基因组步移法克隆小菜蛾CYP9G2基因的上游序列

利用4种产生平端切头的限制性内切酶消化小菜蛾(Plutella xylostella)的基因组DNA,然后利用DNA连接酶的催化作用,在4种不同平端切头的小菜蛾基因组DNA上连接一个氨基化的基因组步移衔接头序列,针对衔接头及已克隆的CYP9G2基因的序列,设计两对PCR上、下游引物,进行PCR扩增、T-A克隆和阳性克隆的巢式PCR验证,通过测序克隆到了小菜蛾CYP9G2基因上游未知序列约1.8 kb.通过对该基因的上游序列进行信息分析,发现1个可能的节肢动物动物转录起始子(Inr),3个CAAT样盒及1个抗氧化剂样反应因子,共5个可能的顺式调控元件.研究还表明,利用基因组步移方法可以快速地克隆已知序列的上游未知序列,实验操作经济、简便,对于已知cDNA序列或部分基因组序列的基因,其上游调控序列的克隆,基因组步移具有较高的实用价值.     

玉米黑粉菌mt DNA的研究 Ⅰ.DNA克隆和基因图谱

本文对玉米黑粉菌mtDNA进行了如下研究:(1)将mt DNA的Bam HⅠ和Pss Ⅰ两套酶切片段分别克隆到pBR322的相应位点上,共克隆到占其基因组总长度89.3%的序列。(2)以植物或真菌来源的线粒体基因作探针,用低严紧度DNA分子杂交法鉴定出了玉米黑粉菌线粒体中的7个基因,并对照另文发表的限制性内切酶图谱,初步得出了这些基因在mt DNA上排列分布的基因图谱。它们排列的次序为:—COB—OⅫ—S—rRNA—OⅩⅢ—L—rRNA—ATPase6—OⅪ—。(3)对已鉴定出的3个含线粒体基因的克隆质粒,用E.coli极大细胞系统作了表达研究,但没见到线粒体基因的编码产物。     

靶向核酸酶在线粒体基因组编辑中的应用

线粒体基因组(mt DNA)的突变可导致多种人类疾病,其中绝大多数的mt DNA突变是异质性的:即在细胞中同时存在突变型和野生型的mt DNA,当突变型mt DNA的比例达到一定阈值时,就会引发疾病的发生。线粒体靶向的核酸内切酶可以诱导mt DNA异质性的改变,将突变型mt DNA的含量控制在发病阈值之下,从而达到疾病治疗的目的。本研究介绍了线粒体靶向的锌指核酸酶(ZFN)、类转录激活样效应因子核酸酶(TALEN)、规律成簇间隔短回文重复序列(CRISPR/Cas)以及常规的限制性核酸内切酶(restriction endonuclease,RE)在线粒体基因组编辑及疾病治疗中的应用。     

节肢动物线粒体基因组研究进展与基因顺序分析

在总结了68种节肢动物线粒体基因组的测序种类、基因组组成、结构及基因排序情况的基础上,特别对节肢动物线粒体基因组基因排列顺序数据进行了详细的分析。线粒体基因组基因排列顺序数据显示六足动物与甲壳动物之间相似,螯肢动物与多足动物相似,这个结果和以前Boore(1998)对节肢动物线粒体基因组顺序分析结果不同,却和核rRNA数据的分析结果一致。     

尼罗鳄线粒体基因组全序列分析及鳄类系统发生关系的探讨

大多数脊椎动物的线粒体基因组（约16—18kb）的组成是相对较稳定的,但在不同类群中,线粒体基因组在基因结构和基因排列方式等方面均显示了极大的多样性,这种多样性可能反映了真核细胞不同的进化路线（Saccone et al．,1999）。就目前的研究而言,线粒体基因组是惟一一个能够从基因组水平上来分析动物系统发生的分子标记,可以从线粒体基因组序列信息、基因组成及基因排列方式等进行多方位的分子进化研究,因而线粒体基因组全序列将成为动物分子系统发生最有力的证据（Saccone et al．,1999）。     

异刺草螽线粒体基因组序列分析

本研究采用高通量测序技术对异刺草螽的基因组进行测序,并组装得到了完整的线粒体基因组序列。结果显示:异刺草螽线粒体基因组序列全长16 038 bp,包含13个蛋白质编码基因、22个t RNA基因、2个r RNA基因和1个控制区。异刺草螽线粒体基因组的总碱基组成如下:A为37.3%、C为15.4%、G为10.3%、T为36.9%,A+T含量较高,为74.2%。异刺草螽线粒体基因的排列与祖先序列相同,该线粒体基因组序列为直翅目螽斯科的系统发生和进化研究提供了重要的分子基础。     

