适应性突变的遗传学特征

基于大肠杆菌FC40菌株的研究结果表明,适应性突变依赖RecBCD重组途径的酶,要求SOS反应的部分基因功能,lac+回复突变序列都是在单核苷酸短重复序列处的一个碱基缺失。有证据表明有的适应性突变来自一个或多个暂时性的超突变的细胞亚群,它们的基因组发生大量的突变,转座子高频丢失。产生这种暂时性的超突变的增变子可能是因为细胞的MMR活性暂时不足,或是因错误翻译产生丧失了校读活性的DNA聚合酶III。其他一些研究系统虽然得到了一些同FC40菌株不一致的结论,但所有实验证据都表明,在饥饿等环境胁迫因子作用下,非生长或缓慢生长的细胞可以产生突变,这种突变具有生长依赖的自发突变所不同的一些遗传学特征。 Abstract:The research based on the Escherichia coli FC40 showed that adaptive mutations required the enzymes of RecBCD recombination pathway and some unknown proteins of SOS response,and the mutation spectrum of lac+ revertants is single-base deletions in the small mononucleotide repeats.Some evidence showed that the revertants with adaptive mutations partly come from one (or some) subset of transient hypermutable subpopulation of cells,in which high frequently losing of transposons and genome-wide mutations were observed.It was suggested that this kind of transient hypermutability may be due to the transient deficient activity of mismatch repair (MMR) system,or a defective epsilon unit of DNA polymerase III generated by mistranslation.Although other systems demonstrated some different mechanisms from FC40,all research works suggested that,adaptive mutations occurred in nondividing or nongrowing cells under environmental stresses,for example,starvation,displayed different genetic features from growth-dependent spontaneous mutation.     

酵母模型揭示胁迫因子驱动基因组变异的研究进展

基因组变异是遗传疾病发生和物种演化的分子基础,这个过程受到细胞内外源理化因子的共同作用。模式生物酿酒酵母（Saccharomyces cerevisiae）基因组小且易于开展分子遗传操作,在探究基因组变异进化调控机制的相关研究中应用广泛。本文总结了酵母模型中典型的DNA变异检测遗传体系,包括利用报告基因检测DNA突变率和红白扇形菌落筛选染色体重组子等;讨论了高通量测序技术在检测自发性和胁迫因子诱导基因组变异中的应用;综述了运用酵母模型揭示温度波动、氧化压力、抗肿瘤药物、金属离子和辐射等胁迫因子对基因组稳定性的影响及遗传机制的研究进展。酵母在多种胁迫条件下均会发生适应性进化现象,特定的染色体结构变异是适应性背后的重要遗传机制之一。在酵母中结合遗传筛选体系和高通量分析手段阐释细胞胁迫因子与基因组变异的关联机制,可为全面理解生物基因组不稳定机理和物种进化规律提供新的视角。     

超突变细胞在进化工程中的开发与应用

通过进化工程技术改造微生物细胞的生理表型是生物技术和生物炼制领域的重要研究方向,但是现阶段的各种进化工程技术面临效率低或连续性差的问题。超突变细胞能够进行自发、连续的胞内诱变,将其应用于进化工程技术能够实现连续、高效的菌种改造。本文详细介绍了自然界中超突变细胞产生的遗传机制和相应的人工超突变细胞的构建策略,以及应用此类超突变系统在微生物细胞生理性能改造和蛋白质突变体文库高效构建上取得的进展。随着相关领域认识和技术的加强,未来人工超突变细胞的构建将继续向着不同维度上可控性、靶向性不断提高的方向发展,从而为细胞和蛋白的改造提供更强更优的进化动力。     

基于复制-转录碰撞的突变和进化意义

复制和转录机器会同时使用相同的DNA区域作为模板,因此复制和转录不可避免地以头对头或追尾方式相互碰撞。头对头碰撞和追尾碰撞均会导致复制机器停留,从而造成DNA损伤和基因组不稳定。就基因组完整性而言,头对头碰撞比追尾碰撞的后果更严重。本文回顾总结了复制-转录冲突的解决机制和进化影响。相对于前导链,滞后链上非同义（氨基酸改变）突变的发生率更高,并且滞后链上基因的高频诱变取决于转录本和基因大小,因此,较快的适应性突变发生在滞后链上。头对头基因的高度转录增加了复制过程中响应压力的突变率。无论是头对头还是追尾模式,复制-转录冲突都可能是适应性进化的驱动力。     

