基于直向同源序列的比较基因组学研究

直向同源序列在不同的物种中具有相近甚至相同的功能、相似的调控途径, 扮演相似甚至相同的角色, 而且, 绝大多数核心生物功能就是由相当数量的直向同源基因所承担, 它是基因组序列的功能注释与分析中最可靠的选择, 其特殊的生物学特性决定: 利用直向同源序列开展比较基因组学研究, 必将为探测不同生物在进化过程中重要功能基因的出现、表达和丢失提供线索。文章从直向同源基因的基本特性、直向同源序列与比较基因组学的关系、应用直向同源序列开展比较基因组学相关研究方法、现状等展开综述。关键词: 直向同源; 比较基因组学; 生物学特性; 数据库     

硒代谢网络与硒蛋白质组的生物信息学研究进展

硒是大多数生物所必需的微量元素,对维持氧化还原稳态平衡具有重要作用,并与许多重大疾病有着密切联系。一直以来,关于硒的研究工作主要集中于硒代谢机制和硒蛋白功能。近年来快速增长的各类组学数据为硒相关的生物信息学研究工作提供了重要条件与机遇。主要介绍了当前利用生物信息学的理论和方法研究硒的代谢通路、功能和进化等领域的最新进展。通过这些研究,一方面发现了大量新的硒蛋白基因,并确定了众多物种的硒蛋白质组;另一方面揭示了新的硒代谢通路及相关新基因,完善了硒代谢网络。在此基础上,通过比较基因组学分析,深入探讨了硒代谢通路、不同硒蛋白家族乃至硒蛋白质组的分布与进化规律,以期为进一步认识硒研究领域中的重要问题和未来的发展方向提供支持。     

主要禾谷类作物比较基因组学研究策略与进展

随着拟南芥、水稻等模式植物基因组测序计划的完成, 比较基因组学作为一门新兴学科, 近年来发展迅速, 为植物基因组的进化、结构和功能研究开辟了新的途径。文章综述了比较基因组学在作物比较遗传作图、基因结构区域的微共线性、ESTs和蛋白质水平的比较以及基于比较基因组学的基因和QTL的克隆等方面内容与研究进展, 分析了不同水平上比较基因组学研究策略的原理、特点、可行性, 以期为利用模式生物的基因和基因组数据、采用比较基因组学策略克隆作物重要性状功能基因、阐明基因组结构与进化提供帮助。     

比较基因组学及其应用

比较基因组学是利用某些基因组图谱和测序获得的信息推测其他生物基因组的基因数目、位置、功能、表达机制和物种进化的学科。比较基因组学的发展与序列数据的积累密切相关,目前该学科已经成为研究生物基因组的最主要手段之一。利用FASTA、BLAST和CLUSTAL W等序列比对工具,种间的比较基因组学能够让人们了解物种间在基因组结构上的差异,发现基因的功能、物种的进化关系,以及进行功能基因的克隆。种内的比较基因组学研究主要涉及个体或群体基因组内诸如SNP、CNP等变异和多态现象。比较基因组学的研究结果不但有助于深入了解生命体的遗传机制,也有助于阐明人类复杂疾病的致病机制,揭示生命的本质规律。     

模式生物斑马鱼在微量元素代谢研究中的应用

微量元素如铁、锌、铜等对维持生物体代谢和健康至关重要,其含量失衡会造成代谢异常甚至死亡,因此生物体存在复杂机制维持这些微量元素的稳态代谢平衡（homeostasis）。近年来国际上一些实验室尝试用模式脊椎生物斑马鱼来开展该领域的研究,展示出斑马鱼的特有优势。特别是大规模正向遗传学筛选的成功开展,一系列微量元素代谢异常的突变体（如：weissherbst、chardonnay、chianti、shiraz、gavi、calamity和catastrophe）相继发现,为研究离子代谢调控机制和相关疾病的发病机理,提供了整体动态的活体模型。铁代谢相关基因加,2J和grx5都己在斑马鱼中成功定位克隆,斑马鱼铜载体基因atp7a突变体calamity的深入研究,进一步阐明了Menkes病的发病机理。利用斑马鱼的优势,结合小鼠模型和人群来研究微量元素的体内稳态代谢平衡将是微量元素代谢机制研究的新方向。     

