Prokaryotic Suppression Subtractive Hybridization PCR cDNA Subtraction, a Targeted Method To Identify Differentially Expressed Genes

Molecular biology tools can be used to monitor and optimize biological treatment systems, but the application of nucleic acid-based tools has been hindered by the lack of available sequences for environmentally relevant biodegradation genes. The objective of our work was to extend an existing molecular method for eukaryotes to prokaryotes, allowing us to rapidly identify differentially expressed genes for subsequent sequencing. Suppression subtractive hybridization (SSH) PCR cDNA subtraction is a technique that can be used to identify genes that are expressed under specific conditions (e.g., growth on a given pollutant). While excellent methods for eukaryotic SSH PCR cDNA subtraction are available, to our knowledge, no methods previously existed for prokaryotes. This work describes our methodology for prokaryotic SSH PCR cDNA subtraction, which we validated using a model system: Pseudomonas putida mt-2 degrading toluene. cDNA from P. putida mt-2 grown on toluene (model pollutant) or acetate (control substrate) was subjected to our prokaryotic SSH PCR cDNA subtraction protocol to generate subtraction clone libraries. Over 90% of the sequenced clones contained gene fragments encoding toluene-related enzymes, and 20 distinct toluene-related genes from three key operons were sequenced. Based on these results, prokaryotic SSH PCR cDNA subtraction shows promise as a targeted method for gene identification.     

TB tools to tell the tale-molecular genetic methods for mycobacterial research

In spite of the availability of drugs and a vaccine, tuberculosis--one of man's medical nemeses--remains a formidable public health problem, particularly in the developing world. The persistent nature of the tubercle bacillus, with one third of the world's population is estimated to be infected, combined with the emergence of multi drug-resistant strains and the exquisite susceptibility of HIV-positive individuals, has underscored the urgent need for in-depth study of the biology of Mycobacterium tuberculosis address the resurgence of TB. In aiming to understand the mechanisms by which mycobacteria react to their immediate environments, molecular genetic tools have been developed from naturally occurring genetic elements. These include protein expressing genes, and episomal and integrating elements, which have been derived mainly from prokaryotic but also from eukaryotic organisms. Molecular genetic tools that had been established as routine procedures in other prokaryotic genera were thus mimicked. Knowledge of the underlying mechanisms greatly expedited the harnessing of these elements for mycobacteriological research and has brought us to a point where these molecular genetic tools are now employed routinely in laboratories worldwide.     

Functional bias in molecular evolution rate of <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

Background  

Characteristics derived from mutation and other mechanisms that are advantageous for survival are often preserved during evolution by natural selection. Some genes are conserved in many organisms because they are responsible for fundamental biological function, others are conserved for their unique functional characteristics. Therefore one would expect the rate of molecular evolution for individual genes to be dependent on their biological function. Whether this expectation holds for genes duplicated by whole genome duplication is not known.     

Screening for ribosomal-based false positives following prokaryotic mRNA differential display

Differential display (DD) and the closely related RNA arbitrarily primed PCR (RAP-PCR) have become the molecular tools of choice for identifying and isolating differentially expressed genes in both eukaryotic and prokaryotic systems. However, one of the current drawbacks of both techniques is the high number of false positives generated. In prokaryotic applications, the many false positive typically generated by DD are subsequently identified as rRNAs because of their greater abundance compared to mRNAs. To circumvent this problem, full-length 16S and 23S rDNA probes, derived from Pseudomonas putida G7 and Pseudomonas aeruginosa FRD1, respectively, were used as a prescreening approach to discriminate between those bands, which appear to be differentially expressed mRNAs, but in fact are rRNAs, following prokaryotic mRNA DD.     

Observing development through evolutionary eyes: a practical approach.

An argument is made that only through a detailed comparison of mutational mechanisms underlying the evolution of the genetic systems governing development, can the 'logic' of individual development be fully comprehended. To do this, it is essential to choose two or more genes (or their products) that interact in the establishment of a given function, and to compare the molecular basis of that interaction in closely related species. The rationale to this approach arises from observations of molecular co-evolution between interacting partners involved with given functions which have led to species specificity in the manner in which such functions are effected. Molecular coevolution reveals that divergence in sequence can be tolerated whilst biological functions are maintained, not because it is neutral and dispensable but because successful, compensatory changes can evolve in eukaryotic genomes that are in continuous states of flux.     

