分子遗传标记技术及其在昆虫科学中的应用

分子遗传标记是随着聚合酶链式反应 (PCR)和Southern杂交等分子生物学技术的飞速发展而出现的遗传学标记技术 ,它突破了以往形态标记 ,细胞学标记和同工酶标记等表达型标记的局限性 ,在揭示物种的遗传变异性研究中发挥着独特的优势。分子遗传标记目前已出现了几十种 ,可依其涉及的位点和反映的多态性的基础分为多位点分子标记和单位点分子标记 ,多位点分子标记反映核苷酸序列的多态性 ,单位点分子标记反映基因座上等位基因的多态性。本文对一些常用的分子标记技术的特点和它们在昆虫系统进化、昆虫分类、昆虫生态、生物防治和特定基因标记等研究中的应用作了介绍。     

Molecular genotyping of Sclerotinia sclerotiorum isolates from different regions and host plants in Iran

Genetic variation among Sclerotinia sclerotiorum isolates from different regions and host plants were investigated using pathogenicity test, mycelial compatibility groups (MCGs) and molecular markers. Six MCGs were identified and significant differences of virulence variability were observed within and among MCGs. Cluster analysis of combined repetitive sequence-based polymerase chain reaction and randomly amplified polymorphic DNA data discriminated 12 isolates into 11 genotypes, indicating high level of genetic polymorphism among tested isolates. Twelve isolates clustered into four major groups corresponding to their hosts andgeographical region. The variability found within closely related isolates of S.sclerotiorum indicated that such morphological and molecular markers are useful in population studies of this pathogen.     

Evaluation of the internal transcribed spacer 2 (ITS2) as a molecular marker for phylogenetic inference using sequence and secondary structure information in blow flies (Diptera: Calliphoridae)

The internal transcribed spacer 2 (ITS2) is a small non-coding region located inside the nuclear ribosomal DNA cluster. ITS2 sequence variability is thought to be appropriate to differentiate species and for phylogenetic reconstructions analyses, which can be further improved if structural information is considered. We evaluated the potential of ITS2 as a molecular marker for phylogenetic inference in Calliphoridae (Diptera: Brachycera) using a broad range of inference methods and different substitution models, accounting or not for structural information. Sequence analyses revealed a hierarchically organized pattern of sequence variation and a small level of nucleotide substitution saturation. Intragenomic variation due to small sequence repeats was found mainly in the most variable domain (IV), but it has no significant impact on the phylogenetic signal at the species level. Inferred secondary structures revealed that GC pairs are more frequently found flanking bulges and loops regions in more conserved domains, thus ensuring structure stability. In the phylogenetic analyses, the use of substitution models accounting for structural information significantly improves phylogenetic inference in both neighbour-joining and Bayesian analyses, although the former provides limited resolution for dealing with highly divergent sequences. For Bayesian analyses, a significant improvement in likelihood was observed when considering structure information, although with small changes in topology and overall support, probably reflecting better evolutionary rates estimates. Based on these findings, ITS2 is a suitable molecular marker for phylogenetic analyses in Calliphoridae, at both species and generic level.     

Studying plant genome variation using molecular markers

The authors' studies on the organization and variation of plant genome with the use of molecular markers are briefly reviewed with special emphasis on random amplified polymorphic DNA (RAPD), inter simple sequence repeat (ISSR), sequence characterized amplified region (SCAR), and cleaved amplified polymorphic sequence (CAPS) markers detected with the use of polymerase chain reaction (PCR). These markers have been demonstrated to be promising for identifying cultivars and determining the purity of genetic strains of pea. Genetic relationships between strains, cultivars, and mutants of pea have been studied. The role of molecular markers in molecular genetic mapping and localizing the genes of commercially important characters of pea has been shown. The possibility of the use of molecular markers for studying somaclonal variation and detecting mutagenic factors in plants during long-term spaceflights is considered. The prospects of using DNA markers for understanding the organization and variability of higher plant genomes are discussed.     