试析世纪之交植物生理学研究的动向

简要介绍了当今植物生理学研究中值得注意的四个动向,它们是从研究生物大分子到阐明复杂生命活动——基因组学、基因结构与功能的研究;实现生命整体性的重要环节——信号传递的研究;生命活动的能量和物质基础——代谢及其调节的研究;植物与环境(非生物和生物环境)的相互关系——生物的协同进化和适应的研究。     

基因组学方法在植物抗逆性研究中的应用

由于植物抗逆性遗传极其复杂,因而植物抗逆性能（包括抗非生物胁迫如盐碱,干旱,低温等的能力和抗生物协迫如真菌,细菌,病毒和线虫的能力等）的提高受到了极大限制,近年来,基因组学的兴起对我们全面理解植物抗逆性起着革命性作用,结果基因组学将会使我们挖大量全新的抗逆基因,并能揭示各抗逆性基因的详细结构以及抗逆性遗传进化机理,功能基因组学将会阐明植物抗逆中的复杂的调控,网络,揭示涉及抗逆蛋白的多样性,通过比较基因学的研究,可以把从模式植物上获得的抗逆遗传信息推广到基因组较复杂的植物上去,大规模的全新基因的发现及其在抗逆反应中的表达模式的研究和它们在抗逆应中作用的理解将会利用遗传工程进行植物抗逆育种提供广阔的前景。     

动物储铁蛋白研究进展

铁元素是生物体中必不可少的微量元素,在生物的生长发育中发挥着重要作用。铁蛋白是一种分布广泛的球形蛋白,能够以稳定的形式储存大量铁。铁蛋白通过储存和释放铁来维持机体内铁平衡。铁蛋白不仅是机体中重要的铁储存蛋白,同时也能有效保护生物体免受来自氧自由基的损伤。与此同时,铁蛋白含量可以作为一些疾病预防检测的明确指标。对铁的代谢吸收及铁对基因调控的研究,进一步说明了维持铁平衡对生物体有重要意义。     

嗜酸氧化亚铁硫杆菌基因组学研究进展

嗜酸氧化亚铁硫杆菌(Acidithiobacillus ferrooxidan,A.ferrooxidans)广泛存在于酸性矿物废水中,与生物冶金和环境净化紧密相关。不同来源嗜酸氧化亚铁硫杆菌全基因组的测序,为我们利用比较基因组学和功能基因组学的方法去洞察嗜酸氧化亚铁硫杆菌功能基因,提供了坚实的研究基础和丰富的科研信息。简述了嗜酸氧化亚铁硫杆菌基因组学的基本特征;从比较基因组学和功能基因组学发现了嗜酸氧化亚铁硫杆菌菌株基因组水平的差异;通过生物信息学概述了该菌的铁和硫代谢机制,并从细菌的功能基因组学对其在生物冶金与环境治理等应用进行了展望。     

藻类对微量元素的生物富集及其应用

生物富集（bioenrichment）又04生物浓缩（bioconcentration）或生物积聚（bioacct－unulahon）,是指生物体从周围环境中蓄积某种元素或难分解的化合物,从而使该物质浓度超过环境中其浓度的现象,富集的程度可以用富集系数即生物体中某富集物浓度与环境中该物质浓度之比来表示［l］藻类对许多微量元素具有较强的生物富集能力,可作为生物吸附剂广泛应用于污水处理、水质净化［2.3］;稀有、贵重金属和放射性物质的回收［4］;痕量、超痕量元素分析［5.6］;高附加值生物的培养等方面［7~9］。利用藻类富集微量元素具有经济、高效、选择性…     

Comparative genomics of trace element dependence in biology

Biological trace elements are needed in small quantities but are used by all living organisms. A growing list of trace element-dependent proteins and trace element utilization pathways highlights the importance of these elements for life. In this minireview, we focus on recent advances in comparative genomics of trace elements and explore the evolutionary dynamics of the dependence of user proteins on these elements. Many zinc protein families evolved representatives that lack this metal, whereas selenocysteine in proteins is dynamically exchanged with cysteine. Several other elements, such as molybdenum and nickel, have a limited number of user protein families, but they are strictly dependent on these metals. Comparative genomics of trace elements provides a foundation for investigating the fundamental properties, functions, and evolutionary dynamics of trace element dependence in biology.     

