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。     

葡萄基因组密码子使用偏好模式研究

根据完整基因组序列,运用多元统计分析和对应分析的方法,探讨了葡萄全基因组序列密码子的使用模式和影响密码子使用的各种可能因素。结果显示:葡萄密码子偏好性主要受到碱基差异(r=0.925)和自然选择(r=0.193)共同作用的影响,突变压力占了主导因素,自然选择的作用较小。同时基因长度和蛋白质疏水性也对密码子的偏好性有所影响。确定了葡萄的20个最优密码子。     

影响鼻疽伯克霍尔德氏菌基因组密码子用法的因素分析

鼻疽伯克霍尔德氏菌(Burkholderia mallei ATCC 23344)的基因组密码子使用受多种因素的影响,本研究根据该菌的完整基因组序列,运用多元统计分析和对应分析的方法,探讨了鼻疽伯克霍尔德氏菌全基因组序列密码子的使用模式和影响密码子使用的因素。结果表明基因表达水平的高低是影响密码子使用的主要因素;基因组中编码区的碱基组成、蛋白质的疏水性和基因的长度对密码子的使用也有一定的影响,但影响力不及基因的表达水平。同时,通过比较高表达的基因、低表达的基因密码子使用情况,GCG 和 CUC 等 21 个密码子被确定为鼻疽伯克霍尔德氏菌的主要偏爱密码子。以上结果对鼻疽伯克霍尔德氏菌的密码子用法研究、在分子水平上研究物种进化、基因组中未知基因的预测、开放阅读框的判断、功能基因的表达以及鼻疽病疫苗的研发等工作都提供了理论基础,具有较强的指导作用。     

人类1号、X、Y染色体基因密码子偏好性研究

随着人类基因组计划测序工作的完成,进一步数据挖掘工作已成为新的研究热点。根据人类1号、X、Y染色体数据,通过自编的Perl程序,提取3条染色体基因的CDS序列,利用密码子偏好性的理论及生物信息学方法分析其碱基组成特点和密码子使用模式,确定了偏好密码子和最优密码子,探讨影响其密码子用法的主要因素。结果表明:1)人类1号、X、Y染色体基因偏好使用以G或C结尾的密码子;2)密码子的使用受基因长度的影响,较长的基因具有较高的表达水平和密码子使用偏性;3)基因表达水平对人类1号、X、Y染色体基因的密码子使用没有影响,暗示了这3条染色体并未承受翻译选择的压力;4)人类1号、X、Y染色体基因共有32个偏好性密码子,其中编码Arg的AGG和AGA、编码Val的GTG、编码Leu的CTG、终止密码子TAG为最优密码子。     

普通野生稻线粒体蛋白质编码基因密码子使用偏好性的分析

以普通野生稻(Oryza rufipogon Griff.)线粒体基因组为对象,分析其蛋白质编码基因的密码子使用特征及与亚洲栽培稻(O. sativa L.)的差异,探讨其密码子偏性形成的影响因素和进化过程。结果显示:普通野生稻线粒体基因组编码序列第1、第2和第3位碱基的GC含量依次为49.18%、42.67%和40.86%;有效密码子数(Nc)分布于45.32～61.00之间,其密码子偏性较弱; Nc值仅与GC_3呈显著相关,密码子第3位的碱基组成对密码子偏性影响较大;第1向量轴上显示9.91%的差异,其与GC_3s、Nc、密码子偏好指数(CBI)和最优密码子使用频率(Fop)的相关性均达到显著水平;而GC_3和GC₁₂的相关性未达到显著水平。因此,普通野生稻线粒体基因组密码子的使用偏性主要受自然选择压力影响而形成。本研究确定了21个普通野生稻线粒体基因组的最优密码子,大多以A或T结尾,与叶绿体密码子具有趋同进化,但是与核基因组具有不同的偏好性。同义密码子相对使用度(RSCU)、PR2偏倚分析和中性绘图分析显示,普通野生稻线粒体基因功能和其密码子使用密切相关,且线粒体密码子使用在普通野生稻、粳稻(O. sativa L. subsp. japonica Kato)和籼稻(O. sativa L. subsp.indica Kato)内具有同质性。     

