Mechanisms and consequences of somatic mosaicism in humans

Somatic mosaicism -- the presence of genetically distinct populations of somatic cells in a given organism -- is frequently masked, but it can also result in major phenotypic changes and reveal the expression of otherwise lethal genetic mutations. Mosaicism can be caused by DNA mutations, epigenetic alterations of DNA, chromosomal abnormalities and the spontaneous reversion of inherited mutations. In this review, we discuss the human disorders that result from somatic mosaicism, as well as the molecular genetic mechanisms by which they arise. Specifically, we emphasize the role of selection in the phenotypic manifestations of mosaicism.     

Construction and Characterization of Large-Insert Genomic Libraries (BAC and Fosmid) from the Ascidian <Emphasis Type="Italic">Botryllus schlosseri</Emphasis> and Initial Physical Mapping of a Histocompatibility Locus

The colonial protochordate Botryllus schlosseri is genetically manipulable and represents a potential model organism for a variety of biological disciplines, including immunology, stem cell biology and development. This article presents the construction and characterization of both BAC and fosmid genomic libraries of the 725-Mbp B. schlosseri genome. The BAC library currently consists of 2× genome coverage with an average insert size of 80 kb. The fosmid library is at 11× genome coverage with an average insert of 40 kb. B. schlosseri is a small organism containing a large number of compounds that hinder DNA purification. Thus a number of protocols had to be modified in order to make purified, high molecular weight inserts for cloning, including both gel purification and insert concentration techniques. Both libraries were characterized by using them in initial physical mapping of a single histocompatibility locus, and were found to be representative and functional. These libraries are important tools for physical mapping and positional cloning in the B. schlosseri genome, and the techniques adapted to make them are suitable for use on other organisms in which high molecular weight DNA is difficult to purify.     

Endosperm degradation during seed development of Echinocystis lobata (Cucurbitaceae) as a manifestation of programmed cell death (PCD) in plants

Programmed cell death (PCD) is an active, genetically controlled process that ultimately leads to elimination of unnecessary or damaged cells from multicellular organism. It occurs during normal growth and development or in response to a variety of environmental triggers and is indispensable for survival of the organism. In Echinocystis lobata the endosperm, an ephemeral tissue in angiosperm plants, undergoes distinct cytological, physiological and molecular changes during seed development and maturation. As a result, mature seeds are deprived of this tissue. The endosperm was analyzed at the consecutive stages of seed development. The morphological changes of cells were studied at light and electron microscope levels. In this paper we report that endosperm cells undergo morphological and biochemical changes characteristic of apoptosis, a particular type of PCD, i.e. cell shrinkage, chromatin condensation, nuclear fragmentation, and cytoplasm degradation, while the ultrastructure of mitochondria seems to be less changed. Furthermore, the progression of DNA degradation has been shown by agarose gel electrophoresis (ladder pattern of DNA fragmentseparation), TUNEL and comet assay. It isconcluded that during seed maturation, endosperm degradation process is accompanied by typical PCD-related changes of cell morphology and internucleosomal DNA cleavage.     

Protein interactions involved in nuclear import of the Agrobacterium VirE2 protein in vivo and in vitro

Agrobacterium, the only known organism capable of trans-kingdom DNA transfer, genetically transforms plants by transferring a segment of its DNA, T-DNA, into the nucleus of the host cell where it integrates into the plant genome. One of the central events in this genetic transformation process is nuclear import of the T-DNA molecule, which to a large degree is mediated by the bacterial virulence protein VirE2. VirE2 is distinguished by its nuclear targeting, which occurs only in plant but not in animal cells and is facilitated by the cellular VIP1 protein. The molecular mechanism of the VIP1 function is still unclear. Here, we used in vitro assays for nuclear import and quantification of protein-protein interactions to directly demonstrate formation of ternary complexes between VirE2, VIP1, and a component of the cellular nuclear import machinery, karyopherin alpha. Our results indicate that VIP1 functions as a molecular bridge between VirE2 and karyopherin alpha, allowing VirE2 to utilize the host cell nuclear import machinery even without being directly recognized by its components.     