Genetic variation: molecular mechanisms and impact on microbial evolution

On the basis of established knowledge of microbial genetics one can distinguish three major natural strategies in the spontaneous generation of genetic variations in bacteria. These strategies are: (1) small local changes in the nucleotide sequence of the genome, (2) intragenomic reshuffling of segments of genomic sequences and (3) the acquisition of DNA sequences from another organism. The three general strategies differ in the quality of their contribution to microbial evolution. Besides a number of non-genetic factors, various specific gene products are involved in the generation of genetic variation and in the modulation of the frequency of genetic variation. The underlying genes are called evolution genes. They act for the benefit of the biological evolution of populations as opposed to the action of housekeeping genes and accessory genes which are for the benefit of individuals. Examples of evolution genes acting as variation generators are found in the transposition of mobile genetic elements and in so-called site-specific recombination systems. DNA repair systems and restriction-modification systems are examples of modulators of the frequency of genetic variation. The involvement of bacterial viruses and of plasmids in DNA reshuffling and in horizontal gene transfer is a hint for their evolutionary functions. Evolution genes are thought to undergo biological evolution themselves, but natural selection for their functions is indirect, at the level of populations, and is called second-order selection. In spite of an involvement of gene products in the generation of genetic variations, evolution genes do not programmatically direct evolution towards a specific goal. Rather, a steady interplay between natural selection and mixed populations of genetic variants gives microbial evolution its direction.     

分子标记技术在昆虫入侵研究中的应用

遗传变异与种群持续性及其进化潜力密切相关,而生物入侵导致种群遗传变异或遗传多样性的改变为研究自然界中各种生态和进化问题提供了理想模式。分子标记技术是调查种群遗传变异的重要工具,揭示了入侵种的入侵过程和结果,并预测未来的发生情况。本综述归纳了分子标记技术在昆虫入侵机制研究中的应用,以典型的研究个案为例,分别综述了分子标记技术在隐蔽入侵的监测应用,分子标记技术在重构入侵历史研究中的推算方式,分子标记技术在探索种群遗传变异与成功入侵机制方面取得的重要进展,并进一步介绍了高分辨率熔解曲线（high-resolution melting, HRM）分析在昆虫入侵研究中的应用前景。     

Polymorphic molecular markers from anonymous nuclear DNA for genetic analysis of populations

A simple method is presented for developing polymorphic, anonymous DNA markers suitable for population genetic studies. Anonymous DNA fragments are screened for sequence variability using a common mutation detection technique (single strand conformation polymorphism analysis; SSCP) and locus-specific PCR primers are designed for polymorphic DNA fragments. Detection of the markers by SSCP analysis coupled with sequence analysis of SSCP variants allows rapid screening while retaining information about the genealogical relationship among alleles. Variability detected for six markers was assessed in rainbow trout Oncorhynchus mykiss and was compared with variability detected by similar analysis of intron loci. Between three and 12 distinct alleles were observed at each marker locus, and average within-population heterozygosity ranged from 0.12 to 0.44. Advantages and limitations of the methodology for population genetic analysis are discussed.     

Optimization of single-strand conformation polymorphism and sequence analysis of the mitochondrial control region in Pagellus bogaraveo (Sparidae, Teleostei): rationalized tools in fish population biology

We report the isolation and sequencing of 400–550 base pairs (bp) of the mitochondrial DNA (mtDNA) control region of eight species of Sparidae (Perciformes, Teleostei). This sequence information allowed us to design specific primers to one of these species (Pagellus bogaraveo). The new set of primers was used to test a rationalized approach to study the mtDNA nucleotide variability at the intraspecific level. The single-strand conformation polymorphism (SSCP) technique was applied to detect sequence variation in two non-overlapping fragments of the control region of 32 individuals of P. bogaraveo. To assess the sensitivity of the method, the nucleotide sequence of the analysed region was determined for all the specimens. The results showed that, for one of the two fragments, SSCP analysis was able to detect 100% of the underlying genetic variability. In sharp contrast, nucleotide variation of the second DNA fragment was completely unresolved by SSCP under different experimental conditions. This suggests that the resolution power of SSCP is crucially dependent on the nature of the fragment subjected to the analysis; therefore, a preliminary test of the sensitivity of the method should be performed on each specific DNA fragment before starting a large-scale survey. A rationalized approach, combining the SSCP technique and a simplified sequencing procedure, is proposed for studying intraspecific polymorphism at the mtDNA control region in fish.     

