禾草模式植物二穗短柄草的研究进展

二穗短柄草（Brachypodium distachyon）是近来开发的一种温带禾草模式植物。它具有与粮食作物相同的许多生物学特性,可作为研究粮食作物生物学特性的模式实验植物。不同采集地的二穗短柄草具有高度的表观变异性,可帮助研究人员对这些生物学特性从表观到遗传的深入研究。二穗短柄草与其他重要经济作物如小麦、大麦及其他潜在能源植物一样同属于早熟禾亚科,使其成为研究这些重要经济作物无可非议的模式植物。近来,由于二穗短柄草基因组序列及其相关注释的完成,功能基因组学和其他实验技术手段的不断进步,二穗短柄草可为其他禾草类植物提供序列分析、基因表达和功能研究等诸多便利。本文综述了利用二穗短柄草作为模式植物来进行比较基因组学、生物学研究、转化和T—DNA突变等方面的最新研究进展。     

短柄草与麦类作物的比较基因组学研究进展

麦类作物是人类主要的食物来源,其遗传改良对于保障世界粮食生产具有重要作用。获得麦类作物的基因组和功能基因组信息是作物遗传育种学家解析种质资源高产及抗逆机理,并准确选择目标性状、实现分子设计育种目标的有效途径。目前,二穗短柄草（Brachypodium distachyum）是早熟禾亚科中唯一完成全基因组测序的植物。以二穗短柄草为模式植物,利用比较基因组学方法获得早熟禾亚科中基因组庞大而复杂的麦类作物的相关信息,必将加速麦类作物的遗传改良进程。本文重点介绍近十年来短柄草在麦类作物比较基因组学方面的研究进展。     

模式植物二穗短柄草研究进展与展望

二穗短柄草(Brachypodium distachyon)是一种温带禾本科植物,其植株矮小,自花授粉,生活周期短,生长条件简单,基因组小,易于进行遗传转化,与小麦、柳枝稷同属禾本科早熟禾亚科,是研究小麦、大麦等经济作物以及柳枝稷等能源植物的比较适合的模式植物。最近,二穗短柄草基因组测序及注释正式完成,有必要对其研究进展进行全面的总结。综述了二穗短柄草的基因组特征、基因表达模式、遗传转化等方面的最新研究进展,并对今后的研究方向作了展望,以促进对禾谷类经济作物和能源植物的深入研究。     

小麦的比较基因组学和功能基因组学

小麦是异源多倍体植物,具有大的染色体组,并且基因组中重复序列所占比例较高,这些特征限制了小麦基因组研究的进展。比较基因组学方法为运用模式植物进行小麦基因组学研究提供了一个操作平台。功能基因组学的研究集中于基因组中转录表达的部分,基因功能的确定是功能基因组学研究的主要内容。对比较基因组学在小麦基因组研究中的应用和小麦功能基因组学的研究内容和方法进行了综述。     

植物功能基因组学的研究策略

植物基因组学是一门研究植物基因组内基因与遗传信息是如何有机结合并如何决定其功能的一门科学。随着植物基因组计划的顺利进行 ,植物基因组学的研究已从结构基因组学转向功能基因组学。近年来 ,多采用高通量 (highthroughput,HTP)序列分析技术、大规模实验技术及计算机统计分析技术研究植物基因组功能。概述了植物功能基因组学的最新进展。     

基于高通量测序的植物群体基因组学研究进展

作为群体遗传学一种新的表现形式,群体基因组学是将基因组概念和技术与群体遗传学理论体系相结合,通过覆盖全基因组范围内的多态位点的分布式样推测位点特异性效应和全基因组效应,从而提升人们对微进化的理解。近年来,随着第二代高通量测序技术的出现和改进,完成基因组测序的植物种类迅速增加,大规模的重测序也随之开展。与此同时,在一些尚未完成基因组测序的植物物种中,也开展了一些平行测序。这些重测序和平行测序极大地促进了群体基因组学的发展,加深了人们对相关植物种群在基因组水平上的遗传多样性、连锁不平衡水平、选择作用、群体历史及复杂性状的分子机理等群体基因组学方面的认识。本文简要介绍了群体基因组学的概念、研究方法等,重点综述了基于高通量测序的植物群体基因组学的研究动态,展望了植物群体基因组学的发展前景并讨论了存在的问题,以期为相关研究提供借鉴和参考。     