樟树叶绿体基因组密码子偏好性分析

为分析樟树(Cinnamomum camphora)叶绿体基因组密码子偏好性使用模式,该研究利用CodonW、EMBOSS、R语言等软件和程序,对53条樟树叶绿体基因组密码子使用模式及偏好性进行了系统分析。结果表明:樟树叶绿体基因的有效密码子数(ENC)在36.82～59.30之间,表明密码子的偏好性较弱。相对同义密码子使用度(RSCU)分析发现RSCU>1的密码子有32个,其中28个以A、U结尾,表明第3位密码子偏好使用A和U碱基。中性绘图分析发现GC₃与GC₁₂的相关性不显著,回归曲线斜率为0.049,说明密码子偏好性主要受到自然选择的影响。ENC-plot分析发现大部分基因落在曲线的下方,同样表明选择是影响密码子偏好性的主要因素。该研究发现共有9个密码子(UUU、CUU、UCA、ACA、UAU、AAU、GAU、UGA、GGA)被鉴定为樟树叶绿体基因组的最优密码子。     

紫花苜蓿叶绿体基因组密码子偏好性分析

为分析紫花苜蓿叶绿体基因组密码子偏好性的使用模式,该文以紫花苜蓿叶绿体基因组中筛选到的49条蛋白质编码序列为研究对象,利用CodonW、CUSP、CHIPS、SPSS等软件对其密码子的使用模式和偏好性进行研究。结果表明:(1)紫花苜蓿叶绿体基因的第3位密码子的平均GC含量为26.44%,有效密码子数(ENC)在40.6～51.41之间,多数密码子的偏好性较弱。(2)相对同义密码子使用度(RSCU)分析发现,RSCU>1 的密码子数目有30个,以A、U结尾的有29个,说明了紫花苜蓿叶绿体基因组A或U出现的频率较高。(3)中性分析发现,GC3与 GC12的相关性不显著,表明密码子偏性主要受自然选择的影响; ENC-plot 分析发现一部分基因落在曲线的下方及周围,表明突变也影响了部分密码子偏性的形成。此外,有17个密码子被鉴定为紫花苜蓿叶绿体基因组的最优密码子。紫花苜蓿叶绿体基因组的密码子偏好性可能受自然选择和突变的共同作用。该研究将为紫花苜蓿叶绿体基因工程的开展和目标性状的遗传改良奠定基础。     

普通野生稻线粒体蛋白质编码基因密码子使用偏好性的分析

以普通野生稻（Oryza rufipogon Griff.）线粒体基因组为对象,分析其蛋白质编码基因的密码子使用特征及与亚洲栽培稻（O.sativa L.）的差异,探讨其密码子偏性形成的影响因素和进化过程。结果显示：普通野生稻线粒体基因组编码序列第1、第2和第3位碱基的GC含量依次为49.18%、42.67%和40.86%;有效密码子数（Nc）分布于45.32~61.00之间,其密码子偏性较弱;Nc值仅与GC₃呈显著相关,密码子第3位的碱基组成对密码子偏性影响较大;第1向量轴上显示9.91%的差异,其与GC_3s、Nc、密码子偏好指数（CBI）和最优密码子使用频率（Fop）的相关性均达到显著水平;而GC₃和GC₁₂的相关性未达到显著水平。因此,普通野生稻线粒体基因组密码子的使用偏性主要受自然选择压力影响而形成。本研究确定了21个普通野生稻线粒体基因组的最优密码子,大多以A或T结尾,与叶绿体密码子具有趋同进化,但是与核基因组具有不同的偏好性。同义密码子相对使用度（RSCU）、PR2偏倚分析和中性绘图分析显示,普通野生稻线粒体基因功能和其密码子使用密切相关,且线粒体密码子使用在普通野生稻、粳稻（O.sativa L.subsp.japonica Kato）和籼稻（O.sativa L.subsp.indica Kato）内具有同质性。     