Microbial systematics in the post-genomics era

Microbial systematics and phylogeny should form the foundation and guiding light for a comprehensive understanding of different aspects of microbiology. However, there are many critical issues in microbial systematics that are currently not resolved. Some of these include: how to define and delimit a prokaryotic species; development of rationale criteria for the assignment of higher taxonomic ranks; understanding what unique properties distinguish species from different groups; and understanding the branching order and interrelationship among higher prokaryotic clades. The sequencing of genomes from large numbers of cultured as well as uncultured microbes covering prokaryotic diversity provides unique means to achieve these important objectives. Prokaryotic genomes are found to be very diverse and dynamic and horizontal gene transfers (HGTs) are indicated to have played important role in species/genome evolution. Although HGT adds a layer of complexity in terms of understanding the genomes and species evolution, it is contended that vast majority of genes and genetic characteristics that are distinctive characteristics of higher prokaryotic taxa are vertically inherited and based on them a solid foundation for microbial systematics can be developed. We describe two kinds of molecular markers consisting of conserved indels in protein sequences and whole proteins that are specific for different groups that are proving particularly valuable in defining different prokaryotic groups in clear molecular terms and in understanding their interrelationships. The genetic and biochemical studies on these taxa-specific molecular markers also open the way to discover novel biochemical and physiological characteristics that are unique properties of these groups.     

All in good time: the Arabidopsis circadian clock

Biological time-keeping mechanisms have fascinated researchers since the movement of leaves with a daily rhythm was first described >270 years ago. The circadian clock confers a approximately 24-hour rhythm on a range of processes including leaf movements and the expression of some genes. Molecular mechanisms and components underlying clock function have been described in recent years for several animal and prokaryotic organisms, and those of plants are beginning to be characterized. The emerging model of the Arabidopsis clock has mechanistic parallels with the clocks of other model organisms, which consist of positive and negative feedback loops, but the molecular components appear to be unique to plants.     

Polydnavirus genome: integrated vs. free virus

Polydnaviruses are unique because of their obligatory association with thousands of parasitoid wasp species from the braconid and ichneumonid families of hymenopterans. PDVs are injected into the parasitized hosts and are essential for parasitism success. However, polydnaviruses are also unique because of their genome composed of multiple dsDNA segments. Cytological evidence has recently confirmed the results of genetic and molecular analyses indicating that PDV segments were integrated in the wasp genome. Moreover a phylogenetic study performed using the age of available fossils to calibrate the molecular clock indicated that the polydnaviruses harboured by braconid wasps have resided within the wasp genome for approximately 70 million years. In the absence of horizontal transmission, the evolution of the PDV genomes has been driven exclusively by the reproductive success they have offered the wasps. The consequences of this particular selection pressure can be observed in the gene content of certain PDV genomes from which increasing sequence data are available. Molecular mechanisms already identified could be involved in the acquisition and loss of genes by the PDV genomes and lead us to speculate on the definition of the virus genome.     

Cell Biology of Prokaryotic Organelles

Mounting evidence in recent years has challenged the dogma that prokaryotes are simple and undefined cells devoid of an organized subcellular architecture. In fact, proteins once thought to be the purely eukaryotic inventions, including relatives of actin and tubulin control prokaryotic cell shape, DNA segregation, and cytokinesis. Similarly, compartmentalization, commonly noted as a distinguishing feature of eukaryotic cells, is also prevalent in the prokaryotic world in the form of protein-bounded and lipid-bounded organelles. In this article we highlight some of these prokaryotic organelles and discuss the current knowledge on their ultrastructure and the molecular mechanisms of their biogenesis and maintenance.The emergence of eukaryotes in a world dominated by prokaryotes is one of the defining moments in the evolution of modern day organisms. Although it is clear that the central metabolic and information processing machineries of eukaryotes and prokaryotes share a common ancestry, the origins of the complex eukaryotic cell plan remain mysterious. Eukaryotic cells are typified by the presence of intracellular organelles that compartmentalize essential biochemical reactions whereas their prokaryotic counterparts generally lack such sophisticated subspecialization of the cytoplasmic space. In most cases, this textbook categorization of eukaryotes and prokaryotes holds true. However, decades of research have shown that a number of unique and diverse organelles can be found in the prokaryotic world raising the possibility that the ability to form organelles may have existed before the divergence of eukaryotes from prokaryotes (Shively 2006).Skeptical readers might wonder if a prokaryotic structure can really be defined as an organelle. Here we categorize any compartment bounded by a biological membrane with a dedicated biochemical function as an organelle. This simple and broad definition presents cells, be they eukaryotes or prokaryotes, with a similar set of challenges that need to be addressed to successfully build an intracellular compartment. First, an organism needs to mold a cellular membrane into a desired shape and size. Next, the compartment must be populated with the proper set of proteins that carry out the activity of the organelle. Finally, the cell must ensure the proper localization, maintenance and segregation of these compartments across the cell cycle. Eukaryotic cells perform these difficult mechanistic steps using dedicated molecular pathways. Thus, if connections exist between prokaryotic and eukaryotic organelles it seems likely that relatives of these molecules may be involved in the biogenesis and maintenance of prokaryotic organelles as well.Prokaryotic organelles can be generally divided into two major groups based on the composition of the membrane layer surrounding them. First are the cellular structures bounded by a nonunit membrane such a protein shell or a lipid monolayer (Shively 2006). Well-known examples of these compartments include lipid bodies, polyhydroxy butyrate granules, carboxysomes, and gas vacuoles. The second class consists of those organelles that are surrounded by a lipid-bilayer membrane, an arrangement that is reminiscent of the canonical organelles of the eukaryotic endomembrane system. Therefore, this article is dedicated to a detailed exploration of three prokaryotic lipid-bilayer bounded organelle systems: the magnetosomes of magnetotactic bacteria, photosynthetic membranes, and the internal membrane structures of the Planctomycetes. In each case, we present the most recent findings on the ultrastructure of these organelles and highlight the molecular mechanisms that control their formation, dynamics, and segregation. We also highlight some protein-bounded compartments to present the reader with a more complete view of prokaryotic compartmentalization.     

