基因组文库构建及其在保护遗传学中的应用前景

基因组文库是进行分子克隆和基因组结构与功能研究的基础。完整的基因组文库的构建, 使任何DNA 片段的筛选和获得成为可能。随着不同克隆载体的相继出现, 基因组文库也经历了一系列的发展过程。其中, BAC文库因其转化效率高、嵌合体少、插入片段易回收, 以及容载量较大等优点而被广泛应用。近几十年来, 随着环境的日益恶化、分子遗传学技术的迅速发展, 以及保护生物学和分子遗传学的不断相互渗透, 孕育产生了保护遗传学这一分支学科。作为保护遗传学中物种保护策略的重要部分, 建立濒危野生动植物的基因组文库, 是保存其种质资源的最为有效的实际手段和方法, 并能为进一步开展与生殖、疾病和重要经济性状等方面有关的功能基因的研究, 提供可靠的材料保证。     

水稻花色苷含量的遗传研究进展

花色苷作为水稻重要的生物活性物质,已成为当前功能性水稻研究开发的热点之一。本文从水稻花色苷的生物合成及其组成成分入手,着重介绍了水稻花色苷含量的影响因素、遗传及分子机理的研究现状以及富集花色苷水稻种质鉴定、筛选与创新现状,并探讨了今后以提高水稻花色苷含量为目标的功能性水稻研究内容和方向。     

A Manual Small Molecule Screen Approaching High-throughput Using Zebrafish Embryos

Zebrafish have become a widely used model organism to investigate the mechanisms that underlie developmental biology and to study human disease pathology due to their considerable degree of genetic conservation with humans. Chemical genetics entails testing the effect that small molecules have on a biological process and is becoming a popular translational research method to identify therapeutic compounds. Zebrafish are specifically appealing to use for chemical genetics because of their ability to produce large clutches of transparent embryos, which are externally fertilized. Furthermore, zebrafish embryos can be easily drug treated by the simple addition of a compound to the embryo media. Using whole-mount in situ hybridization (WISH), mRNA expression can be clearly visualized within zebrafish embryos. Together, using chemical genetics and WISH, the zebrafish becomes a potent whole organism context in which to determine the cellular and physiological effects of small molecules. Innovative advances have been made in technologies that utilize machine-based screening procedures, however for many labs such options are not accessible or remain cost-prohibitive. The protocol described here explains how to execute a manual high-throughput chemical genetic screen that requires basic resources and can be accomplished by a single individual or small team in an efficient period of time. Thus, this protocol provides a feasible strategy that can be implemented by research groups to perform chemical genetics in zebrafish, which can be useful for gaining fundamental insights into developmental processes, disease mechanisms, and to identify novel compounds and signaling pathways that have medically relevant applications.     

Mass Spectrometry–Driven Discovery of Neuropeptides Mediating Nictation Behavior of Nematodes

Neuropeptides regulate animal physiology and behavior, making them widely studied targets of functional genetics research. While the field often relies on differential -omics approaches to build hypotheses, no such method exists for neuropeptidomics. It would nonetheless be valuable for studying behaviors suspected to be regulated by neuropeptides, especially when little information is otherwise available. This includes nictation, a phoretic strategy of Caenorhabditis elegans dauers that parallels host-finding strategies of infective juveniles of many pathogenic nematodes. We here developed a targeted peptidomics method for the model organism C. elegans and show that 161 quantified neuropeptides are more abundant in its dauer stage compared with L3 juveniles. Many of these have orthologs in the commercially relevant pathogenic nematode Steinernema carpocapsae, in whose infective juveniles, we identified 126 neuropeptides in total. Through further behavioral genetics experiments, we identify flp-7 and flp-11 as novel regulators of nictation. Our work advances knowledge on the genetics of nictation behavior and adds comparative neuropeptidomics as a tool to functional genetics workflows.     