寡核苷酸诱导的定点突变

蛋白质工程是生物技术中正在开发的一个新领域。由于它是一门从改变基因入手,制造新的蛋白质的技术学科,因此改变基因的方法就成为蛋白质工程的主要内容之一。 十年来由于重组基因和DNA序列分析方法得到成功,因此很多科学家的注意力都集中到研究DNA编码区域序列结构与功能的关系,发展了各种体内,体外突变方法。改变某一特定区域的DNA结构,用以确定DNA特定区域的功能。     

重金属胁迫下的细菌适应性进化研究进展

细菌进化的本质是碱基突变、基因重排或水平基因转移,在适应性进化过程中,主要受生物和非生物因素的影响,其中重金属胁迫也是细菌适应性进化的主要因素之一.重金属胁迫促使细菌适应性地强化与金属输入和转化有关的代谢途径,而过量的金属则诱导金属积累和外排过程.在重金属胁迫下,基于重金属抗性(HMR)基因和酶蛋白的适应,细菌抗性机制...     

重金属胁迫下的细菌适应性进化研究进展

细菌进化的本质是碱基突变、基因重排或水平基因转移,在适应性进化过程中,主要受生物和非生物因素的影响,其中重金属胁迫也是细菌适应性进化的主要因素之一。重金属胁迫促使细菌适应性地强化与金属输入和转化有关的代谢途径,而过量的金属则诱导金属积累和外排过程。在重金属胁迫下,基于重金属抗性(HMR)基因和酶蛋白的适应,细菌抗性机制亦发生适应性进化,整理和总结了包括隔离机制适应、金属调控蛋白调控机制适应及酶解毒机制适应方面的研究。目前,重金属离子已对环境造成严重污染,威胁人类健康和生态系统的稳定,因此,阐明重金属胁迫下的细菌适应性进化,不仅丰富了细菌进化研究的内容,而且为在复杂环境条件下实现重金属离子污染的微生物的修复提供了理论基础。     

植物DNA甲基化及胁迫诱导的变异

DNA中碱基的化学修饰近年来一直是生命科学领域研究的热点之一。DNA甲基化是一种常见的表观遗传现象,它能在不改变DNA序列的前提下改变遗传表型。各种胁迫因素能诱导植物DNA甲基化产生变异,但其应答胁迫机制仍然未知。本文对植物DNA甲基化研究进展进行了综述,结合本课题组的研究结果,对7Li离子束注入、~(60)CO-γ射线诱变诱导产生的DNA甲基化变异进行了报道,以期为DNA甲基化可能参与涉及植物的表型可塑性提供一定的依据。     

禽流感病毒H5N1血凝素基因适应性进化过程中的关键位点突变规律研究

目的:寻找导致禽流感病毒H5N1血凝素(HA)适应性进化的关键突变,建立氨基酸突变评价体系,对突变作用进行评估,印证它们与病毒适应性进化的关联性。方法:计算株频率和枝频率,寻找标记分枝,向根结点回溯寻找HA进化路径上的氨基酸突变。计算各突变位点氨基酸的频率变化、有效变换及高频次突变,基于以上几个因素建立突变评价体系。结果:建立了大规模自动化寻找突变的方法,计算得到HA进化过程中的氨基酸突变435个,通过氨基酸频率图表分析这些突变可以很好地反映病毒适应性进化过程,其中79个突变是有效变换,发生的位点为正选择位点,且多数位点落在HA抗原表位上;29个突变是高频次突变,其中多数也为有效变换,因而与病毒适应性进化密切相关。结论:大规模自动化寻找突变的方法可靠,建立的突变评价体系准确性高,找到的关键突变及位点对实验有很好的指导意义。     

基于生态系统演变机理的生态系统脆弱性、适应性与突变理论

随着气候变化影响广度与深度的增加,生态系统脆弱性、适应性与突变理论逐渐被广泛应用到生态学研究领域中,探讨和评估各类生态系统对气候变化的敏感性、脆弱性和适应性,可谋求更好的方式来应对气候变化对区域生态系统带来的深远影响,服务于国家生态系统可持续管理及生态安全建设.虽然相关研究已获取许多进展,区分了气候敏感区和某些生态系统...     