Tus-Ter as a tool to study site-specific DNA replication perturbation in eukaryotes

The high-affinity binding of the Tus protein to specific 21-bp sequences, called Ter, causes site-specific, and polar, DNA replication fork arrest in E coli. The Tus-Ter complex serves to coordinate DNA replication with chromosome segregation in this organism. A number of recent and ongoing studies have demonstrated that Tus-Ter can be used as a heterologous tool to generate site-specific perturbation of DNA replication when reconstituted in eukaryotes. Here, we review these recent findings and explore the molecular mechanism by which Tus-Ter mediates replication fork (RF) arrest in the budding yeast, S. cerevisiae. We propose that Tus-Ter is a versatile, genetically tractable, and regulatable RF blocking system that can be utilized for disrupting DNA replication in a diverse range of host cells.     

Emerging models for DNA repair: Dictyostelium discoideum as a model for nonhomologous end-joining

DNA double strand breaks (DSBs) are a particularly cytotoxic variety of DNA lesion that can be repaired by homologous recombination (HR) or nonhomologous end-joining (NHEJ). HR utilises sequences homologous to the damage DNA template to facilitate repair. In contrast, NHEJ does not require homologous sequences for repair but instead functions by directly re-joining DNA ends. These pathways are critical to resolve DSBs generated intentionally during processes such as meiotic and site-specific recombination. However, they are also utilised to resolve potentially pathological DSBs generated by mutagens and errors during DNA replication. The importance of DSB repair is underscored by the findings that defects in these pathways results in chromosome instability that contributes to a variety of disease states including malignancy. The general principles of NHEJ are conserved in eukaryotes. As such, relatively simple model organisms have been instrumental in identifying components of these pathways and providing a mechanistic understanding of repair that has subsequently been applied to vertebrates. However, certain components of the NHEJ pathway are absent or show limited conservation in the most commonly used invertebrate models exploited to study DNA repair. Recently, however, it has become apparent that vertebrate DNA repair pathway components, including those involved in NHEJ, are unusually conserved in the amoeba Dictyostelium discoideum. Traditionally, this genetically tractable organism has been exploited to study the molecular basis of cell type specification, cell motility and chemotaxis. Here we discuss the use of this organism as an additional model to study DNA repair, with specific reference to NHEJ.     

Genetic activity of chemicals in yeast: DNA alterations and mutations induced by alkylating anti-cancer agents.

The simple eukaryotic organism baker's yeast allows demonstration of primary DNA lesions in parallel with measurement of mutagenicity and lethality after treatment with alkylating chemicals. Several anti-cancer drugs formed cross-linked DNA molecules and were genetically active. The mutagenicity and lethality of these drugs varied substantially and were dependent on the function of some processes of DNA dark-repair.     

The human commensal yeast, Candida albicans, has an ancient origin

Candida albicans, the primary causative agent of candidiasis, is a ubiquitous member of the human flora and is capable of causing severe invasive disease. Despite its importance as a human pathogen, little is known concerning those factors creating and maintaining genetic diversity within the species and how extant strains reflect their evolutionary history. Based on nucleotide polymorphism frequencies, we estimated the time to a most recent common ancestor for the species to be about 3-16 million years, with variation due to molecular clock calibration. As C. albicans genotypes have broad geographic associations, this suggests that the origins of DNA sequence variation in extant populations coincided with early hominid evolution. This is consistent with an emerging view of a genetically complex organism that is able to survive under host immunity as an obligate commensal species.     

Molecular genetics of Drosophila vision

The fruitfly, Drosophila melanogaster, is an excellent organism for dissecting the components of vision genetically. Many mutations have been generated that affect a diversity of processes important in vision. Through a combined application of molecular and genetic approaches many of the genes important in Drosophila vision are now being identified.     

Proposal of Mycobacterium peregrinum sp. nov., nom. rev., and elevation of Mycobacterium chelonae subsp. abscessus (Kubica et al.) to species status: Mycobacterium abscessus comb. nov.

