植物反转录转座子的研究进展

反转录转座子是生物界中存在的一类可移动的遗传因子,其转座功能通过RNA介导反转录来实现.它在植物界中普遍存在,并在植物基因和基因组进化中扮演了一个极其重要的角色.概述了植物反转录转座子的类型结构及作为遗传工具在生物学中的作用.     

植物基因组中的非LTR反转录转座子SINEs和LINEs

反转录转座子是基因组进化的推动者之一。分为LTR和非LTR两种类型。前者是真核基因组的主要组分,结构和转座方式与逆转录病毒类似。后者是最初发现于动物基因组新近发现在植物基因组中也广泛存在的新型重复序列,包括LINEs(long interspersed nuclear elements)和SINEs(short interspersed nuclear elements)两个亚型。它们大多因自身或受宿主基因组的调控而失去转座活性。其转座机理目前还不十分清楚,推测LINEs可以自主转座,SINEs依赖其他转座子被动转座。种系分析认为LINEs可能是最古老的反转录转座子,SINEs的起源未知。文章对以上内容进行了归纳和讨论。     

植物反转录转座子及其在功能基因组学中的应用

高等植物中的反转录转座子是构成植物基因组的重要成分之一.它分病毒家族和非病毒家族两类,病毒家族包括反转录病毒和类似于反转录病毒的非病毒转座子,病毒家族中的反转录转座子可再细分为Ty3-gypsy类和Ty1-copia类;非病毒家族可细分为LINE类和SINE类.正常情况下大部分反转录转座子不具有活性,某些生物或非生物因素胁迫可激活部分反转录转座子转座.反转录转座子自身编码反转录酶进行转录,以"拷贝-粘贴"的转座模式导致基因组扩增和进化.具有活性的反转录转座子通过插入产生新的突变,可作为一种基因标签技术,应用于功能基因组学研究,并成为研究植物基因功能和表达的重要技术平台.本文综述了近几年来在植物反转录转座子方面的研究进展,主要包括植物反转录转座子的结构、特征、活性及其对基因组的影响和它们在功能基因组学中的应用.     

植物活性长末端重复序列反转录转座子研究进展

长末端重复序列(Long terminal repeat,LTR)反转录转座子是真核生物基因组中普遍存在的一类可移动的DNA序列,它们以RNA为媒介,通过"复制粘贴"机制在基因组中不断自我复制。在高等植物中,许多活性的LTR反转录转座子已被详尽研究并应用于分子标记技术、基因标签、插入型突变及基因功能等分析。本文对植物活性LTR反转录转座子进行全面的调查,并对其结构、拷贝数和分布以及转座特性进行系统的归纳,分析了植物活性LTR反转录转座子的gag(种属特异抗原)和pol(聚合酶)序列特征,以及LTR序列中顺式调控元件的分布。研究发现自主有活性的LTR反转录转座子必须具备LTR区域以及编码Gag、Pr、Int、Rt和Rh蛋白的基因区。其中两端LTR区域具有高度同源性且富含顺式调控元件;Rt蛋白必备RVT结构域;Rh蛋白必备RNase_H1_RT结构域。这些结果为后续植物活性LTR反转录转座子的鉴定和功能分析奠定了重要基础。     

Parasitism and the retrotransposon life cycle in plants: a hitchhiker's guide to the genome

LTR (long terminal repeat) retrotransposons are the main components of higher plant genomic DNA. They have shaped their host genomes through insertional mutagenesis and by effects on genome size, gene expression and recombination. These Class I transposable elements are closely related to retroviruses such as the HIV by their structure and presumptive life cycle. However, the retrotransposon life cycle has been closely investigated in few systems. For retroviruses and retrotransposons, individual defective copies can parasitize the activity of functional ones. However, some LTR retrotransposon groups as a whole, such as large retrotransposon derivatives and terminal repeats in miniature, are non-autonomous even though their genomic insertion patterns remain polymorphic between organismal accessions. Here, we examine what is known of the retrotransposon life cycle in plants, and in that context discuss the role of parasitism and complementation between and within retrotransposon groups.     

Diaspora, a large family of Ty3 - gypsy retrotransposons in Glycine max, is an envelope-less member of an endogenous plant retrovirus lineage

Background  

The chromosomes of higher plants are littered with retrotransposons that, in many cases, constitute as much as 80% of plant genomes. Long terminal repeat retrotransposons have been especially successful colonizers of the chromosomes of higher plants and examinations of their function, evolution, and dispersal are essential to understanding the evolution of eukaryotic genomes. In soybean, several families of retrotransposons have been identified, including at least two that, by virtue of the presence of an envelope-like gene, may constitute endogenous retroviruses. However, most elements are highly degenerate and are often sequestered in regions of the genome that sequencing projects initially shun. In addition, finding potentially functional copies from genomic DNA is rare. This study provides a mechanism to surmount these issues to generate a consensus sequence that can then be functionally and phylogenetically evaluated.     