Stress-induced mutagenesis and complex adaptation

Because mutations are mostly deleterious, mutation rates should be reduced by natural selection. However, mutations also provide the raw material for adaptation. Therefore, evolutionary theory suggests that the mutation rate must balance between adaptability—the ability to adapt—and adaptedness—the ability to remain adapted. We model an asexual population crossing a fitness valley and analyse the rate of complex adaptation with and without stress-induced mutagenesis (SIM)—the increase of mutation rates in response to stress or maladaptation. We show that SIM increases the rate of complex adaptation without reducing the population mean fitness, thus breaking the evolutionary trade-off between adaptability and adaptedness. Our theoretical results support the hypothesis that SIM promotes adaptation and provide quantitative predictions of the rate of complex adaptation with different mutational strategies.     

Sectorial mutagenesis by transposable elements

Transposable elements (TEs) generate insertions and cause other mutations in the genomic DNA. It is proposed that during co-evolution between TEs and eukaryotic genomes, an optimal path of the insertion mutagenesis is determined by the surviving TEs. These TEs can become semi-permanently established, chromatin-regulated ‘source’ or ‘mutator genes’, responsible for targeting insertion mutations to specific chromosomal regions. Such mutations can manifest themselves in non-random distribution patterns of interspersed repeats in eukaryotic chromosomes. In this paper we discuss specific models, examples and implications of optimized mutagenesis in eukaryotes. This revised version was published online in July 2006 with corrections to the Cover Date.     

DNA polymerases are error-prone at RecA-mediated recombination intermediates

Genetic studies have suggested that Y-family translesion DNA polymerase IV (DinB) performs error-prone recombination-directed replication (RDR) under conditions of stress due to its ability to promote mutations during double-strand break (DSB) repair in growth-limited E. coli cells. In recent studies we have demonstrated that pol IV is preferentially recruited to D-loop recombination intermediates at stress-induced concentrations and is highly mutagenic during RDR in vitro. These findings verify longstanding genetic data that have implicated pol IV in promoting stress-induced mutagenesis at D-loops. In this Extra View, we demonstrate the surprising finding that A-family pol I, which normally exhibits high-fidelity DNA synthesis, is highly error-prone at D-loops like pol IV. These findings indicate that DNA polymerases are intrinsically error-prone at RecA-mediated D-loops and suggest that auxiliary factors are necessary for suppressing mutations during RDR in non-stressed proliferating cells.     

Efficient site-directed saturation mutagenesis using degenerate oligonucleotides.

We describe a reliable protocol for constructing single-site saturation mutagenesis libraries consisting of all 20 naturally occurring amino acids at a specific site within a protein. Such libraries are useful for structure-function studies and directed evolution. This protocol extends the utility of Stratagene's QuikChange Site-Directed Mutagenesis Kit, which is primarily recommended for single amino acid substitutions. Two complementary primers are synthesized, containing a degenerate mixture of the four bases at the three positions of the selected codon. These primers are added to starting plasmid template and thermal cycled to produce mutant DNA molecules, which are subsequently transformed into competent bacteria. The protocol does not require purification of mutagenic oligonucleotides or PCR products. This reduces both the cost and turnaround time in high-throughput directed evolution applications. We have utilized this protocol to generate over 200 site-saturation libraries in a DNA polymerase, with a success rate of greater than 95%.     

Stationary-state mutagenesis inEscherichia coli: A model

Stationary-phase mutagenesis in nondividingE. coli cells exposed to a nonlethal stress was, a few years ago, claimed to be a likely case of a Lamarckian mechanism capable of producing exclusively useful mutations in a directed manner. After a heated debate over the last decade it now appears to involve a Darwinian mechanism that generates a transient state of hypermutagenesis, operating on a large number of sites spread over the entire genome, at least in a proportion of the resting cells. Most of the studies that clarified this position were on the reversion of a frameshift mutation present in alacI-lacZ fusion inE. coli strain FC40. Several groups have extensively examined both the sequence changes associated with these reversions and the underlying genetic requirements. On the basis of our studies on the genomic sequence analysis, we recently proposed a model to explain the specific changes associated with the reversion hotspots. Here we propose a more detailed version of this model that also takes into account the observed genetic requirements of stationary-state mutagenesis. Briefly, G:T/U mismatches produced at methylatable cytosines are preferentially repaired in nondividing cells by the very short patch mismatch repair (VSPMR) mechanism which is itself mutagenic and can produce mutations in very short stretches located in the immediate vicinity of these cytosine methylation sites. This mechanism requires a homologous or homeologous strand invasion step and an error-prone DNA synthesis step and is dependent on RecA, RecBCD and a DNA polymerase. The process is initiated near sequences recognized by Dcm and Vsr enzymes and further stimulated if these sequences are a part of CHI or CHI-like sequences, but a double-strand-break-dependent recombination mediated by the RecBCD pathways proposed by others seems to be nonessential. The strand transfer step is proposed to depend on RecA, RuvA, RuvB and RuvC and is opposed by RecG and MutS. The model also gives interesting insights into the evolution of theE. coli genome.     

