基于纳米基因载体的动植物遗传转化研究进展

转基因技术在动植物优良新品种的培育中发挥着重要作用,而随着纳米生物技术的发展,基于纳米材料构建基因载体的动植物转基因技术,对于发展动植物转基因新方法以及加速转基因种质材料的大规模制备、优良新品种的培育进程具有更为重要的意义。综述了纳米基因载体的种类与性质,并结合动植物遗传育种的研究进展,分析了纳米基因载体相比于其他载体的特点及优势,同时,重点阐述了基于纳米基因载体的基因转染技术的基本原理和操作过程,及其在动植物遗传转化中的应用,以期为动植物基因工程改造提供新思路。     

植物景观遗传学研究进展

植物景观遗传学是新兴的景观遗传学交叉学科的一个重要研究方向。目前植物景观遗传学的研究虽落后于动物,但其在生物多样性保护方面具有的巨大潜力不可忽视。从景观特征对遗传结构、环境因素对适应性遗传变异影响两个方面,系统综述了近十年来国际上植物景观遗传学的研究焦点和研究进展,比较了植物景观遗传学与动物景观遗传学研究在研究设计和研究方法上的异同,并基于将来植物景观遗传学由对空间遗传结构的描述发展为对景观遗传效应的量化分析及预测的发展框架,具体针对目前景观特征与遗传结构研究设计的系统性差、遗传结构与景观格局在时间上的误配、适应性位点与环境变量的模糊匹配、中性遗传变异与适应性遗传变异研究的分隔、景观与遗传关系分析方法的局限等五个方面提出了研究对策。     

Polar delivery in plants; commonalities and differences to animal epithelial cells

Although plant and animal cells use a similar core mechanism to deliver proteins to the plasma membrane, their different lifestyle, body organization and specific cell structures resulted in the acquisition of regulatory mechanisms that vary in the two kingdoms. In particular, cell polarity regulators do not seem to be conserved, because genes encoding key components are absent in plant genomes. In plants, the broad knowledge on polarity derives from the study of auxin transporters, the PIN-FORMED proteins, in the model plant Arabidopsis thaliana. In animals, much information is provided from the study of polarity in epithelial cells that exhibit basolateral and luminal apical polarities, separated by tight junctions. In this review, we summarize the similarities and differences of the polarization mechanisms between plants and animals and survey the main genetic approaches that have been used to characterize new genes involved in polarity establishment in plants, including the frequently used forward and reverse genetics screens as well as a novel chemical genetics approach that is expected to overcome the limitation of classical genetics methods.     

Landscape genetics of plants

Landscape genetics is the amalgamation of landscape ecology and population genetics to help with understanding microevolutionary processes such as gene flow and adaptation. In this review, we examine why landscape genetics of plants lags behind that of animals, both in number of studies and consideration of landscape elements. The classical landscape distance/resistance approach to study gene flow is challenging in plants, whereas boundary detection and the assessment of contemporary gene flow are more feasible. By contrast, the new field of landscape genetics of adaptive genetic variation, establishing the relationship between adaptive genomic regions and environmental factors in natural populations, is prominent in plant studies. Landscape genetics is ideally suited to study processes such as migration and adaptation under global change.     

The development of human genetics in Germany; a personal view

A personal account is given of the reconstruction and development of human genetics in Germany during the years following World War 2. An important stimulus was funding, as a result of the recognition of the genetic hazards of atomic radiation. Starting from 1960, human genetics institutes were progressively established throughout West Germany; comparable development was later in East Germany because of political factors. The first genetic counselling units were formed in 1972, but molecular biology only became an integral part of human genetics institutes at a relatively late stage. Close international links have characterised post-war human genetics in Germany from the outset and a tradition of close links with developing countries has also been established.     

Evolution by individuals,plant-herbivore interactions,and mosaics of genetic variability: The adaptive significance of somatic mutations in plants

Summary Differences in the pattern of organization of organisms may lead to different patterns of evolution, genetics and ecology, Plants and animals differ in their fundamental patterns of organization. Plants consist of a series of repeating units that compete with one another, while animals consist of mutually interdependent systems that cannot compete. As a result, plants may be able to take advantage of somatic mutations in ways that are not available to animals. Somatic mutations arising in plants can be inherited by naturally occurring mechanisms of sexual and asexual reproduction. Long life span, large clone size, and the complete regeneration of buds each year may permit an indivdual plant or clone to evolve. Plants may even develop as mosaics of genetic variation. Evolution by individual plants and/or development as mosaics of genetic variation may prevent herbivores from breaking the defenses of their host plants. This evolution may also result in greater fine tuning to local environments leading to ecotypic variation.     