日本条螽线粒体基因组序列的测定与分析

日本条螽完整的线粒体基因组序列长16 281 bp,包括13个蛋白质编码基因、22个tRNA基因、2个r RNA基因和1个D-loop区,其基因次序和方向与祖先序列相同。该线粒体基因组排列紧凑,但在ND2和tRNA~(Trp)之间有一段长为650 bp的基因间隔区。为研究螽斯科的系统发育关系,本研究选取日本条螽及其它17个螽斯科物种线粒体基因组的蛋白质编码基因和r RNA基因序列构建贝叶斯系统发生树。     

节肢动物线粒体基因组碱基组成特征分析

利用93个节肢动物线粒体基因组数据,分析了线粒体基因组的碱基组成,及对氨基酸组成的影响。研究表明:(1)节肢动物线粒体基因组GC含量较低,分布范围较窄(13.28%～39.64%)。基因组GC含量与密码子第三位置的GC含量间的相关性(r=0.9432,p<0.01)比密码子第一、二位置上的相关性强。(2)在密码子的三个不同位置上均可以观察到C<->T和A<->G相互取代的现象。(3)从NC.004529和NC.003979两个序列的对比研究中可以发现碱基组成变化会引起氨基酸组成的变化,这种变化不仅体现在不同的物种之间,而且也体现在同一基因组内部的不同基因之间,这些影响可能是相互的。表明节肢动物线粒体基因组中的碱基变化是受多种因素共同作用的结果。     

机器学习方法在CRISPR/Cas9系统中的应用

基于CRISPR/Cas9系统介导的第三代基因组定点编辑技术,已被广泛应用于基因编辑和基因表达调控等研究领域。如何提高该技术对基因组编辑的效率与特异性、最大限度降低脱靶风险一直是该领域的难点。近年来,机器学习为解决CRISPR/Cas9系统所面临的问题提供了新思路,基于机器学习的CRISPR/Cas9系统已逐渐成为研究热点。本文阐述了CRISPR/Cas9的作用机理,总结了现阶段该技术面临的基因组编辑效率低、存在潜在的脱靶效应、前间区序列邻近基序(PAM)限制识别序列等问题,最后对机器学习应用于优化设计高效向导RNA (sgRNA)序列、预测sgRNA的活性、脱靶效应评估、基因敲除、高通量功能基因筛选等领域的研究现状与发展前景进行了展望,以期为基因组编辑领域的研究提供参考。     

野牦牛线粒体基因组序列测定及其系统进化

野牦牛属高寒地区的特有物种,是我国最珍贵的野生动物遗传资源之一,已被列为国家一级重点保护动物。对野牦牛mtDNA进行全序列测定和结构分析,并基于线粒体基因组序列对其系统发生进行了探讨。结果表明:(1)野牦牛线粒体基因组全序列的大小为16 322 bp,整个基因组由37个编码基因和D-loop区组成;22个tRNA基因序列长度为1 524 bp、2个RNA基因序列长度为2 528 bp、13个编码蛋白基因序列长度为11420 bp、D-loop区长度为892 bp。基因组中无间隔序列,基因间排列紧密,基因内无内含子。(2)野牦牛具有较丰富的遗传多样性。(3)分子系统发生关系显示牦牛为牛亚科中的一个独立属,即牦牛属(Poephagus),牦牛属包括家牦牛(Poephagus grunniens)和野牦牛(Poephagus mutus)2个种。野牦牛线粒体基因组全序列的获得和结构解析对研究牦牛的起源、演化和分类,以及野牦牛遗传资源的保护、开发和利用均具有重要的理论和实际意义。     

Mitochondrial genome reorganization characterizes various lineages of mesostigmatid mites (Acari: Parasitiformes)

Mesostigmata is an extremely diverse group of mites with more than 11,000 described species in 109 families. The complete mitochondrial (mt) genomes of five species of mesostigmatid mites from three families (Varroidae, Ologamasidae, Phytoseiidae) have been reported previously; all of them are rearranged or highly rearranged in gene order. However, it is unclear when mt genome reorganization occurred and how common it is in mesostigmatid mites. We sequenced the mt genomes of ten species of mesostigmatid mites from five more families (Blattisociidae, Diplogyniidae, Laelapidae, Macrochelidae, Parasitidae). We found that species in the families Diplogyniidae and Parasitidae have retained the ancestral mt genome organization of arthropods, which is in stark contrast to the highly rearranged mt genomes in the Phytoseiidae species. As in the Varroidae and Ologamasidae species, the mt genomes of the Blattisociidae, Macrochelidae and Laelapidae species are also rearranged but are less rearranged than in the Phytoseiidae species. Each of the six mesostigmatid families that have rearranged mt genomes is characterized by unique gene order not seen in other mesostigmatid families. Furthermore, the mt genome organization also differs among three genera of the Phytoseiidae, between two genera of the Laelapidae, and among three Macrocheles species of the Macrochelidae. Our results indicate that: (a) the most recent common ancestor of mesostigmatid mites likely retained the ancestral mt genome organization of arthropods; and (b) mt genome organization characterizes various lineages of mesostigmatid mites and provides a valuable source of information for understanding their phylogeny and evolution.     