How environmental factors regulate mutagenesis and gene transfer in microorganisms

This review is focused on the physiological and evolutionary strategies of the processes occurring during the entry of microbial cells into stationary phase and the subsequent period of stasis. The molecular mechanisms adapting microorganisms from exponential growth to a static state involve activation and complex regulation of the stationary factor Sigma-S, which directs RNA polymerase to the specific promoters. As a result the static cells acquire general resistance (simultaneous tolerances) to different environmental stresses. In parallel with the physiological adaptation to stasis, diverse genetical processes are aimed towards resuming the growth of the static cells. Different types of mutagenesis occur: (i) in cells entering stasis and (ii) in static cells (adaptive mutagenesis). Cessation of growth induces the transient hypermutator state resulting in the accumulation of random mutations in the subpopulation of the static cells. If by chance, one or a few of such mutations lead to resumption of division, the growing cell will return to a normal mechanism of spontaneous mutagenesis. Another mechanism for generating genetical variability in stressed cells involves transposons and conjugative plasmids. Stresses can stimulate the excision of some transposons, which, in turn, can generate chromosomal mutations and activate intracellular mechanisms of mutagenesis. Under stress some conjugative plasmids activate genes encoding antirestriction proteins that repress restriction-modification systems of the recipient cells. Moreover, under stress special cellular mechanisms decrease (alleviate) the activity of restriction-modification systems which, in turn, enhance the probability of gene transfer into the stressed cells. Under stress, the efficiency of inter-species genetical barriers also decreases. This, stimulates inter-species gene transfer and may lead to a burst of incipient speciation in the population of non-growing cells. After resumption of growth the genetical barriers leading to isolation will be restored. In general, the cessation of growth “switches on”, and resumption of growth “switches off”, a set of special processes that are responsible for generating bursts of genetical variability in populations of microorganisms. This article is dedicated to the memory of Nikolai V Timofeev-Ressovsky (1900–1981).     

Transversion-enriched sequence saturation mutagenesis (SeSaM-Tv+): a random mutagenesis method with consecutive nucleotide exchanges that complements the bias of error-prone PCR

The sequence saturation mutagenesis (SeSaM) method has been advanced to a random mutagenesis method with adjustable mutational biases. SeSaM offers, for example, a bias that is complementary to error-prone (ep) PCR and is enriched in transversions (SeSaM-Tv(+)). dNTP alpha S and three degenerate bases (P, K and I) are used to control mutational bias flexibly. After quantifying incorporation rates of dPTP, dKTP and dITP by terminal transferase using a luciferase-based assay and investigating the read and/or write activities of eight DNA polymerases, a transversion-enriched protocol has been developed. In a mutant library generated using dGTP alpha S and dPTP, transversion frequencies of 16.22-22.58% (G-->T) and 6.38-9.69% (G-->C) were achieved. These mutational spectra are complementary and occur twice as frequently in comparison to standard epPCR methods employing Taq DNA polymerase. For generating more complex mutant libraries, the occurrence of consecutive nucleotide exchanges was increased by 10(5)-10(6)-fold compared to epPCR. Finally, 16.7% of all sequenced mutants contained consecutive nucleotide exchanges composed mainly of a transversion followed by a transition.     

高等植物胁迫诱导型启动子的研究进展

逆境胁迫严重影响植物生长发育,降低作物产量。目前在植物抗逆基因工程中,大多使用组成型启动子驱动目的基因表达,组成型启动子的表达虽然能提高转基因植株的抗逆性,但持续过量地表达转化的外源基因有时会阻碍植物的生长且降低其产量。因此,诱导型启动子的研究具有重要的应用价值。该文对近年来植物在逆境胁迫处理下,一些诱导型启动子的种类和功能,可能具有的顺式作用元件,反式作用因子及其研究方法进行了综述。