Techniques and statistical data analysis in molecular population genetics

Following the development of PCR methods, molecular techniques have become widely used for detecting genetic variation in natural populations. Most nucleotide changes can be detected by these techniques. Many of these changes probably reflect silent substitutions that are likely to be selectively neutral, making them particularly suitable to population genetic studies. In this paper, we review the published literature on molecular population genetics, with respect to the genome assayed (nuclear, mitochondrial or chloroplast), the organisms studied, the molecular techniques used, and the biological problems addressed. Several molecular techniques are then compared using experimental results obtained from a population genetic study of the Mytilus complex in the North Atlantic and Mediterranean. Finally, the most appropriate theoretical tools to analyse molecular population genetic data are discussed.     

Genetic approaches to molecular mechanisms of programmed cell death in Dictyostelium

Caspase-independent cell deaths have been observed in many species including the human. However, the molecular mechanisms which govern them are largely unknown. Our present work makes use of a model organism, the protist Dictyostelium discoideum, which displays a caspase-independent cell death during its development. In rich medium, Dictyostelium multiplies vegetatively as a unicellular organism, but in starvation conditions, Dictyostelium cells aggregate, differentiate and morphogenize into a multicellular structure, called sorocarp, containing a mass of spores supported by a stalk. Cells in the stalk are considered dead on the basis of non-regrowth in a rich medium and are vacuolized. This programmed cell death is therefore developmental and vacuolar, and in addition, caspase-independent since the Dictyostelium genome does not contain caspases genes. In order to study in detail this cell death without induction of development, an in vitro experimental protocol has been adopted, which enabled us to describe the cascade of morphological events during this cell death. An insertional mutagenesis approach, followed by appropriate selection or screening of mutants potentially resistant to death, attempted at establishing the cascade of molecular events leading to vacuolar death of Dictyostelium cells. A better understanding of alternative death pathways may allow to control different types of cell deaths in the cases of cancers or neurodegenerative diseases. In this short review, we will discuss briefly some generalities about the development of Dictyostelium in starvation conditions, and we will focus on the course of programmed cell death in Dictyostelium and on the genetic tools used to elucidate the corresponding molecular mechanisms.     

Dictyostelium as a model for human lysosomal and trafficking diseases

Dictyostelium cells are genetically haploid and therefore easily analyzed for mutant phenotypes. In the past, many tools and molecular markers have been developed for a quantitative and qualitative analysis of the endocytic pathway in these amoebae. This review outlines parallels and discrepancies between mutants in Dictyostelium, the corresponding mammalian cells and the symptoms of human patients affected by lysosomal and trafficking defects. Situations where knowledge from Dictyostelium may potentially help understand human disease and vice versa are also addressed.     

Manifestations of multicellularity: Dictyostelium reports in

The recent release of the Dictyostelium genome sequence is important because Dictyostelium has become a much-favoured model system for cell and developmental biologists. The sequence has revealed a remarkably high total number of approximately 12 500 genes, only a thousand fewer than are encoded by Drosophila. Previous protein-sequence comparisons suggested that Dictyostelium is evolutionarily closer to animals and fungi than to plants, and the global protein sequence comparison, now made possible by the genome sequence, confirms this. This review focuses on several classes of proteins that are shared by Dictyostelium and animals: a highly sophisticated array of microfilament components, a large family of G-protein-coupled receptors and a diverse set of SH2 domain-containing proteins. The presence of these proteins strengthens the case for a relatively close relationship with animals and extends the range of problems that can be addressed using Dictyostelium as a model organism.     

Dictyostelium as host model for pathogenesis

The haploid social soil amoeba Dictyostelium discoideum has been established as a host model for several pathogens including Pseudomonas aeruginosa, Cryptococcus neoformans, Mycobacterium spp. and Legionella pneumophila. The research areas presently pursued include (i) the use of Dictyostelium wild-type cells as screening system for virulence of extracellular and intracellular pathogens and their corresponding mutants, (ii) the use of Dictyostelium mutant cells to identify genetic host determinants of susceptibility and resistance to infection and (iii) the use of reporter systems in Dictyostelium cells which allow the dissection of the complex host-pathogen cross-talk. The body of information presented in this review demonstrates that the availability of host cell markers, the knowledge of cell signalling pathways, the completion of the genome sequencing project and the tractability for genetic studies qualifies Dictyostelium for the study of fundamental cellular processes of pathogenesis.     

Crawling into a new era-the Dictyostelium genome project

The social amoeba Dictyostelium discoideum is a well-established model organism for the study of basic aspects of differentiation, signal transduction, phagocytosis, cytokinesis and cell motility. Its genome is being sequenced by an international consortium using a whole chromosome shotgun approach. The pacemaker of the D.discoideum genome project has been chromosome 2, the largest chromosome, which at 8 Mb represents approximately 25% of the genome and whose sequence and analysis have been published recently. Chromosomes 1 and 6 are close to being finished. To accelerate completion of the genome sequence, the next step in the project will be a whole-genome assembly followed by the analysis of the complete gene content. The completed genome sequence and its analysis provide the basis for genome-wide functional studies. It will position Dictyostelium at the same level as other model organisms and further enhance its experimental attractiveness.     