National Science Foundation-sponsored workshop report. Draft plan for soybean genomics

Recent efforts to coordinate and define a research strategy for soybean (Glycine max) genomics began with the establishment of a Soybean Genetics Executive Committee, which will serve as a communication focal point between the soybean research community and granting agencies. Secondly, a workshop was held to define a strategy to incorporate existing tools into a framework for advancing soybean genomics research. This workshop identified and ranked research priorities essential to making more informed decisions as to how to proceed with large scale sequencing and other genomics efforts. Most critical among these was the need to finalize a physical map and to obtain a better understanding of genome microstructure. Addressing these research needs will require pilot work on new technologies to demonstrate an ability to discriminate between recently duplicated regions in the soybean genome and pilot projects to analyze an adequate amount of random genome sequence to identify and catalog common repeats. The development of additional markers, reverse genetics tools, and bioinformatics is also necessary. Successful implementation of these goals will require close coordination among various working groups.     

TILLING - a shortcut in functional genomics

Recent advances in large-scale genome sequencing projects have opened up new possibilities for the application of conventional mutation techniques in not only forward but also reverse genetics strategies. TILLING (Targeting Induced Local Lesions IN Genomes) was developed a decade ago as an alternative to insertional mutagenesis. It takes advantage of classical mutagenesis, sequence availability and high-throughput screening for nucleotide polymorphisms in a targeted sequence. The main advantage of TILLING as a reverse genetics strategy is that it can be applied to any species, regardless of its genome size and ploidy level. The TILLING protocol provides a high frequency of point mutations distributed randomly in the genome. The great mutagenic potential of chemical agents to generate a high rate of nucleotide substitutions has been proven by the high density of mutations reported for TILLING populations in various plant species. For most of them, the analysis of several genes revealed 1 mutation/200–500 kb screened and much higher densities were observed for polyploid species, such as wheat. High-throughput TILLING permits the rapid and low-cost discovery of new alleles that are induced in plants. Several research centres have established a TILLING public service for various plant species. The recent trends in TILLING procedures rely on the diversification of bioinformatic tools, new methods of mutation detection, including mismatch-specific and sensitive endonucleases, but also various alternatives for LI-COR screening and single nucleotide polymorphism (SNP) discovery using next-generation sequencing technologies. The TILLING strategy has found numerous applications in functional genomics. Additionally, wide applications of this throughput method in basic and applied research have already been implemented through modifications of the original TILLING strategy, such as Ecotilling or Deletion TILLING.     

How science will help us move forward in 2021

In 2021, the genetics and genomics community needs to communicate to policymakers how the field of human genetics and genomics is transforming biomedical research and medicine, including its essential role in combatting COVID-19. This is important for ensuring that policies enable a thriving scientific enterprise and provide resources for research advances.

In 2021, the genetics and genomics community needs to communicate to policymakers how the field of human genetics and genomics is transforming biomedical research and medicine, including its essential role in combatting COVID-19. This is important for ensuring that policies enable a thriving scientific enterprise and provide resources for research advances.     

人类长寿相关基因研究进展

人类长寿是多因素、系统性生物学现象。衰老死亡是不可抗拒的自然规律,但通过科学研究可以延缓衰老达到延长寿命目的。影响长寿的因素可分为遗传和环境两种,其中遗传因素是决定长寿的内因,而环境因素则作为影响长寿的外因。本文介绍了人类长寿研究领域的研究现状和进展,概括人类长寿相关基因研究中取得的成果,并将人类染色体长寿相关基因归纳为三类,分别是控制炎症和代谢的长寿相关基因,以及控制信号通路的长寿相关基因,并进一步对三类基因中的代表性基因进行介绍。同时,对长寿研究的方向与未来提出了展望。     

2015年中国医学遗传学研究领域若干重要进展

2015年中国医学遗传学稳步发展,众多具有原创性的研究论文在国际顶级杂志上发表。中国科学家在医学遗传学的诸多领域,如罕见疾病的致病基因、复杂疾病的易感基因、癌症的体细胞突变、遗传学新方法新技术、疾病相关微小RNA(microRNA,miRNA)、疾病相关长链非编码RNA(Long non-coding RNA,lncRNA)、疾病相关竞争性内源RNA(Competing endogenous RNA,ceRNA)、疾病相关可变剪接和分子进化等研究领域均取得了突破性的进展。中国科学家在医学遗传学研究中逐步从常见变异延伸到罕见变异,从遗传学现象的描述到功能机制的确证,从单组学分析扩展至多组学数据整合,从基础研究走向临床应用。同时,中国科学家的研究成果引起了国际同行的高度关注。本文概括性综述了2015年中国科学家在医学遗传学领域取得的若干重要研究进展,旨在追踪当前中国医学遗传学领域发展的前沿,与国内读者分享我国科学家在该领域取得的重要成果以及研究思路。     