影响链球菌属肺炎球菌基因组密码子使用的因素分析

链球菌属肺炎球菌（Steptococcus pneumoniae)的完整基因组序列已经测定完毕并于近期发表,对肺炎球菌基因组序列进行了详细分析,研究了基因组密码子的使用模式和影响密码子使用的因素,高水平高达基因的密码子第三位碱基使用胞嘧啶（C）的频率比表达水平低的基因使用C有显著的提高,表达水平较低的基因在密码子的第三位碱基更趋向使用嘌呤）,基因的表达水平与对应分析的第一条向量轴呈显著相关（R＝0．86）,比较表达水平高,低的两组基因的密码子使用模式发现,基因的表达水平对于密码子使用有显著的影响,基因碱基G＋C的组成与基因的表达水平（R＝0．44）,对应分析的第一条向量轴（R＝0．5）有显著的相关,对基因的表达水平,密码子的使用有显著的影响,通过GC－skew,蛋白质的疏水性,基因的长度分析,发现不同长度的基因表达水平,GC含量,GC3s有差异,结果表明,在表达水平上的自然选择以及基因的碱基组成是影响肺炎球菌基因密码子使用的主要因素,基因的长度对密码子的使用有一定影响。     

Wolbachia pipientis wMel基因组水平上的密码子使用分析

本实验检测了黑腹果蝇的专性寄生菌Wolbachia pipientis wMel基因组的密码子使用模式,并推测影响其密码子组成的因素．选择了478条蛋白编码基因作为研究对象,它们的GC含量比较低,约0．282～0．432．本研究结果显示,关联突变（context-dependent mutation）是影响W.pipientis wMel基因组密码子组成的主要因素．同时,Nc—Plot曲线显示,基因组的密码子组成还受到了核苷酸组成偏好性（nucleotide composition bias）的影响．对应分析的结果显示,基因长度（R=0．123,P〈0．01）和基因表达水平（R=-0．312,P〈0．01）也对基因组的密码子使用偏好性起到了一定的作用．因此,关联突变、核苷酸组成、基因长度和基因表达水平都会影响到基因组的密码子使用偏好性．Wolbachia基因组的几个特征和动物线粒体基因组具有较高的相似性,而且现在已有报道说明它们有共同的起源,但仍需进一步验证．     

人类基因同义密码子偏好的特征以及与基因GC含量的关系

对人类的728个基因,按其编码区中GC的含量分成四组(从GC＜0.43到GC＞0.58),分别考察了这四组样本对同义密码子偏好的特征,发现在全部样本中都呈现NTG(N代表四种碱基中的任一种)特受偏爱和NCG尽量避免的特征.基因环境中GC含量与C3/G3含量(密码子第三位C和G的含量)的相关分析,以及四组样本对密码子的偏好都支持以C结尾的密码子在编码中有特殊的优势,这种优势有利于保证翻译的准确性.还考察了各种氨基酸含量随编码区GC含量不同而变化的趋势.     

Evolution of the Genetic Triplet Code via Two Types of Doublet Codons

Explaining the apparent non-random codon distribution and the nature and number of amino acids in the ‘standard’ genetic code remains a challenge, despite the various hypotheses so far proposed. In this paper we propose a simple new hypothesis for code evolution involving a progression from singlet to doublet to triplet codons with a reading mechanism that moves three bases each step. We suggest that triplet codons gradually evolved from two types of ambiguous doublet codons, those in which the first two bases of each three-base window were read (‘prefix’ codons) and those in which the last two bases of each window were read (‘suffix’ codons). This hypothesis explains multiple features of the genetic code such as the origin of the pattern of four-fold degenerate and two-fold degenerate triplet codons, the origin of its error minimising properties, and why there are only 20 amino acids. Reviewing Editor: Dr. Laura Landweber An erratum to this article can be found at .     