研究: 核糖体失活蛋白及其在黄瓜中的表达分析

核糖体失活蛋白是一类具有高度特异性rRNA N-糖苷酶活性的蛋白,它们能够使原核或真核细胞的核糖体失活因而具有细胞毒性．由于其独特的生物学性质,核糖体失活蛋白被认为在农业和医学中都有着巨大的应用潜力．我们之前的研究表明,黄瓜的基因组中共包含2个2类核糖体失活蛋白基因,分别命名为CumsaAB1和CumsaAB2．以蓖麻毒蛋白Ricin为代表,2类核糖体失活蛋白通常由2条二硫键连接的肽链组成：具有N-糖苷酶活性的A链与具有凝集素活性的B链．本文研究了黄瓜中核糖体失活蛋白的表达情况．亚细胞定位研究表明CumsaAB1经过蛋白分泌通路表达于细胞外,这与蛋白质序列分析显示的CumsaAB1包含一个信号肽而不含转膜区域相一致．对黄瓜的不同生长阶段的不同组织中的转录水平分析表明,CumsaAB1在大部分组织中以极低的水平表达,而CumsaAB2表达水平则明显更高,尤其在第一片真叶阶段和刚开花的植物中．最后,我们使用分子模拟对黄瓜中核糖体失活蛋白的结构及糖结合位点进行了分析．本研究对黄瓜中核糖体失活蛋白的亚细胞定位、表达水平和可能的蛋白质结构进行了研究,为其进一步的生物学功能研究提供了重要信息．     

Molecular approaches for AM fungal community ecology: A primer

Molecular techniques are no longer optional for ecologists interested in arbuscular mycorrhizal (AM) communities. Understanding the role of these soil fungi in natural systems requires knowledge of their abundance and identity but this is impossible to achieve without a molecular approach. Adapting molecular tools to AM fungi can be challenging because of the unique biology of the fungi. Moreover, many recruits in the field of mycorrhizal ecology have little or no experience with molecular biology. Here, we outline a conceptual framework for designing robust ecological experiments with AM fungi using molecular approaches.     

Molecular analysis of linear plasmid-encoded major surface proteins, OspA and OspB, of the Lyme disease spirochaete Borrelia burgdorferi

The ospA and ospB genes encode the major outer membrane proteins of the Lyme disease spirochaete Borrelia burgdorferi. The deduced translation products from the ospA and ospB genes were: (OspA) 273 amino acids long with a molecular weight of 29,334, and (OspB) 296 amino acids long with a molecular weight of 31,739. The two Osp proteins showed a great degree of sequence similarity indicating a recent evolutionary event. Molecular analysis and sequence comparison of OspA and OspB with other proteins revealed a sequence similarity to the signal peptides of prokaryotic lipoproteins. These are the first sequences from Borrelia and provide interesting data on the evolutionary relationship between spirochaetes and other species as well as providing potential for spirochaete diagnostics and vaccines.     