General Trends in Trace Element Utilization Revealed by Comparative Genomic Analyses of Co, Cu, Mo, Ni, and Se

Trace elements are used by all organisms and provide proteins with unique coordination and catalytic and electron transfer properties. Although many trace element-containing proteins are well characterized, little is known about the general trends in trace element utilization. We carried out comparative genomic analyses of copper, molybdenum, nickel, cobalt (in the form of vitamin B₁₂), and selenium (in the form of selenocysteine) in 747 sequenced organisms at the following levels: (i) transporters and transport-related proteins, (ii) cofactor biosynthesis traits, and (iii) trace element-dependent proteins. Few organisms were found to utilize all five trace elements, whereas many symbionts, parasites, and yeasts used only one or none of these elements. Investigation of metalloproteomes and selenoproteomes revealed examples of increased utilization of proteins that use copper in land plants, cobalt in Dehalococcoides and Dictyostelium, and selenium in fish and algae, whereas nematodes were found to have great diversity of copper transporters. These analyses also characterized trace element metabolism in common model organisms and suggested new model organisms for experimental studies of individual trace elements. Mismatches in the occurrence of user proteins and corresponding transport systems revealed deficiencies in our understanding of trace element biology. Biological interactions among some trace elements were observed; however, such links were limited, and trace elements generally had unique utilization patterns. Finally, environmental factors, such as oxygen requirement and habitat, correlated with the utilization of certain trace elements. These data provide insights into the general features of utilization and evolution of trace elements in the three domains of life.     

Biogeographic and Evolutionary Patterns of Trace Element Utilization in Marine Microbial World

Trace elements are required by all organisms, which are key components of many enzymes catalyzing important biological reactions. Many trace element-dependent proteins have been characterized; however, little is known about their occurrence in microbial communities in diverse environments, especially the global marine ecosystem. Moreover, the relationships between trace element utilization and different types of environmental stressors are unclear. In this study, we used metagenomic data from the Global Ocean Sampling expedition project to identify the biogeographic distribution of genes encoding trace element-dependent proteins (for copper, molybdenum, cobalt, nickel, and selenium) in a variety of marine and non-marine aquatic samples. More than 56,000 metalloprotein and selenoprotein genes corresponding to nearly 100 families were predicted, becoming the largest dataset of marine metalloprotein and selenoprotein genes reported to date. In addition, samples with enriched or depleted metalloprotein/selenoprotein genes were identified, suggesting an active or inactive usage of these micronutrients in various sites. Further analysis of interactions among the elements showed significant correlations between some of them, especially those between nickel and selenium/copper. Finally, investigation of the relationships between environmental conditions and metalloprotein/selenoprotein families revealed that many environmental factors might contribute to the evolution of different metalloprotein and/or selenoprotein genes in the marine microbial world. Our data provide new insights into the utilization and biological roles of these trace elements in extant marine microbes, and might also be helpful for the understanding of how these organisms have adapted to their local environments.     

Comparative genomic analyses of nickel, cobalt and vitamin B12 utilization

Background

Nickel (Ni) and cobalt (Co) are trace elements required for a variety of biological processes. Ni is directly coordinated by proteins, whereas Co is mainly used as a component of vitamin B₁₂. Although a number of Ni and Co-dependent enzymes have been characterized, systematic evolutionary analyses of utilization of these metals are limited.