Regulation of cell-fate determination in Dictyostelium

A key step in the development of all multicellular organisms is the differentiation of specialized cell types. The eukaryotic microorganism Dictyostelium discoideum provides a unique experimental system for studying cell-type determination and spatial patterning in a developing multicellular organism. Unlike metazoans, which become multicellular by undergoing many rounds of cell division after fertilization of an egg, the social amoeba Dictyostelium achieves multicellularity by the aggregation of approximately 10(5) cells in response to nutrient depletion. Following aggregation, cell-type differentiation and morphogenesis result in a multicellular organism with only a few cell types that exhibit a defined patterning along the anterior-posterior axis of the organism. Analysis of the mechanisms that control these processes is facilitated by the relative simplicity of Dictyostelium development and the availability of molecular, genetic, and cell biological tools. Interestingly, analysis has shown that many molecules that play integral roles in the development of higher eukaryotes, such as PKA, STATs, and GSK-3, are also essential for cell-type differentiation and patterning in Dictyostelium. The role of these and other signaling pathways in the induction, maintenance, and patterning of cell types during Dictyostelium development is discussed.     

Towards a molecular understanding of human diseases using Dictyostelium discoideum

The social amoeba Dictyostelium discoideum is increasingly being used as a simple model for the investigation of problems that are relevant to human health. This article focuses on several recent examples of Dictyostelium-based biomedical research, including the analysis of immune-cell disease and chemotaxis, centrosomal abnormalities and lissencephaly, bacterial intracellular pathogenesis, and mechanisms of neuroprotective and anti-cancer drug action. The combination of cellular, genetic and molecular biology techniques that are available in Dictyostelium often makes the analysis of these problems more amenable to study in this system than in mammalian cell culture. Findings that have been made in these areas using Dictyostelium have driven research in mammalian systems and have established Dictyostelium as a powerful model for human-disease analysis.     

Cold-Sensitive Mutations of Dictyostelium Myosin Heavy Chain Highlight Functional Domains of the Myosin Motor

Dictyostelium provides a powerful environment for characterization of myosin II function. It provides well-established biochemical methods for in vitro analysis of myosin's properties as well as an array of molecular genetic tools. The absence of myosin function results in an array of phenotypes that can be used to genetically manipulate myosin function. We have previously reported methods for the isolation and identification of rapid-effect cold-sensitive myosin II mutations in Dictyostelium. Here, we report the development and utilization of a rapid method for localizing these point mutations. We have also sequenced 19 mutants. The mutations show distinct clustering with respect to three-dimensional location and biochemically characterized functional domains of the protein. We conclude that these mutants represent powerful tools for understanding the mechanisms driving this protein motor.     

Physical mapping of porcine seasonality genes

Seasonal infertility in sows is a problem in the pig industry characterized by delayed onset of puberty in summer and decreased farrowing rate resulting from silent oestrus and aborted pregnancy. Summer infertility is thought to be influenced by heat, sunburn and stress. However, the strongest contributory factor is photoperiod. The difference in seasonality between wild boar and commercial pig breeds suggests that there may be a genetic component to this trait. The maps and associated molecular tools emerging from the pig genome project have created opportunities to examine the genetic component of seasonal infertility. We are identifying and mapping genes that are likely to be involved in biological clock mechanisms and the melatonin pathways as candidate seasonality genes.     

A specific pathway inducing autophagic cell death is marked by an IP3R mutation

Three main advantages make Dictyostelium a very favorable model to study the induction of autophagic cell death in vitro. First, its small, sequenced and haploid genome facilitates genetic approaches. Second, the Dictyostelium genome does not encode the two main molecular families involved in apoptosis (caspases and bcl-2 family), which therefore cannot interfere in this case with autophagic cell death. Third, induction of autophagic cell death follows in this case a two-step process, namely starvation-induced sensitization leading to autophagy but not to death, followed by a DIF-1-induced pathway leading to cell death proper. The latter, DIF-1-induced pathway is defined experimentally, through sequential additions, and most important also genetically, through random mutagenesis leading in particular to the preparation and study of an iplA mutant. The iplA gene encodes the IP3 Receptor, and its mutation leads to the absence of vacuolization and of death when autophagic cell death is triggered. Further study of the DIF-1 pathway should shed additional light on the induction of autophagic cell death (as opposed to that of just autophagy) in Dictyostelium and by extension perhaps in other organisms.     