Linkage analysis of Schizophrenia: Challenges and promise

Abstract

Schizophrenia is a serious mental illness affecting nearly 1 per cent of the general population. Family, twin, and adoption studies suggest that genetics plays a major role in the etiology of schizophrenia. The inheritance pattern appears complex, similar to that of other common conditions like heart disease. To uncover a causal genetic factor, researchers have recently begun to apply a linkage analysis strategy to schizophrenia. Early results suggest that there are many challenges facing scientists who undertake schizophrenia genetics research. While one study has shown significant linkage of schizophrenia to a region on chromosome 5, several other studies have not found linkage to this area. The likelihood that there are several major genes predisposing to the illness and uncertainties about inheritance patterns and diagnostic boundaries are potential difficulties to overcome. Many more families need to be studied, and creative complementary research strategies pursued, to achieve the potential success offered by a genetic linkage approach.     

Efficient Generation of Recombinant Influenza A Viruses Employing a New Approach to Overcome the Genetic Instability of HA Segments

Influenza A viruses (IAVs) are the most relevant and continual source of severe infectious respiratory complications in humans and different animal species, especially poultry. Therefore, an efficient vaccination that elicits protective and neutralizing antibodies against the viral hemagglutinin (HA) and neuraminidase (NA) is an important strategy to counter annual epidemics or occasional pandemics. With the help of plasmid-based reverse genetics technology, it is possible that IAV vaccine strains (IVVS) are rapidly generated. However, the genetic instability of some cloned HA-cDNAs after transformation into competent bacteria represents a major obstacle. Herein, we report efficient cloning strategies of different genetically volatile HA segments (H5- and H9-subtypes) employing either a newly constructed vector for reverse genetics (pMKPccdB) or by the use of the Escherichia coli strain HB101. Both approaches represent improved and generalizable strategies to establish functional reverse genetics systems preventing genetic changes to the cloned (HA) segments of IAV facilitating more efficient rescue of recombinant IAV for basic research and vaccine development.     

CRISPR: a versatile tool for both forward and reverse genetics research

Human genetics research employs the two opposing approaches of forward and reverse genetics. While forward genetics identifies and links a mutation to an observed disease etiology, reverse genetics induces mutations in model organisms to study their role in disease. In most cases, causality for mutations identified by forward genetics is confirmed by reverse genetics through the development of genetically engineered animal models and an assessment of whether the model can recapitulate the disease. While many technological advances have helped improve these approaches, some gaps still remain. CRISPR/Cas (clustered regularly interspaced short palindromic repeats/CRISPR-associated), which has emerged as a revolutionary genetic engineering tool, holds great promise for closing such gaps. By combining the benefits of forward and reverse genetics, it has dramatically expedited human genetics research. We provide a perspective on the power of CRISPR-based forward and reverse genetics tools in human genetics and discuss its applications using some disease examples.     

Chemical genetics: exploring and controlling cellular processes with chemical probes.

The new field of chemical biology brings together chemists and biologists who are seeking to understand and mimic the natural world. One research strategy in this new field is the development of biologically active small molecules as molecular probes. This approach, which has been called 'chemical' genetics, has allowed elucidation of several pathways that have been difficult to study using traditional genetic approaches.     

Linkage analysis of schizophrenia: challenges and promise.

Schizophrenia is a serious mental illness affecting nearly 1 per cent of the general population. Family, twin, and adoption studies suggest that genetics plays a major role in the etiology of schizophrenia. The inheritance pattern appears complex, similar to that of other common conditions like heart disease. To uncover a causal genetic factor, researchers have recently begun to apply a linkage analysis strategy to schizophrenia. Early results suggest that there are many challenges facing scientists who undertake schizophrenia genetics research. While one study has shown significant linkage of schizophrenia to a region on chromosome 5, several other studies have not found linkage to this area. The likelihood that there are several major genes predisposing to the illness and uncertainties about inheritance patterns and diagnostic boundaries are potential difficulties to overcome. Many more families need to be studied, and creative complementary research strategies pursued, to achieve the potential success offered by a genetic linkage approach.     