Results

We carried out comparative genomic analyses to examine occurrence and evolutionary dynamics of the use of Ni and Co at the level of (i) transport systems, and (ii) metalloproteomes. Our data show that both metals are widely used in bacteria and archaea. Cbi/NikMNQO is the most common prokaryotic Ni/Co transporter, while Ni-dependent urease and Ni-Fe hydrogenase, and B₁₂-dependent methionine synthase (MetH), ribonucleotide reductase and methylmalonyl-CoA mutase are the most widespread metalloproteins for Ni and Co, respectively. Occurrence of other metalloenzymes showed a mosaic distribution and a new B₁₂-dependent protein family was predicted. Deltaproteobacteria and Methanosarcina generally have larger Ni- and Co-dependent proteomes. On the other hand, utilization of these two metals is limited in eukaryotes, and very few of these organisms utilize both of them. The Ni-utilizing eukaryotes are mostly fungi (except saccharomycotina) and plants, whereas most B₁₂-utilizing organisms are animals. The NiCoT transporter family is the most widespread eukaryotic Ni transporter, and eukaryotic urease and MetH are the most common Ni- and B₁₂-dependent enzymes, respectively. Finally, investigation of environmental and other conditions and identity of organisms that show dependence on Ni or Co revealed that host-associated organisms (particularly obligate intracellular parasites and endosymbionts) have a tendency for loss of Ni/Co utilization.

Conclusion

Our data provide information on the evolutionary dynamics of Ni and Co utilization and highlight widespread use of these metals in the three domains of life, yet only a limited number of user proteins.     

Prediction of functionally related proteins by comparative genomics in silico

The review considers the computational prediction of functionally related proteins by comparative genomics. Growing possibilities of biotechnology for genome sequencing lead to generation of sequences for millions of genes. However, functions of majority of these genes remain unknown, and can be determined experimentally only for a few of them. Therefore, accurate and robust methods for in silico prediction (annotation) of gene functions are needed. We describe here the main techniques of comparative genomics, including the standard method based on transferring functions between homologous sequences and also context-based methods, including phylogenetic profiles and gene-neighbor approaches. Modern methods of comparative genomics allow obtaining correct functional annotations for more than a half of all organism proteins.     

The rapidly evolving field of plant centromeres

Meiotic and mitotic chromosome segregation are highly conserved in eukaryotic organisms, yet centromeres--the chromosomal sites that mediate segregation--evolve extremely rapidly. Plant centromeres have DNA elements that are shared across species, yet they diverge rapidly through large- and small-scale changes. Over evolutionary time-scales, centromeres migrate to non-centromeric regions and, in plants, heterochromatic knobs can acquire centromere activity. Discerning the functional significance of these changes will require comparative analyses of closely related species. Combined with functional assays, continued efforts in plant genomics will uncover key DNA elements that allow centromeres to retain their role in chromosome segregation while allowing rapid evolution.     

Trace elements incorporated into the culture medium of Mycobacterium tuberculosis promote the presence of tuberculoprotein C in the preparation of purified protein derivatives

Two purified protein derivatives (PPDs) were prepared from Mycobacterium tuberculosis, H37Ra. One of the PPDs was prepared from the culture filtrate of organisms grown on Proskauer-Beck medium to which trace elements had been added. The other PPD was prepared from the culture filtrate of organisms grown on the same medium but without trace elements, and was used as the control. Comparative skin reactions in sensitized rabbits showed that the PPD prepared from organisms grown in the presence of trace elements was less potent than the control. Since it has long been recognized that of the many tuberculoproteins present in PPD, the C protein (a 44 to 66 kDa protein) was always the least potent fraction when tested in equivalent concentrations in both serological and skin test assays, the possibility existed that the PPD obtained from organisms grown in trace element medium had more of the C protein complex than the control. Comparative studies of these two PPDs in terms of their chemical composition, skin test responses, and electrophoretic profiles obtained by SDS-polyacrylamide gel electrophoresis provide support for this assumption.     