番茄果重数量性状基因的研究进展及在遗传学教学中的应用

遗传学发展史上一系列经典的研究案例对学科的发展起了巨大的推动作用,将这些经典案例与教学内容相结合应用到遗传学课程教学中,对学生的科学思维和遗传分析能力是一个很好的训练。番茄果重基因的定位与克隆在数量性状基因座研究中是开创性的工作,完整的体现了植物数量性状基因的研究历程。将其作为一个综合案例应用于遗传学教学,可以生动直观地给学生展示一个精彩的科学发现过程,展现遗传学研究的魅力,激发学生的学习兴趣,收到了很好的教学效果。     

Cell genetic engineering: Transmission genetics of plants

Achievements of cell and genetic engineering that led to formation of a new genetics chapter— transmission genetics—have been described. Results have been analyzed and new opportunities in the field of transgenomic somatic hybrids and cybrid obtaining, production of transgenic plants with agronomic pharmaceutical application, development of transplastomic plants, and accumulation of recombinant proteins by using the transient expression of foreign genes in plants have been shown.     

Application of TILLING and EcoTILLING as Reverse Genetic Approaches to Elucidate the Function of Genes in Plants and Animals

With the fairly recent advent of inexpensive, rapid sequencing technologies that continue to improve sequencing efficiency and accuracy, many species of animals, plants, and microbes have annotated genomic information publicly available. The focus on genomics has thus been shifting from the collection of whole sequenced genomes to the study of functional genomics. Reverse genetic approaches have been used for many years to advance from sequence data to the resulting phenotype in an effort to deduce the function of a gene in the species of interest. Many of the currently used approaches (RNAi, gene knockout, site-directed mutagenesis, transposon tagging) rely on the creation of transgenic material, the development of which is not always feasible for many plant or animal species. TILLING is a non-transgenic reverse genetics approach that is applicable to all animal and plant species which can be mutagenized, regardless of its mating / pollinating system, ploidy level, or genome size. This approach requires prior DNA sequence information and takes advantage of a mismatch endonuclease to locate and detect induced mutations. Ultimately, it can provide an allelic series of silent, missense, nonsense, and splice site mutations to examine the effect of various mutations in a gene. TILLING has proven to be a practical, efficient, and an effective approach for functional genomic studies in numerous plant and animal species. EcoTILLING, which is a variant of TILLING, examines natural genetic variation in populations and has been successfully utilized in animals and plants to discover SNPs including rare ones. In this review, TILLING and EcoTILLING techniques, beneficial applications and limitations from plant and animal studies are discussed.Key Words: Reverse genetics, functional genomics, TILLING (target induced local lesions in genomes), EcoTILLING (Ecotype TILLING), sequencing, SNP (single nucleotide polymorphism), genetic stocks.     

Recent Developments in Human Behavioral Genetics: Past Accomplishments and Future Directions

The field of behavioral genetics has enormous potential to uncover both genetic and environmental influences on normal and deviant behavior. Behavioral-genetic methods are based on a solid foundation of theories and methods that successfully have delineated components of complex traits in plants and animals. New resources are now available to dissect the genetic component of these complex traits. As specific genes are identified, we can begin to explore how these interact with environmental factors in development. How we interpret such findings, how we ask new questions, how we celebrate the knowledge, and how we use or misuse this knowledge are all important considerations. These issues are pervasive in all areas of human research, and they are especially salient in human behavioral genetics.     

The emergence and development of genetics in Mexico

Early in the twentieth century it was shown that Mendel's laws apply to plants and animals and that genes reside on chromosomes. In the 1950s the double-helix model of DNA inaugurated the molecular biology era, which culminated at the end of the century with the publication of the human genome sequence. Although the early response to discoveries in genetics was slow in Mexico, the Green Revolution and other agricultural applications of genetic knowledge contributed greatly to economic welfare, and by the end of the millennium Mexican genetics had reached world-class status at several universities and research institutions.     

Genetic evidence for polarities that regulate leaf morphogenesis

Leaf morphogenesis is a fundamental process of shoot morphogenesis, since the leaf is the basic organ of the shoot. However, leaf morphogenesis is still poorly understood, in particular in dicotyledonous plants, because of the complex nature of the development of leaves. Thus, the mechanisms regulating each process of the morphogenesis, such as leaf determination, establishment of dorsoventrality, and polarity recognition, remain unknown. Developmental genetics seems to prove the most suitable approach to such processes and should allow us to dissect the relevant developmental pathways into genetically programmed, unit processes. The techniques of developmental genetics have been applied to studes of leaf morphogenesis of model plants, such asArabidopsis thaliana andAntirrhinum majus, and have recently revealed several important steps in leaf morphogenesis. The review will focus on genetic evidence for polarities that regulate leaf morphogenesis. Hypothetical mechanisms for leaf morphogenesis will be also discussed, based on the genetic data. Receipt of the Botanical Society Award of Young Scientists, 1996.     

The genetic architecture of natural variation in flower morphology

A pollination syndrome is defined as a suite of floral traits that are associated with the attraction of a specific group of animals as pollinators. Traits such as flower morphology, color, scent, and rewards contribute to the plant's reproductive success by attracting pollinators. Here we focus on the genetics of natural variation in flower morphology and how the adaptation between plants and their cognate pollinator class contributes to plant's reproductive success. We review recent work on the genetic basis of interspecific differences in reproductive organ morphology and discuss possible genetic mechanisms for coordinated changes in complex syndromes.     