Integrating climate change and habitat fragmentation to identify candidate seed sources for ecological restoration

Anthropogenic change (climate change and habitat fragmentation) is driving a growing view that local seed collections may need to be supplemented with nonlocal seed as a strategy to bolster genetic diversity and thus increase evolutionary potential of plantings. While this strategy is becoming widely promoted, empirical support is limited, and there is a lack of accessible research tools to assist in its experimental testing. We therefore provide the Provenancing Using Climate Analogues (PUCA) framework that integrates the principles of the climate‐adjusted provenancing strategy with concepts from population genetics (i.e. potential inbreeding in small fragmented populations) as both a research and operational‐ready tool to guide the collection of nonlocal seed. We demonstrate the application of PUCA using the Midlands of Tasmania, Australia, a region that is currently undergoing large‐scale ecological restoration. We highlight multiple nonlocal seed sources for testing by identifying actual species distribution records that currently occupy environments similar to that projected to occur at the restoration site in the future. We discuss the assumptions of PUCA and the ecological considerations that need to be tested when moving nonlocal genotypes across the landscape.     

Biology Teaching in West Africa

Simulation games designed as training exercises have been used in a wide variety of fields. With the exception of medical education they have as yet been little used in teaching science. Lebemo is a game simulating research in bacterial genetics. The player has to manipulate data, interpret results, plan an overall strategy, and decide upon appropriate experimental protocols; a combination of features found in research and project work but rarely in traditional laboratory classes. In its present form Lebemo is self-instructional and takes a few hours to play. Lebemo and games like it might prove useful adjuncts to traditional laboratory classes and could perhaps replace more time-consuming project work.     

Discovery genetics: serendipity in basic research

The role of serendipity in science has no better example than the discovery of spontaneous mutations that leads to new mouse models for research. The approach of finding phenotypes and then carrying out genetic analysis is called forward genetics. Serendipity is a key component of discovering and developing mice with spontaneous mutations into animal models of human disease. In this article, the role of serendipity in discovering and developing mouse models is described within a program at The Jackson Laboratory that capitalizes on serendipitous discoveries in large breeding colonies. Also described is how any scientists working with mice can take advantage of serendipitous discoveries as a research strategy to develop new models. Spontaneous mutations cannot be planned but happen in all research mouse colonies and are discovered as unexpected phenotypes. The alert scientist or technician can rationally exploit such chance observations to create new research opportunities.     

Forward from the crossroads of ecology and evolution

Community genetics is a synthesis of community ecology and evolutionary biology. It examines how genetic variation within a species affects interactions among species to change ecological community structure and diversity. The use of community genetics approaches has greatly expanded in recent years and the evidence for ecological effects of genetic diversity is growing. The goal of current community genetics research is to determine the circumstances in which, and the mechanisms by which community genetic effects occur and is the focus of the papers in this special issue. We bring a new group of researchers into the community genetics fold. Using a mixture of empirical research, literature reviews and theoretical development, we introduce novel concepts and methods that we hope will enable us to develop community genetics into the future.     

Whiteness studies and laypeople's engagements with race and genetics

This paper proposes a research strategy for examining laypeople's thoughts and reflections on innovations in the science of race and genetics. While some sociologists have shown a reluctance to engage in such discussions, this paper argues that social scientists need to take such views seriously. To do this, the paper brings together an anthropological approach to the study of scientific literacy and recent scholarship in the field of Whiteness studies. The combining of these literatures raises a set of interesting and sometimes uncomfortable questions about the ways in which social scientists and research participants contribute to the reproduction of White power and dominance in Western societies.     

新一代测序技术在遗传性耳聋基因研究及诊断中的应用

超过50%的耳聋由遗传基因缺陷所致,伴随着基因组学技术的发展,耳聋分子遗传学研究逐渐成为耳科学研究的前沿领域。新一代高通量测序技术的出现,提供了以数据为导向的新的遗传性疾病研究模式,革新了人们对遗传性疾病的认识过程,使得对遗传性疾病的研究策略也发生了重大转变。近年来新一代测序技术(Next generation sequencing,NGS)在耳聋研究中的应用,大大加快了耳聋基因发现的速度,并逐渐向临床应用方向转化。文章总结了遗传性耳聋的特点和研究现状,以及新一代测序技术在耳聋研究中的应用和前景,以及基于NGS技术的耳聋基因研究和临床耳聋基因诊断的发展方向。