新模式禾草植物短柄草的研究现状

随着短柄草基因组测序基本完成,短柄草其因生长周期短、植株矮小、基因组较小及在进化上比水稻与小麦的亲缘关系更为接近等特点,成为继水稻之后,加速获取遗传信息相对缺少的小麦等相关物种遗传信息的新兴起的禾草类模式植物。对近年来有关短柄草的生理生化、组织培养、实验室条件下各生态型的生长状况,分子及细胞遗传学等方面的研究加以综述,希望对这一新的禾草类模式植物有进一步的了解。     

泛基因组及其在植物功能基因组学研究中的应用

参考基因组是现代功能基因组学的核心框架,以此为基础的现代基因组学技术在过去20年对植物遗传变异发掘、功能基因克隆等研究起了巨大的推动作用。然而,越来越多的研究发现,单一或少数参考基因组不能完整代表和呈现物种或特定群体内的所有基因组变异,因此其在功能基因组学研究中应用存在很大的局限性,甚至会导致错误的结果。泛基因组是指物种或特定群体内全部基因或基因组序列的总和。泛基因组通过完整捕获和呈现群体内全部的基因或基因组序列,代替单一参考基因组应用于功能基因组学研究,可以突破单一参考基因组的局限性。泛基因组在植物功能基因组学研究中有广泛的应用,以泛基因组为基础,结合最新的基因组学技术可以高效、精准鉴定种质资源中的遗传变异。泛基因组研究是目前植物基因组学研究的前沿和热点。本文综述了泛基因组概念的起源和发展,泛基因组组装的技术和策略,以及泛基因组在植物基因组学研究和分子育种方面的应用和最新进展,最后对植物泛基因组研究目前存在的问题和今后研究方向进行了展望。本综述可为植物泛基因组研究和应用提供参考。     

高粱基因组学研究进展

高粱是世界上主要的谷物作物之一,是越来越重要的生物燃料作物,是恶性杂草约翰逊草的祖先,同时也是很多具有复杂基因组的热带禾本科植物的植物学模型.因此高粱成为植物基因组学研究的主要对象之一.高粱基因组学研究的丰富历史随着重要的自交系材料BT×623全基因组测序的完成而达到顶峰,这为更好研究高粱基因及其相关功能打下了基础.对甘蔗亚族谷类植物以外的植物的更进一步的基因组特征分析,将有利于发现基因组大小和结构进化的机制,水平和模式,为进一步研究甘蔗和其它重要的经济作物奠定基础.     

单核苷酸多态性（SNPs）原理及其在植物功能功能基因组学中的应用前景

近缘种群或同种个体之间的单核苷酸多态性(SNPs)是存在于生物基因组上由单个核苷酸的变异所引起的一种DNA序列多态性。它具有高丰度、高信息量和良好稳定性的特点,而且比较适合自动化操作。SNPs将会在植物功能基因组学研究中得到广泛应用,并加强功能基因学与种群遗传学的联系。本文就SNPs及其在植物功能基因组学中的应用前景作一下探讨。     

黄曲霉功能基因组学研究

黄曲霉（Aspergillus flavus）是一种常见的腐生真菌和条件致病菌,其次生代谢产物黄曲霉毒素（Aflatoxin,AFT）具有高度的致癌性和致畸性,严重危及人类和动物健康。近年来,功能基因组学研究发展迅速,在真菌生长发育、挖掘真菌次级代谢产物以及研究包括黄曲霉毒素在内的真菌毒素等方面得到了广泛的应用。功能基因组学在研究黄曲霉与宿主之间的相互作用以及黄曲霉与其他曲霉之间的相互作用方面具有巨大的潜力。然而,黄曲霉功能基因组学受到细胞壁难以破除、耐药性高、筛选标记少、缺陷型菌株构建费力耗时等因素的影响而发展缓慢。概述了黄曲霉的选择标记、遗传转化方法和黄曲霉毒素以及环匹阿尼酸（cyclopiazonic acid, CPA）生物合成的研究进展,并讨论了在提高黄曲霉基因操作效率方面的潜在策略。例如,构建缺乏非同源末端连接（NHEJ）途径的菌株、Cre-loxP重组系统、CRISPR-Cas9等方法,为深入开展黄曲霉遗传学研究提供参考。     

