单子叶植物无融合生殖的研究进展

植物的无融合生殖是指不经过雌雄配子融合而产生种子的一种特殊生殖方式。由于利用无融合生殖途径可以固定杂种优势 ,从而改良现有植物的育种策略 ,因此对无融合生殖的研究已成为生物学科的新生长点。本文主要从无融合生殖的概念和类型 ,无融合生殖在单子叶植物中的分布 ,无融合生殖的胚胎学 ,分子生物学和遗传学机制及创造新的无融合生殖种质资源的方法等 6方面对单子叶植物的无融合生殖的研究进展进行了综述 ,并提出了今后开展无融合生殖研究的思路和设想     

单子叶植物无融合生殖的研究进展

植物的无融合生殖是指不经过雌雄配子融合而产生种子的一种特殊生殖方式。由于利用无融合生殖途径可以固定杂种优势,从而改良现有植物的育种策略,因此对无融合生殖的研究已成为生物学科的新生长点。本文主要从无融合生殖的概念和类型,无融合生殖在单子叶植物中的分布,无融合生殖的胚胎学,分子生物学和遗传学机制及创造新的无融合生殖种质资源的方法等6方面对单子叶植物的无融合生殖的研究进展进行了综述,并提出了今后开展无融合生殖研究的思路和设想。     

植物无融合生殖的筛选和鉴定研究进展

植物无融合生殖具有复杂的发育过程,与细胞学、遗传学、生物化学和分子生物学等相关的各种技术均被应用于植物无融合生殖的筛选和鉴定.本文结合新近发表的研究文献,介绍了常规的植物无融合生殖筛选和鉴定技术的新应用,评介了流式细胞种子筛选技术、胚珠整体透明技术、外源标记基因转入法等植物无融合生殖筛选和鉴定的新技术,并对各种筛选和鉴定技术的优势和不足进行了评述.     

植物的无融合生殖

植物的无融合生殖肖辅珍,王景林（首都师范大学生物系,北京１０００３７）１无融合生殖及其类型无融合生殖（Ａｐｏｍｉｘｉｓ）是被子植物不经过精卵结合而产生种子的特殊生殖方式［１］。它广泛存在于自然界的多种植物中,或代替有性生殖（专性的）,或与有性生殖共存...     

植物无融合生殖研究进展

本文综述了植物无融合生殖研究进展。无融合生殖能固定杂种优势,是新的研究热点。无融合合生殖转充研究取得长足进展。胚胎发生研究手段由切片技术逐渐发展为整体透明、组化荧光技术。大孢子母细胞（ＭＭＣ）细胞壁无胼胝质（ｃａｌｌｏｓｅ）及ＭＭＣ哑铃状核是二倍性孢子形成区别于有性生殖的特征。ＤＮＡ分子标记是无融合生殖研究的新的有效工具,狼尾草属、摩擦禾属的无融合生殖分子标记已被找到,并且后者已定位到玉米第６染色     

植物无融合生殖的遗传机理和分子机理的研究进展

利用植物无融合生殖固定杂种优势,已被认为是一条生产杂交种子的高效途径。近年来,由于RAPD、RFLP和差异显示等技术的应用,已使植物无融合生殖的研究面貌一新。特别是一系列与无融合生殖有关的特异DNA片段的发现,为深入了解其遗传机理和分子机理增加了大量新的知识,这些知识无疑为定位和克隆植物无融合生殖基因,进而利用遗传操作的手段来改变植物的生殖方式积累了必要的理论基础。本文对植物无融合生殖遗传机理和分子机理的研究进展作了综述。 Abstract:Apomixis allows the establishment of genetically stable seed propagating clones of crops,which can perpetuate themselves across countless sporophytic generations.This asexual mode of reproduction,which naturally occurs in some angiosperms,may prove to be an unrivalled tool to improve crop yields.The current state of knowledge on the molecular and genetic basis of apomixis is reviewed.     