Comparative genomic analyses of copper transporters and cuproproteomes reveal evolutionary dynamics of copper utilization and its link to oxygen

Copper is an essential trace element in many organisms and is utilized in all domains of life. It is often used as a cofactor of redox proteins, but is also a toxic metal ion. Intracellular copper must be carefully handled to prevent the formation of reactive oxygen species which pose a threat to DNA, lipids, and proteins. In this work, we examined patterns of copper utilization in prokaryotes by analyzing the occurrence of copper transporters and copper-containing proteins. Many organisms, including those that lack copper-dependent proteins, had copper exporters, likely to protect against copper ions that inadvertently enter the cell. We found that copper use is widespread among prokaryotes, but also identified several phyla that lack cuproproteins. This is in contrast to the use of other trace elements, such as selenium, which shows more scattered and reduced usage, yet larger selenoproteomes. Copper transporters had different patterns of occurrence than cuproproteins, suggesting that the pathways of copper utilization and copper detoxification are independent of each other. We present evidence that organisms living in oxygen-rich environments utilize copper, whereas the majority of anaerobic organisms do not. In addition, among copper users, cuproproteomes of aerobic organisms were larger than those of anaerobic organisms. Prokaryotic cuproproteomes were small and dominated by a single protein, cytochrome c oxidase. The data are consistent with the idea that proteins evolved to utilize copper following the oxygenation of the Earth.     

Molybdoproteomes and evolution of molybdenum utilization

The trace element molybdenum (Mo) is utilized in many life forms, and it is a key component of several enzymes involved in nitrogen, sulfur, and carbon metabolism. With the exception of nitrogenase, Mo is bound in proteins to a pterin, thus forming the molybdenum cofactor (Moco) at the catalytic sites of molybdoenzymes. Although a number of molybdoenzymes are well characterized structurally and functionally, evolutionary analyses of Mo utilization are limited. Here, we carried out comparative genomic and phylogenetic analyses to examine the occurrence and evolution of Mo utilization in bacteria, archaea and eukaryotes at the level of (i) Mo transport and Moco utilization trait, and (ii) Mo-dependent enzymes. Our results revealed that most prokaryotes and all higher eukaryotes utilize Mo whereas many unicellular eukaryotes including parasites and most yeasts lost the ability to use this metal. In addition, eukaryotes have fewer molybdoenzyme families than prokaryotes. Dimethylsulfoxide reductase (DMSOR) and sulfite oxidase (SO) families were the most widespread molybdoenzymes in prokaryotes and eukaryotes, respectively. A distant group of the ModABC transport system, was predicted in the hyperthermophilic archaeon Pyrobaculum. ModE-type regulation of Mo uptake occurred in less than 30% of Moco-utilizing organisms. A link between Mo and selenocysteine utilization in prokaryotes was also identified wherein the selenocysteine trait was largely a subset of the Mo trait, presumably due to formate dehydrogenase, a Mo- and selenium-containing protein. Finally, analysis of environmental conditions and organisms that do or do not depend on Mo revealed that host-associated organisms and organisms with low G + C content tend to reduce their Mo utilization. Overall, our data provide new insights into Mo utilization and show its wide occurrence, yet limited use of this metal in individual organisms in all three domains of life.     

Genome-assisted analysis of dissimilatory metal-reducing bacteria

The availability of whole genome sequences for Shewanella oneidensis and Geobacter sulfurreducens has provided numerous new biological insights into the function of these model dissimilatory metal-reducing bacteria. Many of these findings, including the identification of a high number of c-type cytochromes in both organisms, have resulted from comparative genomic analyses, and several have been experimentally confirmed. These genome sequences have also aided the identification of genes important for the reduction of metal ions and other electron acceptors utilized during anaerobic growth, by facilitating the identification of genes disrupted by random insertions. Technologies for assaying global expression patterns for genes and proteins have also been employed, but their application has been limited mainly to the analysis of the role of global regulatory genes and to identifying genes expressed or repressed in response to specific electron acceptors. It is anticipated that details of the mechanisms of metal ion respiration, and metabolism in general, will eventually be revealed by comprehensive, systems-level analyses enabled by functional genomics data.