啮总目昆虫的线粒体基因组多样性及系统发育研究进展

啮总目包括啮虫目（皮虱和书虱）和虱目（羽虱和吸虱）,是农业和医学等领域具有重要经济意义和研究价值的类群,目前已鉴定和描述的物种超过10 000个。啮总目昆虫线粒体基因组的变异性在昆虫各类群中最为剧烈,这些变异包括基因组的结构、基因排序、基因含量和链上分布等诸多方面。本文全面分析和总结了啮总目昆虫裂化线粒体基因组的进化属性,并结合两侧对称动物线粒体基因组的裂化特征重构了线粒体基因组环裂化的过程。引入“线粒体基因组核型”的概念来描述动物线粒体基因组丰富的变异程度。动物线粒体的染色体有减小的趋势,而线粒体基因组的裂化正是体现这种趋势的一种重要策略。同时,总结和探讨了目前具有争议的啮总目主要类群间的系统发育关系。本综述为啮总目昆虫线粒体基因组学、啮总目系统发生关系以及两侧对称动物线粒体基因组进化模式的研究提供一个新的视角。     

Genome size in arthropods; different roles of phylogeny,habitat and life history in insects and crustaceans

Despite the major role of genome size for physiology, ecology, and evolution, there is still mixed evidence with regard to proximate and ultimate drivers. The main causes of large genome size are proliferation of noncoding elements and/or duplication events. The relative role and interplay between these proximate causes and the evolutionary patterns shaped by phylogeny, life history traits or environment are largely unknown for the arthropods. Genome size shows a tremendous variability in this group, and it has a major impact on a range of fitness‐related parameters such as growth, metabolism, life history traits, and for many species also body size. In this study, we compared genome size in two major arthropod groups, insects and crustaceans, and related this to phylogenetic patterns and parameters affecting ambient temperature (latitude, depth, or altitude), insect developmental mode, as well as crustacean body size and habitat, for species where data were available. For the insects, the genome size is clearly phylogeny‐dependent, reflecting primarily their life history and mode of development, while for crustaceans there was a weaker association between genome size and phylogeny, suggesting life cycle strategies and habitat as more important determinants. Maximum observed latitude and depth, and their combined effect, showed positive, and possibly phylogenetic independent, correlations with genome size for crustaceans. This study illustrate the striking difference in genome sizes both between and within these two major groups of arthropods, and that while living in the cold with low developmental rates may promote large genomes in marine crustaceans, there is a multitude of proximate and ultimate drivers of genome size.     

One-step PCR amplification of complete arthropod mitochondrial genomes

A new PCR primer set which enables one-step amplification of complete arthropod mitochondrial genomes was designed from two conserved 16S rDNA regions for the long PCR technique. For this purpose, partial 16S rDNAs amplified with universal primers 16SA and 16SB were newly sequenced from six representative arthropods: Armadillidium vulgare and Macrobrachium nipponense (Crustacea), Anopheles sinensis (Insecta), Lithobius forficatus and Megaphyllum sp. (Myriapoda), and Limulus polyphemus (Chelicerata). The genomic locations of two new primers, HPK16Saa and HPK16Sbb, correspond to positions 13314-13345 and 12951-12984, respectively, in the Drosophila yakuba mitochondrial genome. The usefulness of the primer set was experimentally examined and confirmed with five of the representative arthropods, except for A. vulgare, which has a linearized mitochondrial genome. With this set, therefore, we could easily and rapidly amplify complete mitochondrial genomes with small amounts of arthropod DNA. Although the primers suggested here were examined only with arthropod groups, a possibility of successful application to other invertebrates is very high, since the high degree of sequence conservation is shown on the primer sites in other invertebrates. Thus, this primer set can serve various research fields, such as molecular evolution, population genetics, and molecular phylogenetics based on DNA sequences, RFLP, and gene rearrangement of mitochondrial genomes in arthropods and other invertebrates.     

