Northwestern song sparrow populations show genetic effects of sequential colonization

Two genetic consequences are often considered evidence of a founder effect: substantial loss in genetic diversity and rapid divergence between source and founder populations. Single-step founder events have been studied for these effects, but with mixed results, causing continued controversy over the role of founder events in divergence. Experiments of serial bottlenecks have shown losses of diversity, increased divergence, and rapid behavioural changes possibly leading to reproductive isolation between source and final populations. The few studies conducted on natural, sequentially founded systems show some evidence of these effects. We examined a natural vertebrate system of sequential colonization among northwestern song sparrows (Melospiza melodia). This system has an effectively linear distribution, it was probably colonized within the last 10,000 years, there are morphological and behavioural differences among populations, and the westernmost populations occur in atypical habitats for the species. Eight microsatellite loci from eight populations in Alaska and British Columbia (n = 205) showed stepwise loss of genetic diversity, genetic evidence for strong population bottlenecks, and increased population divergence. The endpoint population on Attu Island has extremely low diversity (H(E) = 0.18). Our study shows that sequential bottlenecks or founder events can have powerful genetic effects in reducing diversity, possibly leading to rapid evolutionary divergence.     

The role of the NK-homeobox gene slouch (S59) in somatic muscle patterning.

In the Drosophila embryo, a distinct class of myoblasts, designated as muscle founders, prefigures the mature pattern of somatic body wall muscles. Each founder cell appears to be instrumental in generating a single larval muscle with a defined identity. The NK homeobox gene S59 was the first of a growing number of proposed 'identity genes' that have been found to be expressed in stereotyped patterns in specific subsets of muscle founders and their progenitor cells and are thought to control their developmental fates. In the present study, we describe the effects of gain- and loss-of-function experiments with S59. We find that a null mutation in the gene encoding S59, which we have named slouch (slou), disrupts the development of all muscles that are derived from S59-expressing founder cells. The observed phenotypes upon mutation and ectopic expression of slouch include transformations of founder cell fates, thus confirming that slouch (S59) functions as an identity gene in muscle development. These fate transformations occur between sibling founder cells as well as between neighboring founders that are not lineage-related. In the latter case, we show that slouch (S59) activity is required cell-autonomously to repress the expression of ladybird (lb) homeobox genes, thereby preventing specification along the lb pathway. Together, these findings provide new insights into the regulatory interactions that establish the somatic muscle pattern.     

Founder Cell Differentiation and Acrasin Production in an Aggregateless Mutant of Polyspondylium violaceum

A specific class of aggregation-deficient mutants, aggA , of Polyshondylium violaceum are unable to aggregate unless supplied exogenously with a stimulating factor called D factor. The present study examines the effect of D factor on the induction of founder cells and on the production of the chemoattractant of aggregation, N-propionyl-γ-L-glutamyl-L-ornithine-δ-lactam ethyl ester (or glorin). Founder cells initiate aggregate formation and are morphologically distinct from the majority of the amoebae. Founder cell differentiation and oriented movement of attracted amoebae have been studied by time-lapse videotape analysis. In wild-type strains, on the average 90 min after the onset of starvation, a single, motile, irregularly shaped amoeba stops wandering and becomes round in shape. This founder cell has differentiated randomly from the pool of starved amoebae and within 2.5 min after the cessation of movement begins to attract and establish cellular contacts nighboring amoebae. The aggA mutants neither aggregate nor differentiate founder cells in the absence of D factor; whereas, aggregate formation and founder cell differentiation occur in the presence of physiological concentrations of purified, externally added D factor. However, in either the presence or absence of D factor, aggA amoebae produce and excrete glorin (measured using a bioassay) at levels comparable to their parental strain. These studies suggest that D factor is required for founder cell differentiation and organization of the aggregate, and that the ability to synthesize and excrete glorin is not sufficient to trigger aggregation.     

Antisocial, an intracellular adaptor protein, is required for myoblast fusion in Drosophila.

Somatic muscle formation in Drosophila requires fusion of muscle founder cells with fusion-competent myoblasts. In a genetic screen for genes that control muscle development, we identified antisocial (ants), a gene that encodes an ankyrin repeat-, TPR repeat-, and RING finger-containing protein, required for myoblast fusion. In ants mutant embryos, founder cells and fusion-competent myoblasts are properly specified and patterned, but they are unable to form myotubes. ANTS, which is expressed specifically in founder cells, interacts with the cytoplasmic domain of Dumbfounded, a founder cell transmembrane receptor, and with Myoblast city, a cytoskeletal protein, both of which are also required for myoblast fusion. These findings suggest that ANTS functions as an intracellular adaptor protein that relays signals from Dumbfounded to the cytoskeleton during myoblast fusion.     