基于分子生物学方法的外来入侵物种入侵历史重构

生物入侵是一个世界性的问题。全球每年因生物入侵造成的损失超过1万亿美元。探究入侵物种在入侵地的入侵历史对了解生物入侵的生物生态学机制、制定阻截及防除措施有重要意义。分子标记方法的兴起和大规模应用打开了入侵生物入侵历史研究的新天地。采用分子标记的方法可鉴定入侵物种的种类、追溯其来源地、回溯其扩散路径、分析扩散模式及探究物种入侵过程中对入侵种群本身的变化及其对生态系统所造成的各种影响。分子标记的应用使得多个入侵物种的入侵历史得以重现。由于分子标记方法重构的入侵历史受采样范围、采用的分子标记的种类及数量等因素的影响,该方法呈现入侵历史是否是真实发生的入侵过程还存在争议。     

Bioactive natural products from marine cyanobacteria for drug discovery

The prokaryotic marine cyanobacteria continue to be an important source of structurally bioactive secondary metabolites. A majority of these molecules are nitrogen-containing compounds biosynthesized by large multimodular nonribosomal polypeptide (NRP) or mixed polyketide-NRP enzymatic systems. A total of 128 marine cyanobacterial alkaloids, published in the literature between January 2001 and December 2006, are presented in this review with emphasis on their biosynthesis and biological activities. In addition, a number of highly cytotoxic compounds such as hectochlorin, lyngbyabellins, apratoxins, and aurilides have been identified as potential lead compounds for the development of anticancer agents. A brief coverage on the distribution of natural product biosynthetic genes as well as the mechanisms of tailoring enzymes involved in the biosynthesis of cyanobacterial compounds will also be given.     

Prokaryotic DNA Methyltransferases: The Structure and the Mechanism of Interaction with DNA

The review considers current views on the function of DNA methyltransferases (MTases) that belong to prokaryotic type II restriction–modification systems. A commonly accepted classification of MTases is described along with their primary and tertiary structures and molecular mechanisms of their specific interaction with DNA (including methylation). MTase inhibitors are also considered. Special emphasis is placed on the flipping of the target heterocyclic base out of the double helix and on the methods employed in its analysis. Base flipping is a fundamentally new type of DNA conformational changes and is also of importance in the case of other DNA-operating enzymes. MTases show unique sequence homology, and are similar in structure of functional centers and in the mechanism of methylation. These data contribute to the understanding of the general biological significance of methylation, since prokaryotic and eukaryotic MTases are structurally and functionally similar.     

Prokaryotic DNA methyltransferases: the structure and the mechanism of interaction with DNA

The review considers current views on the function of DNA methyltransferases (MTases) that belong to prokaryotic type II restriction-modification systems. A commonly accepted classification of MTases is described along with their primary and tertiary structures and molecular mechanisms of their specific interaction with DNA (including methylation). MTase inhibitors are also considered. Special emphasis is placed on the flipping of the target heterocyclic base out of the double helix and on the methods employed in its analysis. Base flipping is a fundamentally new type of DNA conformational changes and is also of importance in the case of other DNA-operating enzymes. MTases show unique sequence homology, and are similar in structure of functional centers and in the mechanism of methylation. These data contribute to the understanding of the general biological significance of methylation, since prokaryotic and eukaryotic MTases are structurally and functionally similar.     

水稻两个frr基因的结构、转录特性及同源性分析

对水稻中两个核糖体再循环因子同源基因OsfrrA和OsfrrB进行了鉴定与分析.这两个单拷贝基因分别位于水稻的4号和7号染色体上,且在细胞器基因组中未发现同源序列.它们在不同组织中的转录特性及其蛋白质产物的N端特征提示其翻译产物会被各自转运并分别定位于线粒体和叶绿体中,而序列上的保守性及构成性的表达则表明它们在植物生长中扮演着重要的角色.它们与其它原核及真核RRF之间在基因结构及编码序列上的异同为内共生学说提供了新的证据,也揭示了RRF在分子进化研究方面所具有的潜在价值.     

Life's unity and flexibility: the ecological link.

The small size, ubiquity, metabolic versatility and flexibility, and genetic plasticity (horizontal transfer) of microbes allow them to tolerate and quickly adapt to unfavorable and/or changing environmental conditions. Prokaryotes are endowed with sophisticated cellular envelopes that contain molecules not found elsewhere in the biological world. Although prokaryotic cells lack the organelles that characterize their eukaryotic counterparts, their interiors are surprisingly complex. Prokaryotes sense their environment and respond as individual cells to specific environmental challenges; but prokaryotes also act cooperatively, displaying communal activities. In many microbial ecosystems, the functionally active unit is not a single species or population (clonal descendence of the same bacterium) but a consortium of two or more types of cells living in close symbiotic association. Only recently have we become aware that microbes are the basis for the functioning of the biosphere. Thus, we are at a unique time in the history of science, in which the interaction of technological advances and the exponential growth in our knowledge of the present microbial diversity will lead to significant advances not only in microbiology but also in biology and other sciences in general.