Improvement of <Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation in Hi-II maize (<Emphasis Type="Italic">Zea mays</Emphasis>) using standard binary vectors

High-frequency transformation of maize (Zea mays L.) using standard binary vectors is advantageous for functional genomics and other genetic engineering studies. Recent advances in Agrobacterium tumefaciens-mediated transformation of maize have made it possible for the public to transform maize using standard binary vectors without a need of the superbinary vector. While maize Hi-II has been a preferred maize genotype to use in various maize transformation efforts, there is still potential and need in further improving its transformation frequency. Here we report the enhanced Agrobacterium-mediated transformation of immature zygotic embryos of maize Hi-II using standard binary vectors. This improved transformation process employs low-salt media in combined use with antioxidant l-cysteine alone or l-cysteine and dithiothreitol (DTT) during the Agrobacterium infection stage. Three levels of N6 medium salts, 10, 50, and 100%, were tested. Both 10 and 50% salts were found to enhance the T-DNA transfer in Hi-II. Addition of DTT to the cocultivation medium also improves the T-DNA transformation. About 12% overall and the highest average of 18% transformation frequencies were achieved from a large number of experiments using immature embryos grown in various seasons. The enhanced transformation protocol established here will be advantageous for maize genetic engineering studies including transformation-based functional genomics.     

ALGAL TRANSGENICS IN THE GENOMIC ERA1

The last few years have witnessed significant advances in the field of algal genomics. Complete genome sequences from the red alga Cyanidioschyzon merolae and the diatom Thalassiosira pseudonana have been published, the genomes for two more algae (Chlamydomonas reinhardtii and Ostreococcus tauri) are nearing completion, and several others are in progress or at the planning stage. In addition, large‐scale cDNA sequencing projects are being carried out for numerous algal species. This wealth of genome data is serving as a powerful catalyst for the development and application of recombinant techniques for these species. The data provide a rich resource of DNA elements such as promoters that can be used for transgene expression as well as an inventory of genes that are possible targets for genetic engineering programs aimed at manipulating algal metabolism. It is not surprising therefore that significant progress in the genetic engineering of eukaryotic algae is being made. Nuclear transformation of various microalgal species is now routine, and progress is being made on the transformation of macroalgae. Chloroplast transformation has been achieved for green, red, and euglenoid algae, and further success in organelle transformation is likely as the number of sequenced plastid, mitochondrial, and nucleomorph genomes continues to grow. Importantly, the commercial application of algal transgenics is beginning to be realized, and algal biotechnology companies are being established. Recent work has shown that recombinant proteins of therapeutic value can be produced in microalgal species, and it is now realistic to envisage the genetic engineering of commercially important species to improve production of valuable algal products. In this article we review the recent progress in algal transgenics and consider possible future developments now that phycology has entered the genomic era.     

High-efficiency Agrobacterium-mediated transformation of Brachypodium distachyon inbred line Bd21-3

Brachypodium distachyon (Brachypodium) is a small grass with biological attributes (rapid generation time, small genome, diploid accessions, small stature and simple growth requirements) that make it suitable for use as a model system. In addition, a growing list of genomic resources have been developed or are currently under development including: cDNA libraries, BAC libraries, EST sequences, BAC end sequences, a physical map, genetic markers, a linkage map and, most importantly, the complete genome sequence. To maximize the utility of Brachypodium as a model grass it is necessary to develop an efficient Agrobacterium-mediated transformation system. In this report we describe the identification of a transformable inbred diploid line, Bd21-3, and the development of a transformation method with transformation efficiencies as high as 41% of co-cultivated calluses producing transgenic plants. Conducting the co-cultivation step under desiccating conditions produced the greatest improvement in transformation efficiency.     