Species identification of Alnus (Betulaceae) using nrDNA and cpDNA genetic markers

One nuclear and three chloroplast DNA regions (ITS, rbcL, matK and trnH-psbA) were used to identify the species of Alnus (Betulaceae). The results showed that 23 out of all 26 Alnus species in the world, represented by 131 samples, had their own specific molecular character states, especially for three morphologically confused species (Alnus formosana, Alnus japonica and Alnus maritima). The discriminating power of the four markers at the species level was 10% (rbcL), 31.25% (matK), 63.6% (trnH-psbA) and 76.9% (ITS). For ITS, the mean value of genetic distance between species was more than 10 times the intraspecific distance (0.009%), and 13 species had unique character states that differentiated them from other species of Alnus. The trnH-psbA region had higher mean values of genetic distance between and within species (2.1% and 0.68% respectively) than any other region tested. Using the trnH-psbA region, 13 species are distinguished from 22 species, and seven species have a single diagnostic site. The combination of two regions, ITS and trnH-psbA, is the best choice for DNA identification of Alnus species, as an improvement and supplement for morphologically based taxonomy. This study illustrates the potential for certain DNA regions to be used as novel internet biological information carrier through combining DNA sequences with existing morphological character and suggests a relatively reliable and open taxonomic system based on the linked DNA and morphological data.     

植物分子群体遗传学研究动态

分子群体遗传学是当代进化生物学研究的支柱学科, 也是遗传育种和关于遗传关联作图和连锁分析的基础理论学科。分子群体遗传学是在经典群体遗传的基础上发展起来的, 它利用大分子主要是DNA序列的变异式样来研究群体的遗传结构及引起群体遗传变化的因素与群体遗传结构的关系, 从而使得遗传学家能够从数量上精确地推知群体的进化演变, 不仅克服了经典的群体遗传学通常只能研究群体遗传结构短期变化的局限性, 而且可检验以往关于长期进化或遗传系统稳定性推论的可靠程度。同时, 对群体中分子序列变异式样的研究也使人们开始重新审视达尔文的以“自然选择”为核心的进化学说。到目前为止, 分子群体遗传学已经取得长足的发展, 阐明了许多重要的科学问题, 如一些重要农作物的DNA多态性式样、连锁不平衡水平及其影响因素、种群的变迁历史、基因进化的遗传学动力等, 更为重要的是, 在分子群体遗传学基础上建立起来的新兴的学科如分子系统地理学等也得到了迅速的发展。文中综述了植物分子群体遗传研究的内容及最新成果。     

Pathogenic and molecular characterisations of pigeonpea wilt pathogen Fusarium udum

Thirty two pathogenic isolates of Fusarium udum from different pigeonpea growing areas in India were studied for pathogenic and molecular variability. Pathogenic variability was tested on 12 pigeonpea differential genotypes, which revealed prevalence of five variants in F. udum. The amount of genetic variation was evaluated by Polymerase Chain Reaction (PCR) amplification with 20 random amplified polymorphic DNA (RAPD) markers and nine microsatellite markers. All amplifications revealed scorable polymorphisms among the isolates, and a total of 137 polymorphic fragments were scored for the RAPD markers and 16 alleles for the simple sequence repeat (SSR) markers. RAPD primers showed 86% polymorphism. Genetic similarity was calculated using Jaccard's similarity coefficient and cluster analysis was used to generate a dendrogram showing relationships between them. Isolates could be grouped into three subpopulations based on molecular analysis. Results indicated that there is high genetic variability among a subpopulation of F. udum as identified by RAPD and SSR markers and pathogenicity on differential genotypes.     

Hierarchical organization of genetic variation in the Costa Rican livebearing fish Brachyrhaphis rhabdophora (Poeciliidae)

I examined the geographic distribution of genetic variation in the livebearing freshwater fish Brachyrhaphis rhabdophora in northwestern Costa Rica as revealed by allozymes and mitochondrial DNA sequences. Allelic variability at 11 enzyme-coding loci surveyed across 12 localities revealed marked genetic differentiation among populations within drainages (0_P= 0.36) and among drainages within regions (0_D=0.17), but not between northern and southern geographic regions (0_R=– 0.02). Allozyme variation was hierarchically organized such that populations found within stream drainages were more similar to each other than to populations found in adjacent drainages, a result confirmed by cluster analysis. In contrast to the allozyme data, there was extremely little DNA sequence variation among populations in the mitochondrial control region (3 variable nucleotide positions out of 444 bp examined). The difference in genetic divergence between allozyme and mtDNA markers was unexpected and is discussed in terms of biogeographical colonization events and a molecular selective swéep on the mitochondrial genome, both processes that could explain the lack of mitochondrial variability in this highly subdivided species.     