Young but not relatively old retrotransposons are preferentially located in gene‐rich euchromatic regions in tomato (Solanum lycopersicum) plants

Long terminal repeat (LTR) retrotransposons are the major DNA components of flowering plants. They are generally enriched in pericentromeric heterochromatin regions of their host genomes, which could result from the preferential insertion of LTR retrotransposons and the low effectiveness of purifying selection in these regions. To estimate the relative importance of the actions of these two factors on their distribution pattern, the LTR retrotransposons in Solanum lycopersicum (tomato) plants were characterized at the genome level, and then the distribution of young elements was compared with that of relatively old elements. The current data show that old elements are mainly located in recombination‐suppressed heterochromatin regions, and that young elements are preferentially located in the gene‐rich euchromatic regions. Further analysis showed a negative correlation between the insertion time of LTR retrotransposons and the recombination rate. The data also showed there to be more solo LTRs in genic regions than in intergenic regions or in regions close to genes. These observations indicate that, unlike in many other plant genomes, the current LTR retrotransposons in tomatoes have a tendency to be preferentially located into euchromatic regions, probably caused by their severe suppression of activities in heterochromatic regions. These elements are apt to be maintained in heterochromatin regions, probably as a consequence of the pericentromeric effect in tomatoes. These results also indicate that local recombination rates and intensities of purifying selection in different genomic regions are largely responsible for structural variation and non‐random distribution of LTR retrotransposons in tomato plants.     

植物LTR反转录转座子的研究进展

反转录转座子是真核生物基因组中普遍存在的一类可移动的遗传因子,它们以RNA为媒介,在基因组中不断自我复制。在高等植物中,反转录转座子是基因组的重要成分之一。反转录转座子可以分为5大类型,其中以长末端重复（LTR）类型报道较多。LTR类型由于其首尾具有长末端重复序列,内部含有PBS、PPT、GAG和POL开放阅读框、TSD等结构,可以采用生物信息学软件进行预测。LTR反转录转座子的活性受到自身甲基化和环境因素的影响,DNA甲基化抑制反转录转座子转座,而外界环境的刺激能够激活转座子,从而影响插入位点周边基因的表达。同时由于LTR反转录转座子在植物中普遍存在,丰富的拷贝数以及多态性为新型分子标记（RBIP、SSAP、IRAP、REMAP）的开发提供了良好的素材。该文对近年来国内外有关植物反转录转座子的类型、结构特征、 LTR反转录转座子的活性及其影响因素、 LTR反转录转座子的预测以及标记开发等方面的研究进展进行综述。     

High-throughput S-SAP by fluorescent multiplex PCR and capillary electrophoresis in plants

The inherent replicative mode of transposition endows retrotransposons with considerable advantages as genetic tools in plant genome analysis. Here we present a high-throughput sequence-specific amplification polymorphism (S-SAP) method based on copia-like retrotransposons to fulfill the increasing desire of screening large numbers of samples in plants. Classic approach for digestion, ligation and pre-amplification was combined with optimized fluorescent multiplex PCR for simultaneously selective amplifying S-SAP fragments, and multiple S-SAPs were subsequently detected by capillary electrophoresis using ABI PRISM 3700 capillary instruments. Comparisons of results from multiplex PCR with simplex PCR, and from capillary electrophoresis with slab-gel electrophoresis demonstrated that this method is an efficient, economical, and accurate means for high-throughput and large-scale genotyping retrotransposon variation in plants.     

LTR retrotransposons and flowering plant genome size: emergence of the increase/decrease model

Long Terminal Repeat (LTR) retrotransposons are ubiquitous components of plant genomes. Because of their copy-and-paste mode of transposition, these elements tend to increase their copy number while they are active. In addition, it is now well established that the differences in genome size observed in the plant kingdom are accompanied by variations in LTR retrotransposon content, suggesting that LTR retrotransposons might be important players in the evolution of plant genome size, along with polyploidy. The recent availability of large genomic sequences for many crop species has made it possible to examine in detail how LTR retrotransposons actually drive genomic changes in plants. In the present paper, we provide a review of the recent publications that have contributed to the knowledge of plant LTR retrotransposons, as structural components of the genomes, as well as from an evolutionary genomic perspective. These studies have shown that plant genomes undergo genome size increases through bursts of retrotransposition, while there is a counteracting process that tends to eliminate the transposed copies from the genomes. This process involves recombination mechanisms that occur either between the LTRs of the elements, leading to the formation of solo-LTRs, or between direct repeats anywhere in the sequence of the element, leading to internal deletions. All these studies have led to the emergence of a new model for plant genome evolution that takes into account both genome size increases (through retrotransposition) and decreases (through solo-LTR and deletion formation). In the conclusion, we discuss this new model and present the future prospects in the study of plant genome evolution in relation to the activity of transposable elements.     

Male germline control of transposable elements

Repetitive sequences, especially transposon-derived interspersed repetitive elements, account for a large fraction of the genome in most eukaryotes. Despite the repetitive nature, these transposable elements display quantitative and qualitative differences even among species of the same lineage. Although transposable elements contribute greatly as a driving force to the biological diversity during evolution, they can induce embryonic lethality and genetic disorders as a result of insertional mutagenesis and genomic rearrangement. Temporary relaxation of the epigenetic control of retrotransposons during early germline development opens a risky window that can allow retrotransposons to escape from host constraints and to propagate abundantly in the host genome. Because germline mutations caused by retrotransposon activation are heritable and thus can be deleterious to the offspring, an adaptive strategy has evolved in host cells, especially in the germline. In this review, we will attempt to summarize general defense mechanisms deployed by the eukaryotic genome, with an emphasis on pathways utilized by the male germline to confer retrotransposon silencing.