but not in those of D. melanogaster and H. sapiens. This strongly suggests that the AT choice is a host-independent characteristic common to all TEs. The codon usage of TEs generally appeared to be different from the mean of the host genes. In the AT-rich genomes of Arabidopsis thaliana, Caenorhabditis elegans, and Saccharomyces cerevisiae, the codon usage bias of TEs was similar to that of weakly expressed genes. In the GC-rich genome of D. melanogaster, however, the bias in codon usage of the TEs clearly differed from that of weakly expressed genes. These findings suggest that selection acts on TEs and that TEs may display specific behavior within the host genomes. Received: 2 May 2001 / Accepted: 29 October 2001     

The Evolution of Codon Preferences in Drosophila: A Maximum-Likelihood Approach to Parameter Estimation and Hypothesis Testing

Synonymous codon usage in related species may differ as a result of variation in mutation biases, differences in the overall strength and efficiency of selection, and shifts in codon preference—the selective hierarchy of codons within and between amino acids. We have developed a maximum-likelihood method to employ explicit population genetic models to analyze the evolution of parameters determining codon usage. The method is applied to twofold degenerate amino acids in 50 orthologous genes from D. melanogaster and D. virilis. We find that D. virilis has significantly reduced selection on codon usage for all amino acids, but the data are incompatible with a simple model in which there is a single difference in the long-term N _e, or overall strength of selection, between the two species, indicating shifts in codon preference. The strength of selection acting on codon usage in D. melanogaster is estimated to be |N _e s|≈ 0.4 for most CT-ending twofold degenerate amino acids, but 1.7 times greater for cysteine and 1.4 times greater for AG-ending codons. In D. virilis, the strength of selection acting on codon usage for most amino acids is only half that acting in D. melanogaster but is considerably greater than half for cysteine, perhaps indicating the dual selection pressures of translational efficiency and accuracy. Selection coefficients in orthologues are highly correlated (ρ= 0.46), but a number of genes deviate significantly from this relationship. Received: 20 December 1998 / Accepted: 17 February 1999     

Comparative genome analysis of six malarial parasites using codon usage bias based tools

Codon usage bias (CUB) is an omnipresent phenomenon, which occurs in nearly all organisms. Previous studies of codon bias in Plasmodium species were based on a limited dataset. This study uses whole genome datasets for comparative genome analysis of six Plasmodium species using CUB and other related methods for the first time. Codon usage bias, compositional variation in translated amino acid frequency, effective number of codons and optimal codons are analyzed for P.falciparum, P.vivax, P.knowlesi, P.berghei, P.chabaudii and P.yoelli. A plot of effective number of codons versus GC3 shows their differential codon usage pattern arises due to a combination of mutational and translational selection pressure. The increased relative usage of adenine and thymine ending optimal codons in highly expressed genes of P.falciparum is the result of higher composition biased pressure, and usage of guanine and cytosine bases at third codon position can be explained by translational selection pressure acting on them. While higher usage of adenine and thymine bases at third codon position in optimal codons of P.vivax highlights the role of translational selection pressure apart from composition biased mutation pressure in shaping their codon usage pattern. The frequency of those amino acids that are encoded by AT ending codons are significantly high in P.falciparum due to action of high composition biased mutational pressure compared with other Plasmodium species. The CUB variation in the three rodent parasites, P.berghei, P.chabaudii and P.yoelli is strikingly similar to that of P.falciparum. The simian and human malarial parasite, P.knowlesi shows a variation in codon usage bias similar to P.vivax but on closer study there are differences confirmed by the method of Principal Component Analysis (PCA).

Abbreviations

CDS - Coding sequences, GC1 - GC composition at first site of codon, GC2 - GC composition at second site of codon, GC3 - GC composition at third site of codon, Ala - Alanine, Arg - Arginine, Asn - Asparagine, Asp - Aspartic acid, Cys - Cysteine, Gln - Glutamine Glu - Glutamic acid Gly - Glycine His - Histidine Ile - Isoleucine Leu - Leucine Lys - Lysine Met - Methionine Phe - Phenylalanine Pro - Proline Ser - Serine Thr - Threonine Trp - Tryptophan Tyr - Tyrosine Val - Valine.     

Comparative studies on codon usage pattern of chloroplasts and their host nuclear genes in four plant species

A detailed comparison was made of codon usage of chloroplast genes with their host (nuclear) genes in the four angiosperm speciesOryza sativa, Zea mays, Triticum aestivum andArabidopsis thaliana. The average GC content of the entire genes, and at the three codon positions individually, was higher in nuclear than in chloroplast genes, suggesting different genomic organization and mutation pressures in nuclear and chloroplast genes. The results of Nc-plots and neutrality plots suggested that nucleotide compositional constraint had a large contribution to codon usage bias of nuclear genes inO. sativa, Z. mays, andT. aestivum, whereas natural selection was likely to be playing a large role in codon usage bias in chloroplast genomes. Correspondence analysis and chi-test showed that regardless of the genomic environment (species) of the host, the codon usage pattern of chloroplast genes differed from nuclear genes of their host species by their AU-richness. All the chloroplast genomes have predominantly A- and/or U-ending codons, whereas nuclear genomes have G-, C- or U-ending codons as their optimal codons. These findings suggest that the chloroplast genome might display particular characteristics of codon usage that are different from its host nuclear genome. However, one feature common to both chloroplast and nuclear genomes in this study was that pyrimidines were found more frequently than purines at the synonymous codon position of optimal codons.     