The impact of molecular biology on neuroscience

How our brains work is one of the major unsolved problems of biology. This paper describes some of the techniques of molecular biology that are already being used to study the brains of animals. Mainly as a result of the human genome project many new techniques will soon become available which could decisively influence the progress of neuroscience. I suggest that neuroscientists should tell molecular biologists what their difficulties are, in the hope that this will stimulate the production of useful new biological tools.     

The calcineurin inhibitor gossypol impairs growth, cell signalling and development in Dictyostelium discoideum

The Dictyostelium genome harbors single copy genes for both the catalytic and regulatory subunits of the Ca2+/calmodulin-dependent protein phosphatase calcineurin. Since molecular genetic approaches to reduce the expression of these genes have failed so far, we attempted to pharmacologically target calcineurin activity in vivo by using the recently described calcineurin inhibitor, gossypol. Up-regulation of expression of the gene for the Ca2+-ATPase PAT1 in conditions of Ca2+ stress was reduced by gossypol. Dictyostelium wild-type cells treated with 12.5-100 microM gossypol showed reduced growth rates and impaired development. In addition, cell signalling was affected. A cell line that overproduces the catalytic subunit of calcineurin was more resistant to gossypol.     

Applications of random amplified polymorphic DNA (RAPD) in molecular ecology

Molecular genetic markers have been developed into powerful tools to analyse genetic relationships and genetic diversity. As an extension to the variety of existing techniques using polymorphic DNA markers, the Random Amplified Polymorphic DNA (RAPD) technique may be used in molecular ecology to determine taxonomic identity, assess kinship relationships, analyse mixed genome samples, and create specific probes. Main advantages of the RAPD technology include (i) suitability for work on anonymous genomes, (ii) applicability to problems where only limited quantities of DNA are available, (iii) efficiency and low expense.     

Dictyostelium discoideum: a model system for differentiation and patterning

In Dictyostelium, development begins with the aggregation of free living amoebae, which soon become organized into a relatively simple organism with a few different cell types. Coordinated cell type differentiation and morphogenesis lead to a final fruiting body that allows the dispersal of spores. The study of these processes is having increasing impact on our understanding of general developmental mechanisms. The availability of biochemical and molecular genetics techniques has allowed the discovery of complex signaling networks which are essential for Dictyostelium development and are also conserved in other organisms. The levels of cAMP (both intracellular and extracellular) play essential roles in every stage of Dictyostelium development, regulating many different signal transduction pathways. Two-component systems, involving histidine kinases and response regulators, have been found to regulate intracellular cAMP levels and PKA during terminal differentiation. The sequence of the Dictyostelium genome is expected to be completed in less than two years. Nevertheless, the available sequences that are already being released, together with the results of expressed sequence tags (ESTs), are providing invaluable tools to identify new and interesting genes for further functional analysis. Global expression studies, using DNA microarrays in synchronous development to study temporal changes in gene expression, are presently being developed. In the near future, the application of this type of technology to the complete set of Dictyostelium genes (approximately 10,000) will facilitate the discovery of the effects of mutation of components of the signaling networks that regulate Dictyostelium development on changes in gene expression.     

Dictyostelium nucleomorphin is a member of the BRCT-domain family of cell cycle checkpoint proteins

A search of the Dictyostelium genome project database (http://dictybase.org/db/cgi-bin/blast.pl) with nucleomorphin, a protein that regulates the nuclear number, predicted it to be encoded by a larger gene containing a putative breast cancer carboxy-terminus domain (BRCT). Using RT-PCR, Northern and Western blotting we have identified a differentially expressed, 2318 bp cDNA encoding a protein isoform of Dictyostelium NumA with an apparent molecular weight of 70 kDa that we have called NumB. It contains a single amino-terminal BRCT-domain spanning residues 125-201. Starvation of shaking cultures reduces NumA expression by approximately 88+/-5.6%, whereas NumB expression increases approximately 35+/-3.5% from vegetative levels. NumC, a third isoform that is also expressed during development but not growth, remains to be characterized. These findings suggest NumB may be a member of the BRCT-domain containing cell cycle checkpoint proteins.     

Molecular genetic approaches to understanding the actin cytoskeleton

New tools in molecular genetics, such as genetic interaction screens and conditional gene targeting, have advanced the study of actin dynamics in a number of model systems. Yeast, Dictyostelium, Caenorhabditis elegans, Drosophila, and mice have contributed much in recent years to a better understanding of both the numerous functions and modes of regulation of the actin cytoskeleton.     

盘基网柄菌——研究致病机制的宿主模型

盘基网柄菌作为致病菌宿主模型的研究主要有:筛选致病菌株及相应突变菌株毒性;鉴别对致病菌易感性和抗性的突变细胞宿主;宿主细胞的有效标记、已完成的基因组计划以及宿主细胞与致病菌间信号转导通路的相互作用;这些都表明盘基网柄菌是致病机制研究的理想宿主模型。