Selection pressures on codon usage in the complete genome of bacteriophage T7

Summary We searched the complete 39,936 base DNA sequence of bacteriophage T7 for nonrandomness that might be attributed to natural selection. Codon usage in the 50 genes of T7 is nonrandom, both over the whole code and among groups of synonymous codons. There is a great excess of purineany base-pyrimidine (RNY) codons. Codon usage varies between genes, but from the pooled data for the whole genome (12,145 codons) certain putative selective constraints can be identified. Codon usage appears to be influenced by host tRNA abundance (particularly in highly expressed genes), tRNA-mRNA interactions (one such interaction being perhaps responsible for maintaining the excess of RNY codons) and a lack of short palindromes. This last constraint is probably due to selection against host restriction enzyme recognition sites; this is the first report of an effect of this kind on codon usage. Selection against susceptibility to mutational damage does not appear to have been involved.     

Evolution of the mitochondrial genetic code I. Origin of AGR serine and stop codons in metazoan mitochondria

Summary AGA and AGG (AGR) are arginine codons in the universal genetic code. These codons are read as serine or are used as stop codons in metazoan mitochondria. The arginine residues coded by AGR in yeast orTrypanosoma are coded by arginine CGN throughout metazoan mitochondria. AGR serine sites in metazoan mitochondria are occupied mainly in corresponding sites in yeast orTrypanosoma mitochondria by UCN serine, AGY serine, or codons for amino acids other than serine or arginine. Based on these observations, we propose the following evolutionary events. AGR codons became unassigned because of deletion of tRNA Arg (UCU) and elimination of AGR codons by conversion to CGN arginine codons. Upon acquisition by serine tRNA of pairing ability with AGR codons, some codons for amino acids other than arginine mutated to AGR, and were caputed by anticodon GCU in serine tRNA. During vertebrate mitochondrial evolution, AGR stop codons presumably were created from UAG stop by deletion of the first nucleotide U and by use of R as the third nucleotide that had existed next to the ancestral UAG stop.     

Recognizing shorter coding regions of human genes based on the statistics of stop codons.

With the quick progress of the Human Genome Project, a great amount of uncharacterized DNA sequences needs to be annotated copiously by better algorithms. Recognizing shorter coding sequences of human genes is one of the most important problems in gene recognition, which is not yet completely solved. This paper is devoted to solving the issue using a new method. The distributions of the three stop codons, i.e., TAA, TAG and TGA, in three phases along coding, noncoding, and intergenic sequences are studied in detail. Using the obtained distributions and other coding measures, a new algorithm for the recognition of shorter coding sequences of human genes is developed. The accuracy of the algorithm is tested based on a larger database of human genes. It is found that the average accuracy achieved is as high as 92.1% for the sequences with length of 192 base pairs, which is confirmed by sixfold cross-validation tests. It is hoped that by incorporating the present method with some existing algorithms, the accuracy for identifying human genes from unannotated sequences would be increased.     

Mutations affecting translation of the bacteriophage T4 rIIB gene cloned in Escherichia coli

Summary Mutant ribosome binding sites of the bacteriophage T4 rIIB gene, resident on an 873 bp DNA fragment, were cloned into a plasmid vector as in-frame fusions to a reporter gene, beta-galactosidase. The collection of mutations included changes in the region 5 to the Shine/Dalgarno sequence, a mutation of the Shine/Dalgarno sequence, the alternate initiation codons GUG, AUA and ACG, and mutants in which several closely spaced initiation codons compete with each other on the same mRNA. The results show that the secondary structure variations we have installed 5 to the Shine/Dalgarno sequence have little effect on translation. GUG is essentially as good an initiator of translation as AUG when they are assayed on separate messages, but is outcompeted at least 50-fold in the sequence AUGUG. AUA and ACG are poor start codons, and are temperature sensitive. The initiation codon pair AUGAUA, in which the AUG is only two nucleotides from the Shine/Dalgarno sequence, displays a novel cold-sensitive phenotype.     