雾灵山草地早熟禾多胚囊和多胚的研究

无融合生殖是指未经炷卵事例而产生后代的特殊生殖方式,它可以分为单倍体无融合生殖和二倍体无融合生殖;对于作物意义更大的是二倍体无融合生殖。多胚囊和多胚现象ＳＨＩ是无融合生殖的表现形式。本文运用石蜡切片法、子房整体透明法研究了雾灵山草地早熟禾（Ｐｏａ ｐｒａｔｅｎｓｉｓ Ｌ．）多胚囊和多胚现象。结果表明,（１）草地早熟禾多胚囊来源有两种：一是自大孢子母细胞,二是来自珠心细胞;（２）草地早熟禾多 来源有     

植物无融合生殖研究新进展

无融合生殖是指不经过雌雄配子融合而产生种子的一种特殊生殖方式,能使基因型的杂合性得以保持,从而可以固定杂种优势,对作物育种具有极其重要的意义。目前大量的研究都在设法将无融合生殖作为一种重要的植物育种手段。本文对近几年来无融合生殖新种质资源的发现、主要研究方法、遗传机制和相关基因等方面的最新进展作了介绍,并对无融合生殖研究中存在的问题和发展前景作了讨论。     

植物无融合生殖相关基因研究进展

无融合生殖是指不经过精卵融合即可形成胚从而进行种子繁殖后代的一种特殊的无性生殖方式, 无融合生殖胚的形成没有父本的参与, 其后代是母本基因型的完整克隆, 因此是植物杂种优势固定与利用的一种最理想的途径, 具有巨大的潜在利用价值, 被誉为“无性革命”。按其胚体发生的途径, 无融合生殖可分为二倍体孢子生殖、无配子生殖和不定胚生殖三种类型。本文介绍了植物胚发育、胚乳发育、减数分裂等涉及无融合生殖过程的相关基因的研究进展, 同时介绍了可能与植物无融合生殖途径调控相关的几个基因片段的研究情况。     

披碱草 Elymus rectisetus无融合生殖及其转育的研究进展

披碱草Elymus rectisetus(Nees in Lehm）A Loeve et Connor(2n=6x=42）,SSYYWW）是目前发现的小麦族（Triticeae）中唯一的无融合生殖种,属二倍性孢子形成的假受精无融合生殖类型,无融合生殖能固定杂种优势,简化育种程序,缩短育种年限,因此E.rectisetus无融合生殖及其向小麦中导入的研究一直受到遗传育种学家的重视,与有性生殖相比,无融合生殖类型大孢子母细胞（MMC）的形成有三个显著特点：（1）MMC在早前期合点形成液泡;（2）MMC核显著伸长,呈椭圆形或哑玲形;（3）MMC周围缺乏含,胼胝质的细胞壁E.rectisetus与披碱草属内的种间杂交取得较大进展,了其分类和遗传学研究。E.rectisetus与近缘属杂交成功例子逐渐增多,目前国内外已成功进行了普通小麦与E.rectisetus属间杂交,为最终将E.rectisetus无融合生殖基因导入小麦奠定了基础。     

Chromosome control of apomixis in maize-gamagrass hybrids

The results of long-term studies on the transmission of the mode of asexual reproduction through seeds to maize from gamagrass, a closely related wild plant, performed in the Laboratory of Plant Cytology and Apomixis are summarized. The first apomictic hybrids between Zea mays and Tripsacum dactyloides were obtained in this laboratory more than 40 years ago and have been maintained until the present time. Cytogenetic studies on the hybrids have shown that at least nine chromosomes of the wild parent are necessary for the expression of asexual reproduction through seeds. In addition, the genes controlling two elements of apomixis (apomeiosis and parthenogenesis) have been found to be inherited independently from each other.     

CLEISTOGAMY IN MICROLAENA POLYNODA (GRAMINEAE): AN EXAMINATION OF SOME MODEL PREDICTIONS

A population of the cleistogamous grass, Microlaena polynoda, was investigated to determine some of the factors responsible for adjusting the balance between reproduction by chasmogamous (CH) and cleistogamous (CL) flowers, the tissue costs associated with the two reproductive modes, the fate of progeny produced by each mode, and the genetic diversity of the progeny. Cleistogamous flower production begins earlier in the season than CH flower production. There is a distinct threshold of low light intensity below which mostly CL flowers are produced. Paternal expenditure per plant is an order of magnitude larger for the CH than the CL component. The opposite relation holds for maternal expenditure. Increased maternal expenditure in the CL component may be due to greater fertilization success and retrieval of paternal costs. Cleistogamous seeds are dispersed later than CH seeds. Following dispersal, the spikelet encloses the CL seed but not the CH seed, and is responsible for inducing dormancy. The ratio of seedlings arising from CH seeds to that from CL seeds in a natural habitat is significantly lower than the ratio of estimated numbers of CH to CL seeds produced. There were no detectable polymorphisms among ten presumptive enzyme loci assayed. Many of the features associated with CH and CL reproduction in M. polynoda are in accord with the theoretical requirements for the evolution of closed flower self-pollination and the maintenance of two distinct methods of reproduction.     