The complete mitochondrial genome of the relict frog Leiopelma archeyi: insights into the root of the frog Tree of Life

Determining the root of the anuran Tree of Life is still a contentious and open question in frog systematics. Two genera with disjunct distributions have been traditionally considered the most basal among extant frogs: Leiopelma, which is endemic to New Zealand, and Ascaphus, which lives in North America. However, their specific phylogenetic position is rather elusive because each genus shows many autapomorphies, and together they retain many symplesiomorphic characters. Therefore, several alternative hypotheses have been proposed regarding the relative phylogenetic position of both Leiopelma and Ascaphus. In order to distinguish among these competing phylogenetic hypotheses, we sequenced the complete mitochondrial (mt) genome of Leiopelma archeyi and used it along with previously reported frog mt genomes (including that of Ascaphus truei) to infer a robust phylogeny of major anuran lineages. The reconstructed maximum likelihood and Bayesian inference phylogenies recovered identical topology, which supports the sister group relationship of Ascaphus and Leiopelma, and the placement of this clade at the base of the anuran tree. Interestingly, the mt genome of L. archeyi displays a novel gene arrangement in frog mt genomes affecting the relative position of cytochrome b, trnT, NADH dehydrogenase subunit 6, trnE, and trnP genes. The tandem duplication-random loss model of gene order change explains the origin of this novel frog mt genome arrangement, which is convergent with others reported in some fishes and salamanders. These results, together with comparative data for other available vertebrate mt genomes, provide evidence that the 5' end of the control region is a hot spot for gene order rearrangement.     

Analysis of complete mitochondrial genome sequences increases phylogenetic resolution of bears (Ursidae), a mammalian family that experienced rapid speciation

Background  

Despite the small number of ursid species, bear phylogeny has long been a focus of study due to their conservation value, as all bear genera have been classified as endangered at either the species or subspecies level. The Ursidae family represents a typical example of rapid evolutionary radiation. Previous analyses with a single mitochondrial (mt) gene or a small number of mt genes either provide weak support or a large unresolved polytomy for ursids. We revisit the contentious relationships within Ursidae by analyzing complete mt genome sequences and evaluating the performance of both entire mt genomes and constituent mtDNA genes in recovering a phylogeny of extremely recent speciation events.     

The mitochondrial genomes of Amphiascoides atopus and Schizopera knabeni (Harpacticoida: Miraciidae) reveal similarities between the copepod orders Harpacticoida and Poecilostomatoida

Members of subclass Copepoda are abundant, diverse, and—as a result of their variety of ecological roles in marine and freshwater environments—important, but their phylogenetic interrelationships are unclear. Recent studies of arthropods have used gene arrangements in the mitochondrial (mt) genome to infer phylogenies, but for copepods, only seven complete mt genomes have been published. These data revealed several within-order and few among-order similarities. To increase the data available for comparisons, we sequenced the complete mt genome (13,831 base pairs) of Amphiascoides atopus and 10,649 base pairs of the mt genome of Schizopera knabeni (both in the family Miraciidae of the order Harpacticoida). Comparison of our data to those for Tigriopus japonicus (family Harpacticidae, order Harpacticoida) revealed similarities in gene arrangement among these three species that were consistent with those found within and among families of other copepod orders. Comparison of the mt genomes of our species with those known from other copepod orders revealed the arrangement of mt genes of our Harpacticoida species to be more similar to that of Sinergasilus polycolpus (order Poecilostomatoida) than to that of T. japonicus. The similarities between S. polycolpus and our species are the first to be noted across the boundaries of copepod orders and support the possibility that mt-gene arrangement might be used to infer copepod phylogenies. We also found that our two species had extremely truncated transfer RNAs and that gene overlaps occurred much more frequently than has been reported for other copepod mt genomes.     

The complete mitochondrial genome of Arctic Calanus hyperboreus (Copepoda,Calanoida) reveals characteristic patterns in calanoid mitochondrial genome

Copepoda is the most diverse and abundant group of crustaceans, but its phylogenetic relationships are ambiguous. Mitochondrial (mt) genomes are useful for studying evolutionary history, but only six complete Copepoda mt genomes have been made available and these have extremely rearranged genome structures. This study determined the mt genome of Calanus hyperboreus, making it the first reported Arctic copepod mt genome and the first complete mt genome of a calanoid copepod. The mt genome of C. hyperboreus is 17,910 bp in length and it contains the entire set of 37 mt genes, including 13 protein-coding genes, 2 rRNAs, and 22 tRNAs. It has a very unusual gene structure, including the longest control region reported for a crustacean, a large tRNA gene cluster, and reversed GC skews in 11 out of 13 protein-coding genes (84.6%). Despite the unusual features, comparing this genome to published copepod genomes revealed retained pan-crustacean features, as well as a conserved calanoid-specific pattern. Our data provide a foundation for exploring the calanoid pattern and the mechanisms of mt gene rearrangement in the evolutionary history of the copepod mt genome.