Lack of concordance between genetic diversity estimates at the molecular and quantitative-trait levels

In many applications of population genetics, particularly in the field of conservation biology, estimates of molecular diversity are used as surrogate indicators of less easily acquired measures of genetic variation for quantitative traits. The general validity of this approach to inferring levels of quantitative genetic variation within populations is called into question by the demonstration that estimates of molecular and quantitative-genetic variation are essentially uncorrelated in natural populations of Daphnia, one of the few organisms for which multiple estimates of both quantities are available. On the other hand, molecular measures of population subdivision seem to give conservatively low estimates of the degree of genetic subdivision at the level of quantitative traits. This suggests that although molecular markers provide little information on the level of genetic variation for quantitative traits within populations, they may be valid indicators of population subdivision for such characters.     

Molecular Genetic Variation in a Clonal Plant Population of Leymus chinensis （Trin.） Tzvel.

Randomly amplified polymorphic DNA （RAPD） analysis was used to investigate the genetic variation among populations, between populations, and within populations, relationships between genetic distance and geographic distance, and the molecular variation and population size. The effects of geographic and genetic distances, as well as of genetic differentiation and population size, on genetic variations of Leymus chinensis （Trin.） Tzvel. are discussed. The present study showed that there was significant RAPD variation between the Baicheng region population and the Daqing region population, with a molecular variance of 6.35% （P 〈 0.04）, and for differentiation among area populations of the Daqing region, with a molecular variance of 8.78% （P 〈 0.002）. A 21.06% RAPD variation among all 16 populations among two regions was found （P 〈 0.001）, as well as 72.59% variation within populations （P 〈 0.001）. Molecular variation within populations was significantly different among 16 populations.     

Comparison between RAPD and SSR molecular markers in detecting genetic variation in kiwifruit (Actinidia deliciosa A. Chev)

Two different DNA-based techniques, random amplified polymorphic DNA (RAPD) and simple sequence repeat (SSR) markers, were used for fingerprinting kiwifruit genotypes and for detecting undesirable genetic variation in micropropagated plants. The fragments were scored as present (1) or absent (0), and those readings were entered in a computer file as a binary matrix (one for each marker). Two cluster analyses were performed to express - in the form of dendrograms - the relationships among the genotypes and the genetic variability detected. Both DNA-based techniques were able to amplify all of the genotypes, but only SSR markers could detect genetic variation induced in micropropagated plants of cv. Tomuri. Two hypotheses were formulated to explain these results, both of them are in agreement with the results obtained using these two types of molecular markers. We conclude that when the tissue culture technique is used, the analysis of somaclonal variability could require more than one DNA-based technique; in fact, the genetic variation present in different sources could interfere or combine with the more or less polymorphic ability, as our results showed for SSR and RAPD markers.     

串珠藻目分子系统学研究进展

串珠藻目（Batrachospermales）是淡水红藻中最主要的类群。近年来,应用DNA序列分析探讨串珠藻目的系统发育,并与传统的形态学和生态学特征相结合,为串珠藻目系统学研究拓展了新的思路。本文回顾了串珠藻目的建立及其所含类群的研究历史,归纳了目前在串珠藻目系统发育与进化研究中常用的分子标记方法,其中包括核基因组的18SrDNA、26SrDNA和ITS序列,叶绿体基因组的rbcL序列,线粒体基因组的cox9．-3序列,以及新兴的ISSR技术,并对各种分子标记的特点及适用范围做了评述。结果表明,ITS序列多适用于种群分化及相近种间遗传分析,ISSR标记适用于种下分类群间及同一种群不同个体间基因多态性分析,cox2-3序列在一定程度上也可用于同一种群不同个体间的基因多态性分析,而18SrDNA与rbcLFF列既可用于种问关系分析,又可用于更高水平分析的构建系统树。这些分子枥对己已被证明在研究串珠藻目系统地理、物种起源和散布机制方面有着广泛的应用前景。同时,本文对串珠藻目分子系统学研究的最新进展也进行了概述,并对今后的研究方向做了展望。     

Natural genetic variation in Arabidopsis: tools, traits and prospects for evolutionary ecology