Apomixis for crop improvement

Summary Apomixis is a genetically controlled reproductive process by which embryos and seeds develop in the ovule without female meiosis and egg cell fertilization. Apomixis produces seed progeny that are exact replicas of the mother plant. The major advantage of apomixis over sexual reproduction is the possibility to select individuals with desirable gene combinations and to propagate them as clones. In contrast to clonal propagation through somatic embryogenesis or in vitro shoot multiplication, apomixis avoids the need for costly processes, such as the production of artificial seeds and tissue culture. It simplifies the processes of commercial hybrid and cultivar production and enables a large-scale seed production economically in both seed- and vegetatively propagated crops. In vegetatively reproduced plants (e.g., potato), the main applications of apomixis are the avoidance of phytosanitary threats and the spanning of unfavorable seasons. Because of its potential for crop improvement and global agricultural production, apomixis is now receiving increasing attention from both scientific and industrial sectors. Harnessing apomixis is a major goal in applied plant genetic engineering. In this regard, efforts are focused on genetic and breeding strategies in various plant species, combined with molecular methods to analyze apomictic and sexual modes of reproduction and to identify key regulatory genes and mechanisms underlying these processes. Also, investigations on the components of apomixis, i.e., apomeiosis, parthenogenesis, and endosperm development without fertilization, genetic screens for apomictic mutants and transgenic approaches to modify sexual reproduction by using various regulatory genes are receiving a major effort. These can open new avenues for the transfer of the apomixis trait to important crop species and will have far-reaching potentials in crop improvement regarding agricultural production and the quality of the products.     

Finding regulatory sequences

DNA regulatory sequences control gene expression by forming DNA-protein complex with specific DNA binding protein. A major task of studies of gene regulation is to identify DNA regulatory sequences in genome-wide. Especially with the rapid pace of genome project, the function of DNA regulatory sequences becomes one of the focuses in functional genome era. Several approaches for screening and characterizing DNA regulatory sequences emerged one by one, from initial low-throughput methods to high-throughput strategies. Even though at present bioinformatics tools facilitate the process of screening regulatory fragments, the most reliable results will come from experimental test. This article highlights some experimental methods for the identification of regulatory sequences. A brief review of the history and procedures for selection methods are provided. Tendency as well as limitation and extension of these methods are also presented.     

Chromosome engineering: power tools for plant genetics

The term "chromosome engineering" describes technologies in which chromosomes are manipulated to change their mode of genetic inheritance. This review examines recent innovations in chromosome engineering that promise to greatly increase the efficiency of plant breeding. Haploid Arabidopsis thaliana have been produced by altering the kinetochore protein CENH3, yielding instant homozygous lines. Haploid production will facilitate reverse breeding, a method that downregulates recombination to ensure progeny contain intact parental chromosomes. Another chromosome engineering success is the conversion of meiosis into mitosis, which produces diploid gametes that are clones of the parent plant. This is a key step in apomixis (asexual reproduction through seeds) and could help to preserve hybrid vigor in the future. New homologous recombination methods in plants will potentiate many chromosome engineering applications.     