The close proximity ofEscherichia coli genes: Consequences for stop codon and synonymous codon use

It is shown that synonymous codon usage is less biased in favor of those codons preferred by highly expressed genes at the end ofEscherichia coli genes than in the middle. This appears to be due to the close proximity of manyE. coli genes. It is shown that a substantial number of genes overlap either the Shine-Dalgarno sequence or the coding sequence of the next gene on the chromosome and that the codons that overlap have lower synonymous codon bias than those which do not. It is also shown that there is an increase in the frequency of A-ending codons, and a decrease in the frequency of G-ending codons at the end ofE. coli genes that lie close to another gene. It is suggested that these trends in composition could be associated with selection against the formation of mRNA secondary structure near the start of the next gene on the chromosome. Stop codon use is also affected by the close proximity of genes; many genes are forced to use TGA and TAG stop codons because they terminate either within the Shine-Dalgarno or coding sequence of the next gene on the chromosome. The implications these results have for the evolution of synonymous codon use are discussed.     

Cytoplasmic mRNA for human triosephosphate isomerase is immune to nonsense-mediated decay despite forming polysomes

Nonsense codons between position 14 within the first exon and position 193 within the penultimate exon of the human gene for triosephosphate isomerase reduce mRNA abundance to 25% of normal. The reduction in abundance is due to the decay of newly synthesized mRNA that copurifies with nuclei. TPI mRNA that copurifies with cytoplasm is immune to decay. We show here that immunity is not due to the failure of nonsense-containing mRNA to form polysomes. This finding indicates that cytoplasmic mRNA, in contrast to nucleus-associated mRNA, may have lost one or more factors that are required for nonsense-mediated decay or gained one or more factors that confer immunity to nonsense-mediated decay.     

Studies on FGF-2: Nuclear localization and function of high molecular weight forms and receptor binding in the absence of heparin

Multiple forms of FGF-2 have been shown to exist in many cell types. These different species of molecular masses of 18, 21.5, 22, and 24 kDa are all translated via the use of alternate initiation codons. The three forms of HMW FGF-2 initiate at CUGs codons, whereas the 18 kDa form initiates at an AUG codon. The entire 18 kDa sequence is contained within the larger forms of HMW FGF-2 as the AUG codon is 3′ to the CUG codons. Although the 18 kDa form FGF-2 is localized primarily in the cytosol, a significant fraction of the HMW FGF-2 has a nuclear location. The nuclear localization of HMW FGF-2 is determined by amino acid residues in the amino-terminal extended sequence. The residues required for nuclear localization appear to be RG repeats that are found at multiple sites within the amino-terminal extension of HMW FGF-2. The nuclear localization of HMW FGF-2 suggested that these species may have unique properties. By selecting permanent transfectants of 3T3 cells expressing HMW, 18 kDa FGF-2, or all forms of FGF-2, we have found that HMW FGF-2 can endow cells with a phenotype different from that of cells expressing 18 kDa FGF-2. These cells are transformed by what appears to be the intracellular action of HMW FGF-2. The interaction of FGF-2 with heparin has also been examined. Contrary to other reports claiming that FGF-2 required heparin or heparan-sulfate for interaction with its high-affinity receptor, we have found that FGF-2 binds to its receptor in the absence of glycosaminoglycans, and that this binding activates the receptor. © 1994 Wiley-Liss, Inc.     

Unusual codon usage bias in low expression genes of Vibrio cholerae

Positive correlation between gene expression and synonymous codon usage bias is well documented in the literature. However, in the present study of Vibrio cholerae genome, we have identified a group of genes having unusually high codon usage bias despite being low potential expressivity. Our results suggest that codon usage in lowly expressed genes might also be selected on to preferably use non-optimal codons to maintain a low cellular concentration of the proteins that they encode. This would predict that lowly expressed genes are also biased in codon usage, but in a way that is opposite to the bias of highly expressed genes.