BACKGROUND: The model plant Arabidopsis thaliana (Arabidopsis) shows a wide range of genetic and trait variation among wild accessions. Because of its unparalleled biological and genomic resources, the potential of Arabidopsis for molecular genetic analysis of this natural variation has increased dramatically in recent years. SCOPE: Advanced genomics has accelerated molecular phylogenetic analysis and gene identification by quantitative trait loci (QTL) mapping and/or association mapping in Arabidopsis. In particular, QTL mapping utilizing natural accessions is now becoming a major strategy of gene isolation, offering an alternative to artificial mutant lines. Furthermore, the genomic information is used by researchers to uncover the signature of natural selection acting on the genes that contribute to phenotypic variation. The evolutionary significance of such genes has been evaluated in traits such as disease resistance and flowering time. However, although molecular hallmarks of selection have been found for the genes in question, a corresponding ecological scenario of adaptive evolution has been difficult to prove. Ecological strategies, including reciprocal transplant experiments and competition experiments, and utilizing near-isogenic lines of alleles of interest will be a powerful tool to measure the relative fitness of phenotypic and/or allelic variants. CONCLUSIONS: As the plant model organism, Arabidopsis provides a wealth of molecular background information for evolutionary genetics. Because genetic diversity between and within Arabidopsis populations is much higher than anticipated, combining this background information with ecological approaches might well establish Arabidopsis as a model organism for plant evolutionary ecology.     

Variability in nuclear DNA among nonhuman primates: Application of molecular genetic techniques to intra- and inter-species genetic analyses

Nuclear DNA clones and sequence information derived from human genetic analyses were used to detect and characterize intra- and inter-species DNA variation at several nuclear loci in hominoids and cercopithecoids. Restriction fragment length polymorphisms were found at five loci among captive rhesus monkeys. Cross-species polymerase chain reaction (PCR) amplification detected an insertion within the beta-globin gene cluster in hylobatids. The combined use of cross-species PCR and denaturing gradient gel electrophoresis detected both species differences and intra-species polymorphism in the homeobox cluster 2 of hominoids. These results a) demonstrate that DNA clones and nucleotide sequence information from human molecular genetics can be used to facilitate studies of the molecular genetics of nonhuman primates, and b) document specific examples of intra- and inter-species molecular variability at several loci. © 1992 Wiley-Liss, Inc.     

Studying plant genome variation using molecular markers

The authors studies on the organization and variation of plant genome with the use of molecular markers are briefly reviewed with special emphasis on random amplified polymorphic DNA (RAPD), inter simple sequence repeat (ISSR), sequence characterized amplified region (SCAR), and cleaved amplified polymorphic sequence (CAPS) markers detected with the use of polymerase chain reaction (PCR). These markers have been demonstrated to be promising for identifying cultivars and determining the purity of genetic strains of pea. Genetic relationships between strains, cultivars, and mutants of pea have been studied. The role of molecular markers in molecular genetic mapping and localizing the genes of commercially important characters of pea has been shown. The possibility of the use of molecular markers for studying somaclonal variation and detecting mutagenic factors in plants during long-term spaceflights is considered. The prospects of using DNA markers for understanding the organization and variability of higher plant genomes are discussed.__________Translated from Genetika, Vol. 41, No. 4, 2005, pp. 480–492.Original Russian Text Copyright © 2005 by Gostimsky, Kokaeva, Konovalov.     

鲸类分子系统学研究进展

综述了近年来分子生物学标记技术在鲸类系统学研究中的进展。分子生物学证据支持鲸目与有蹄类之间有较近的亲缘关系,并支持鲸类的单系起源,但鲸类不同类群(须鲸类、抹香鲸类及不包括抹香鲸类的齿鲸类)之间的系统发生关系仍存在争议。抹香鲸类到底与须鲸类还是与其它齿鲸类有更近的亲缘关系,不同的分子生物学家所得到的结果并不一致。此外,分子生物学技术还被用于解决须鲸亚目和齿鲸亚目内科间以及科内种间的系统发生关系,特别是齿鲸亚目的海豚科、鼠豚科和淡水豚类。通过分子标记技术来研究鲸类种下的遗传结构是鲸类分子系统学研究中的一个新热点,使用的标记主要是mtDNA控制区、核DNA微卫星和主要组织相容性复合体(major histo-compatibilitv complex,MHC)等。