蕨类植物叶绿体基因ycf94的分子进化研究

ycf94基因是近年来在叶绿体基因组中新发现的一个基因,在蕨类植物中表现高度保守。该研究共选取94种蕨类植物,在系统发育背景下,对ycf94基因的结构特征、密码子偏好性、进化速率和适应性进化进行分析。结果表明, ycf94基因的密码子偏好性较弱,偏好使用以A/U结尾的密码子,且不同物种间的偏好性存在一定差异。密码子偏好性的形成主要受到突变压的影响,同时也存在其他因素的作用;基于凤尾蕨科和其他蕨类中ycf94基因的结构特征存在区别,对两者的分子替换速率进行了比较,表明颠换率、非同义替换率和ω值间存在显著差异;仅检测出1个正选择位点74A,强烈的负选择作用表明ycf94基因的结构和功能基本趋于稳定。这为蕨类系统发育分析提供了新依据,并提供了解析ycf94基因功能的线索。     

Study of codon bias perspective of fungal xylanase gene by multivariate analysis

Fungal xylanases has important applications in food, baking, pulp and paper industries in addition to various other industries. Xylanases are produced extensively by both bacterial and fungal sources and has tremendous potential of being active at extremes of temperature and pH. In the present study an effort has been made to explore the codon bias perspective of this potential enzyme using bioinformatics tools. Multivariate analysis has been used as a tool to study codon bias perspectives of xylanases. It was further observed that the codon usage of xylanases genes from different fungal sources is not similar and to reveal this phenomenon the relative synonymous codon usage (RSCU) and base composition variation in fungal xylanase genes were also studied. The codon biasing data like GC content at third position (GC_3S), effective codon number (N_C), codon adaptive index (CAI) were further analyzed with statistical softwares like Sigma1plot 9.0 and Systat 11.0. Furthermore, study of translation selection was also performed to verify the influences of codon usage variation among the 94 xylanase genes. In the present study xylanase gene from 12 organisms were analyzed and codon usages of all xylanases from each organism were compared separately. Analysis indicates biased codon among all 12 fungi taken for study with Aspergillus nidulans, Chaetomium globosum, Aspergillus terreus and Aspergillus clavatus showing maximum biasing. N_C plot and correspondence analysis on relative synonymous codon usage indicate that mutation bias and translation selection influences codon usage variation in fungal xylanase gene. To reveal the relative synonymous codon usage and base composition variation in xylanase, 94 genes from 12 fungi were used as model system.     

落叶松-杨栅锈菌基因组密码子使用偏好分析

为了解落叶松‐杨栅锈菌密码子使用模式,并探究影响其密码子偏好形成的因素,本研究利用CondonW对落叶松‐杨栅锈菌标准菌株98AG31基因组中14 650个基因进行分析,计算基因的有效密码子数,及64个密码子的相对使用度等偏好性参数。结果表明,落叶松‐杨栅锈菌全基因组水平的密码子偏好程度较低,只有少数基因呈现出高偏好性。落叶松‐杨栅锈菌的高频密码子多以A或T结尾,而最优密码子则倾向以G或C结尾。PR2-plot分析及ENC-plot曲线与中性绘图分析显示,落叶松‐杨栅锈菌基因密码子使用模式受到选择压力和突变压力等多重因素的影响,相较于选择压力,落叶松‐杨栅锈菌基因密码子的偏好更多地受到突变压力的影响。相关性分析表明,密码子碱基组成会对密码子偏好性产生影响,其他因素如序列长度等均不会影响密码子偏好性。     

Are codon usage patterns in unicellular organisms determined by selection-mutation balance?

Strongly biased codon usage is common in unicellular organisms, particularly in highly expressed genes. The bias is most simply explained as a balance between selection and mutation, with selection favouring those codons which are more efficiently translated. In a review Ikemura (1985) has proposed four rules for predicting which codons will be preferred, based on the properties of the transfer RNAs responsible for translating messenger RNA into protein. In this paper codon usage in E. coli and yeast is re-examined using the recent compilation of Maruyama et al. (1986). The codon adaptation index of Sharp and Li (1986a) is used as a measure of gene expression to investigate the importance of this factor. It is found that Ikemura's rules successfully predict preferred codons for yeast, but that two of them work less well for E. coli, and it is suggested that some of the apparent bias in weakly expressed genes of E. coli may be due to contextual effects on mutation rates.     

An evolutionary perspective on synonymous codon usage in unicellular organisms

Summary Observed patterns of synonymous codon usage are explained in terms of the joint effects of mutation, selection, and random drift. Examination of the codon usage in 165Escherichia coli genes reveals a consistent trend of increasing bias with increasing gene expression level. Selection on codon usage appears to be unidirectional, so that the pattern seen in lowly expressed genes is best explained in terms of an absence of strong selection. A measure of directional synonymous-codon usage bias, the Codon Adaptation Index, has been developed. In enterobacteria, rates of synonymous substitution are seen to vary greatly among genes, and genes with a high codon bias evolve more slowly. A theoretical study shows that the patterns of extreme codon bias observed for someE. coli (and yeast) genes can be generated by rather small selective differences. The relative plausibilities of various theoretical models for explaining nonrandom codon usage are discussed.Presented at the FEBS Symposium on Genome Organization and Evolution, held in Crete, Greece, September 1–5, 1986