Invited review: Transformation of strawberry: The basis for translational genomics in Rosaceae

Summary Translational genomics is defined as the application of molecular-genetic principles derived from model systems to species of experimental or economic interest. The past 20 years of research in plant model systems such as Arabidopsis thaliana have relinquished vast amounts of information regarding gene function, the integration of genetic components into pathways, and the interrelationships between pathways to control form and function in plants and plant-products alike. At present, the challenge is to relate these paradigms to other species of economic or scientific interest. Apart from being an important and valuable crop, strawberry (Fragaria spp.) is a member of the Rosaceae, a plant family containing fruit, nut, ornamental and wood-bearing species. Strawberry is unique within the Rosaceae in that it is a rapidly growing herbaceous perennial with a small genome and the ability to thrive in a laboratory setting. Strawberry species may also be transformed and regenerated in a time scale of weeks or months instead of years. For these reasons, strawberry has been recognized as the translational genomics model for the Rosaceae family. This review summarizes and synthesizes the technical reports of strawberry regeneration and transformation, consolidating the large body of information regarding genetic modification of this important genus.     

多重耐药寡养单胞菌的基因组学研究进展

寡养单胞菌(Stenotrophomonas)是一类广泛分布于自然环境中的革兰氏阴性非发酵细菌,环境适应能力较强,尤其具备高度耐受抗生素的能力,被认为是耐药基因(antimicrobial resistance,AMR)传播的“物流转运仓库”。临床上寡养单胞菌检出率逐年提高,且耐受抗生素能力及其种类呈现增加态势。本文围绕寡养单胞菌基因组编码的多样性耐药因子,结合基因组学工具开发、抗生素耐药分子机制的研究进展,针对耐药相关因子所涉及的进化/变异和序列编辑技术展开综述。寡养单胞菌的比较基因组学(comparative genomics)研究,可推动耐药菌高效监测与扩散风险防控、解析微生物适应环境关键机制和设计靶向药物。     

RETRACTED ARTICLE: Virus-induced gene silencing for functional analysis of selected genes

Virus-induced gene silencing (VIGS) is a technology that exploits an RNA-mediated antiviral defense mechanism and has been shown to be of great potential in plant reverse genetics. Circumvention of plant transformation, methodological simplicity, robustness, and speedy results makes VIGS an attractive alternative instrument in functional genomics, even in a high throughput fashion. The system is well established in Nicotiana benthamiana, and efforts are being made to improve VIGS in other species, including monocots. Here, we discuss the issues specific to the application of VIGS technology to determine gene function, which has revealed the roles of a variety of genes in disease resistance, abiotic stress, cellular signaling and secondary metabolite biosynthesis. M. R. Godge and A. Purkayastha made equal contributions and hence should be treated as joint first authors for this paper.     

Transformation of Actinidia eriantha: A potential species for functional genomics studies in Actinidia

Protocols were developed for regeneration and Agrobacterium-mediated transformation of Actinidia eriantha Benth. A. eriantha has a number of features that make it a useful tool for functional genomics in Actinidia: the vines are relatively small and non-vigorous in nature, flowers form all over the vine including on lower axillary branches and the species flowers prolifically in greenhouse conditions. Flowering and fruiting of transgenic A. eriantha plants was obtained within 2 years of transformation in a containment greenhouse. GUS (β-glucuronidase) activity indicating stable expression of the uidA gene was observed in leaf, stem, root, petal and fruit tissues. Molecular evidence for incorporation of transgenes into the A. eriantha genome was obtained by PCR and DNA gel blot analysis. Inheritance of transgenic phenotypes was demonstrated in seedling progeny. Functional genomic studies in kiwifruit have been initiated using transgenic A. eriantha plants. Communicated by F. Sato