We studied the taxonomic positions of the rapidly growing organism Mycobacterium fortuitum and phenotypically related organisms. We confirmed that "Mycobacterium peregrinum" ATCC 14467T (T = type strain) is genetically independent of M. fortuitum ATCC 6841T by using various DNA hybridization conditions. Strains that were genetically identified as "M. peregrinum" were phenotypically differentiated from M. fortuitum ATCC 6841T. Thus, we propose that "M. peregrinum" should be revived as an independent species, Mycobacterium peregrinum sp. nov., nom. rev. The type strain is strain ATCC 14467. M. fortuitum subsp. acetamidolyticum ATCC 35931T exhibited a high level of DNA relatedness to M. fortuitum ATCC 6841T. The hybridized DNAs maintained stable heteroduplexity at high stringency; thus, we confirmed that M. fortuitum subsp. acetamidolyticum is identical to M. fortuitum ATCC 6841T. We found that M. chelonae subsp. abscessus ATCC 19977T is genetically different from M. chelonae subsp. chelonae NCTC 946T on the basis of the results of quantitative hybridization even under optimal conditions. There was no reason to maintain this organism as a subspecies of M. chelonae. Thus, we propose that M. chelonae subsp. abscessus should be elevated to species status as Mycobacterium abscessus (Kubica et al.) comb. nov. The type strain is strain ATCC 19977.     

Extracting haplotypes from diploid organisms

Each diploid organism has two alleles at every gene locus. In sexual organisms such as most plants, animals and fungi, the two alleles in an individual may be genetically very different from each other. DNA sequence data from individual alleles (called a haplotype) can provide powerful information to address a variety of biological questions and guide many practical applications. The advancement in molecular technology and computational tools in the last decade has made obtaining large-scale haplotypes feasible. This review summarizes the two basic approaches for obtaining haplotypes and discusses the associated techniques and methods. The first approach is to experimentally obtain diploid sequence information and then use computer algorithms to infer haplotypes. The second approach is to obtain haplotype sequences directly through experimentation. The advantages and disadvantages of each approach are discussed. I then discussed a specific example on how the direct approach was used to obtain haplotype information to address several fundamental biological questions of a pathogenic yeast. With increasing sophistication in both bioinformatics tools and high-throughput molecular techniques, haplotype analysis is becoming an integrated component in biomedical research.     

泰泽病原体基因组DNA提取方法的建立

目的　提取泰泽病原体基因组DNA ,为建立该菌基因组文库奠定基础。方法　使用密度梯度离心结合酶解消化方法、酶解消化方法、本研究建立方法即过滤盐析离心法 ,从感染肝脏组织纯化泰泽病原体 ,并比较三种方法纯化泰泽病原体效果 ;采用氯化苄法、试剂盒、酚法提取泰泽病原体基因组DNA ,并比较三种方法提取基因组DNA质量 ;鉴定酚法提取泰泽病原体基因组DNA特异性。结果　使用过滤盐析离心法从感染肝脏组织纯化泰泽病原体 ,采用酚法提取其基因组DNA ,所获得的基因组DNA特异性好、纯度高、DNA片段长度大于 5 0kb ,且均一性好 ,无降解。结论　本研究首次成功提取泰泽病原体基因组DNA ,可用于多种分子生物学实验     

Key issues in the deliberate release of genetically-manipulated bacteria

Abstract The deliberate release of a genetically engineered bacterium often requires that a complex pathway be travelled through scientific and regulatory questions. It is important to consider the scientific aim of the release and the nature of the modification (deletion or insertion, site of insertion, level of expression) and its likely effect on survival of the organism and the possibility of gene transfer. In Australia, the Genetic Manipulation Advisory Committee assesses applications and makes recommendations about pre-release testing and procedures for conducting field release. Two examples of field release of genetically manipulated bacteria in Australia are considered. Firstly, the commercial product Agrobacterium strain K1026 (‘NoGall’^TM), a genetically engineered biological control agent for crown gall disease of stone fruits and roses. Secondly, a lacZY -marked derivative of a strain of Pseudomonas corrugata , that can act as a biological control agent against take-all disease of wheat. Prior to release, bacterial survival and competition was tested in soil microcosms. The distribution and survival of the organism were monitored after field release. Since 1992 the marked bacteria have been recovered only after enrichment. Assessment of risk should consider the survival and spread of the genetically manipulated bacterium and its foreign DNA and the impact of the inoculated bacteria on other (‘non-target’) organisms.     