Reconstruction of reproductive diversity in Hypericum perforatum L. opens novel strategies to manage apomixis

The mode of reproduction was characterized for 113 accessions of the tetraploid facultative apomictic species Hypericum perforatum using bulked or single mature seeds in the flow cytometric seed screen (FCSS). This screen discriminates several processes of sexual or asexual reproduction based on DNA contents of embryo and endosperm nuclei. Seed formation in H. perforatum proved to be highly polymorphic. Eleven different routes of reproduction were determined. For the first time, individual seeds were identified that originated from two embryo sacs: the endosperm from an aposporous and the embryo from the legitimate meiotic embryo sac. Moreover, diploid plants were discovered, which apparently reproduce by a hitherto unknown route of seed formation, that is chromosome doubling within aposporous initial cells followed by double fertilization. Although most plants were tetraploid and facultative sexual/apomictic, diploid obligate sexuals and tetraploid obligate apomicts could be selected. Additionally, genotypes were detected which at a high frequency produced embryos either from reduced parthenogenetic or unreduced fertilized egg cells. The endosperm developed most frequently after fertilization of the central cell in aposporous embryo sacs (pseudogamy) but in few cases also autonomously. The genetic control of apomixis appears to be complex in H. perforatum. Basic material was developed for breeding H. perforatum, and strategies are suggested for elucidation of inheritance as well as evolution of apomixis and for molecular approaches of apomixis engineering.     

Evolutionarily stable allocation to vegetative and sexual reproduction in plants

I apply the resource allocation approach to construct an ESS model aimed at predicting the rate of vegetative and sexual reproduction in plants. The model provides an integrated explanation of why the mode of reproduction should vary between populations and species, and what factors should affect the trade-off between ramet and seed production. It follows that seed production, usually considered to be less effective and more costly than ramet production, may be maintained in the population. The production of ramets should be favored when their recruitment rate is high or the costs are low. The intensity of vegetative reproduction is also related to conditions which affect seed production directly. The rate of ramet production should be inversely correlated with factors favoring sexual reproduction, such as lower cost of seeds or high opportunity for colonization of new patches, etc. Under such conditions it is beneficial to allocate more resources available for reproduction into seeds, at the expense of ramet production. The model emphasizes the need to consider both modes of plant reproduction whenever one of them is theoretically or empirically studied.     

Reproductive biology of Clintonia udensis

To clarify the life history of Clintonia udensis, we investigated its reproductive systems and spatio‐temporal population structure. Pollination experiments and the observation of floral visitors revealed that C. udensis was compatible with both self‐ and outcross‐pollen, and it potentially produces seeds by insect‐mediated outcrossing in natural conditions. In addition, propagation by clonal reproduction from rhizomes was evident. In this study, it was clarified that C. udensis potentially propagates by sexual and asexual reproduction and maintains its population through a stable frequency of flowering. The differences in the dependence on each reproduction mode could be one of the contributing factors for creating a variety of population sizes and distribution patterns of ramets in populations.     

Seed enhancement: getting seeds restoration‐ready

Seed enhancement technologies such as seed priming and seed coating, developed by the agricultural seed industry, are standard procedures for the majority of crop and horticultural seeds. However, such technologies are only just being evaluated for native plant seeds despite the potential benefits of such treatments for improving restoration effectiveness. Key approaches applicable to native seed include: (1) seed priming, where seeds are hydrated under controlled conditions, and (2) seed coating, in which external materials and compounds are applied onto seeds through a diversity of treatments. These technologies are commonly employed to accelerate and synchronize germination and to improve seed vigor, seedling emergence, establishment, and to facilitate mechanized seed delivery to site, through standardizing seed size and shape. Seed enhancement technologies have now been tested on native seeds to overcome logistical and ecological barriers in restoration. However, further research is needed to extend the application of seed enhancements to a broader array of species, ecosystems, and regions as well as to evaluate new and innovative approaches such as the incorporation of beneficial soil microorganisms and plant growth regulators in the coatings. As techniques in native seed enhancement develop, these approaches need to be capable of being scaled‐up to provide the tonnages of seed required for global restoration.     

Reproduction pathway analysis of several Hypericum perforatum L. somaclonal families

Flow cytometry seed screen of mature seeds originating from several in vitro regenerated Hypericum perforatum L. somaclones and their seed progenies were used to screen the ways of reproduction of 4 subsequent generations of several somaclonal families and to search for the relation between the ploidy and prevalent mode of reproduction. The prevalent reproduction pathway of diploid plants was sexual reproduction. Seed samples of plants with higher ploidy levels showed an extensive variation in the mode of reproduction: BII and BIII hybrid formation and/or aposporous pseudogamy including parthenogenetic development of a reduced embryo sac.