A comparative study of distant hybridization in plants and animals

Distant hybridization refers to crosses between two different species, genera, or higher-ranking taxa, which can break species limits, increase genetic variation, and combine the biological characteristics of existing species. It is an important way of creating genetic variation, fertile strains, and excellent characteristics in new strains and populations. Combining analyses and summaries from many inter-related documents in plants and animals, both domestic and international, including examples and long-standing research on distant hybridization in fish from our laboratory, we summarize and compare the similarities and differences in plant and animal distant hybridization. In addition, we analyze and review the biological characteristics of their different ploidy progenies and the possible causes of disparity in survival rates. Mechanisms of sterility in animal and plant distant hybrids are also discussed, and research methods for the study of biological characteristics of hybrids, including morphology, cytology,and molecular cytogenetics are presented. This paper aims to provide comprehensive research materials and to systematically compare the general and specific characteristics of plant and animal hybrids with regards to reproduction, genetics, growth traits,and other biological characteristics. It is hoped that this paper will have great theoretical and practical significance for the study of genetic breeding and biological evolution of plant and animal distant hybridization.     

植物保护遗传学研究进展

保护遗传学是过用遗传学的原理和研究手段,以生物多样性尤其是遗传多样性的研究和保护为核心的一门新兴学科,近几十年来,遗传学研究在生物多样性保护的理论和实践中发挥着越来越重要的作用。本文简要回顾了保护遗传学的发展历史,研究方向和涉及的概念,着重介绍了植物保护遗传学研究所取得的一些进展,包括植物系统发育重建和保护单元的确定,遗传多样性与物种和群体适应性之间的关系,群体遗传结构与保护策略的制定以及植物遗传资源的鉴定和利用等方面的内容,并强调保护遗传学研究是未来生物多样性和保护生物学研究中一个亟待加强的研究领域。     

居群遗传学原理及其在珍稀濒危植物保护中的应用

居群遗传学在珍稀濒危植物保护研究中有着重要的应用价值。本文首先介绍了居群遗传学中的几个重要概念——有效居群大小、近交繁殖、遗传漂变和基因流,然后详细叙述了居群遗传学原理在珍稀濒危植物保护中的应用途径和前景。     

Understanding of genetic information in higher secondary students in northeast India and the implications for genetics education

Since the work of Watson and Crick in the mid-1950s, the science of genetics has become increasingly molecular. The development of recombinant DNA technologies by the agricultural and pharmaceutical industries led to the introduction of genetically modified organisms (GMOs). By the end of the twentieth century, reports of animal cloning and recent completion of the Human Genome Project (HGP), as well techniques developed for DNA fingerprinting, gene therapy and others, raised important ethical and social issues about the applications of such technologies. For citizens to understand these issues, appropriate genetics education is needed in schools. A good foundation in genetics also requires knowledge and understanding of topics such as structure and function of cells, cell division, and reproduction. Studies at the international level report poor understanding by students of genetics and genetic technologies, with widespread misconceptions at various levels. Similar studies were nearly absent in India. In this study, I examine Indian higher secondary students' understanding of genetic information related to cells and transmission of genetic information during reproduction. Although preliminary in nature, the results provide cause for concern over the status of genetics education in India. The nature of students' conceptual understandings and possible reasons for the observed lack of understanding are discussed.     

RNA沉默机制及其抗病毒应用

RNA沉默是发生在植物 (转录后基因沉默或共抑制 )、动物 (RNA干扰 )和真菌 (消除作用 )等真核生物细胞中的一种对外源遗传因子 (转座子、转基因或病毒 )的特异性和高效率的降解机制。随着对植物病毒分子遗传学认识的加深和对寄主防御系统研究的深入 ,发现了许多控制植物病毒病的方法 ,不过迄今为止最为成功的是通过RNA沉默机制获取抗病毒工程植株。在陈述了RNA沉默机制的研究最新进展基础上 ,提出了如何充分利用该机制进行植物抗病毒转基因研究。     

Genetic Analysis of Growth in Tomato: the F1 generation

Some aspects of the genetic control of plant development wereinvestigated by combining the methods of growth analysis withthose of quantitative genetics. Four varieties of Lycopersiconesculentum and one of L. pimpinellifolium were included in adiallel cross and the growth of parents and hybrids were followedover a IO-week period. Whole plants and plants with side-shootsremoved were studied. Significant differences in growth-ratewere found between varieties and between the reciprocal inter-specifichybrids; the latter difference followed from the maternal variationin seed size. The growth-rate was reduced by removing the side-shoots.A diallel analysis showed that the control of log fruit weightand number was largely additive but similar analysis of dryweight and leaf-area data showed considerable variation withtime. Extreme caution is, therefore, necessary in generalizingfrom a genetic analysis made at only one point of time. Thisdifficulty was largely overcome and much more information concerningthe inheritance of factors influencing plant development providedby carrying out a genetic analysis of the measured growth-rates.