Molecular characterization for food safety assessment of a genetically modified late blight resistant potato: an unusual case

Standard food safety assessments of genetically modified crops require a thorough molecular characterization of the novel DNA as inserted into the plant that is intended for commercialization, as well as a comparison of agronomic and nutritional characteristics of the genetically modified to the non-modified counterpart. These characterization data are used to identify any unintended changes in the inserted DNA or in the modified plant that would require assessment for safety in addition to the assessment of the intended modification. An unusual case of an unintended effect discovered from the molecular characterization of a genetically modified late blight resistant potato developed for growing in Bangladesh and Indonesia is presented here. Not only was a significant portion of the plasmid vector backbone DNA inserted into the plant along with the intended insertion of an R-gene for late blight resistance, but the inserted DNA was split into two separate fragments and inserted into two separate chromosomes. One fragment carries the R-gene and the other fragment carries the NPTII selectable marker gene and the plasmid backbone DNA. The implications of this for the food safety assessment of this late blight resistant potato are considered.

     

DNA Damage Signalling and Repair in Dictyostelium discoideum

Repair of DNA double strand breaks (DSBs) is critical for the maintenance of genome integrity. DNA DSBs can be repaired by either homologous recombination (HR) or nonhomologous end-joining (NHEJ). Whilst HR requires sequences homologous to thedamaged DNA template in order to facilitate repair, NHEJ occurs through recognition of DNA DSBs by a variety of proteins that process and rejoin DNA termini by direct ligation. Here we review two recent reports that NHEJ is conserved in the social amoebaDictyostelium discoideum. Certain components of the mammalian NHEJ pathway that are absent in genetically tractable organisms such as yeast are present in Dictyostelium and we discuss potential directions for future research, in addition to considering this organism as a genetic model system for the study of NHEJ in vivo.     

Fromin vitro toin vivo. Progress in the use of cultured cells for human therapy

The use of cultured cells with the ultimate goal of using the cells or their products for human therapy has experienced an exponential growth during the last decade. Stable cell cultures have been established and genetically modified to obtain high quality products for protein replacement therapy or vaccines. Cells have also been directly isolated from the human organism and, after their expansionin vitro, been retransferred as skin grafts for treatment of burns or for cancer therapy by activated lymphocytes. With the explosive development of molecular biology techniques, it is now possible to genetically modifyex vivo, cells derived from the human body. These modifications should allow targeted expression of therapeutic genes into specific cells which will, upon retransfer to the body, exert their therapeutic action in a diseased organism.Abbreviations ADA adenosine deaminase - GM-CSF granulocyte-macrophage colony-stimulating factor - IFN interferon - IL interleukin - TIL tumor infiltrating lymphocytes     

DNA shuffling技术及其在基因工程疫苗中的应用

DNA shuffling技术是一项全新的体外人工进化模式,它通过基因在分子水平上的重组,再定向筛选具有预期性状的突变体,获得同时具有多个亲本基因的特征的突变基因。该文介绍DNA shuffling技术的基本原理,并列举了由该技术发展而来的新技术及其在基因工程疫苗领域的应用,展望了DNAshuffling技术的发展方向。     

Characterization of minute differences between genomes of strains of Penicillium nalgiovense using subtractive suppression hybridization without cloning

AIMS: Characterization of integrated DNA fragments of unknown base sequences from foreign species using the genetically modified mould Penicillium nalgiovense. METHODS AND RESULTS: A modified suppression subtractive hybridization method was deployed in order to detect and characterize foreign genes. Combined with a special two-dimensional polyacrylamide gel electrophoretic technique the usual background was eliminated from the prospective foreign polymerase chain reaction fragments according to their base composition (Müller et al. 1981). CONCLUSIONS AND SIGNIFICANCE AND IMPACT OF THE STUDY: DNA fragments obtained from the procedure were suitable for direct DNA sequencing. Each DNA fragment derived from the tester genomic DNA was found to be completely absent in the driver organism.