Characterization of glycosylation profiles of HIV-1 transmitted/founder envelopes by mass spectrometry

The analysis of HIV-1 envelope carbohydrates is critical to understanding their roles in HIV-1 transmission as well as in binding of envelope to HIV-1 antibodies. However, direct analysis of protein glycosylation by glycopeptide-based mass mapping approaches involves structural simplification of proteins with the use of a protease followed by an isolation and/or enrichment step before mass analysis. The successful completion of glycosylation analysis is still a major analytical challenge due to the complexity of samples, wide dynamic range of glycopeptide concentrations, and glycosylation heterogeneity. Here, we use a novel experimental workflow that includes an up-front complete or partial enzymatic deglycosylation step before trypsin digestion to characterize the glycosylation patterns and maximize the glycosylation coverage of two recombinant HIV-1 transmitted/founder envelope oligomers derived from clade B and C viruses isolated from acute infection and expressed in 293T cells. Our results show that both transmitted/founder Envs had similar degrees of glycosylation site occupancy as well as similar glycan profiles. Compared to 293T-derived recombinant Envs from viruses isolated from chronic HIV-1, transmitted/founder Envs displayed marked differences in their glycosylation site occupancies and in their amounts of complex glycans. Our analysis reveals that the glycosylation patterns of transmitted/founder Envs from two different clades (B and C) are more similar to each other than they are to the glycosylation patterns of chronic HIV-1 Envs derived from their own clades.     

A dominant negative form of Rac1 affects myogenesis of adult thoracic muscles in Drosophila

Blocking Rac1 function in precursors of the indirect flight muscle of Drosophila severely disrupts muscle formation. The DLM fibers that develop using larval scaffolds are reduced in number and fiber size, while the DVMs, which develop using founder cells, are mostly absent. These adult muscle phenotypes are in part due to a reduced myoblast pool present at the third larval instar. BrDU labeling studies indicated that this is primarily due to a reduction in proliferation. In addition, DVM myoblasts display altered morphology and are unable to segregate into primordia. This defect precedes the evident block in fusion. We also show that the recently described DVM founder cells can be labeled with 22C10 and beta-3 tubulin, and that they are present under conditions of dominant negative Rac1(N17) expression. Despite the presence of founder cells, DVM fiber formation is rarely observed. Although DLM myoblasts are able to segregate around their larval scaffolds, the pace of fusion is reduced and consequently there is a delay in DLM fiber formation. Thus, in addition to its well-established role in fusion, Rac1 is also involved in the regulation of myoblast proliferation and segregation during adult myogenesis. These are two new roles for Rac1 in Drosophila.     

Haemopoietic progenitors in different parts of one femur perform different functions during regeneration

Femoral haemopoietic tissue was divided into cells released by flushing and cells released by grinding and washing flushed femora. The flushed femur contained 5 times more nucleated cells than the ground femur, 40 times more macrophage colony-forming cells and 6 times more developmentally late, day 8, and developmentally early, day 13, spleen colony-forming cells. However, the ground femur contained 2 times more developmentally early high proliferation potential colony-forming cells and 3 times more late ones. Haemopoietic regeneration of mice treated with fluorouracil was compared in samples obtained by flushing alone and grinding flushed femora. The number of nucleated cells recovered by flushing fell thirteen-fold by the sixth day after administration of the drug and the number recovered by grinding fell six-fold by the eighth day. Developmentally early high-proliferation-potential colony-forming cells which were recovered by grinding doubled their number in half the time taken by similar cells recovered by flushing. These observations are consistent with haemopoietic cells in different parts of the same bone performing different functions during regeneration. Large numbers of high-proliferation-potential colony-forming cells were not found in the circulation until 8 days after treatment with fluorouracil. Five days after mice had been treated with fluorouracil, when their blood forming systems were regenerating, early high-proliferation-potential colony-forming cells in one sample of marrow were derived from different founder cells than were late cells in the same sample. At the same time, early high-proliferation-potential colony-forming cells in the ground sample of a femur were derived from different founder cells than were cells at the same stage of development in the flushed sample of the femur. These observations are consistent with the view that haemopoietic regeneration after treatment with fluorouracil is due to the growth of few founder cells whose progeny have migrated little within 5 days of drug treatment.     

At most three ES cells contribute to the somatic lineages of chimeric mice and of mice produced by ES-tetraploid complementation

Chimeric or entirely embryonic stem (ES) cell-derived mice ("ES mice") can be produced by injecting ES cells into diploid (2n) or tetraploid (4n) host blastocysts, respectively. Usually, between 10 and 15 ES cells are injected into the host blastocyst, but it is not clear how many of the injected cells contribute to the somatic lineages, thus serve as "founder cells" of the embryo proper. We have used genetically labeled ES cells to retrospectively determine the number of founder ES cells that generate the somatic lineages of chimeric and of ES mice. ES cell clones individually labeled with provirus were mixed in equal numbers and injected into 2n or 4n blastocysts to generate chimeric or ES mice. Southern analysis of DNA from the resulting animals indicated that the somatic lineages were most often derived from one or two and sometimes from up to three founder ES cells. The number of founder cells was independent of the total number of cells injected into the host blastocysts. Our results are consistent with the notion that constraints of the host embryo restrict the number of ES cells that can contribute to a chimeric or an ES mouse.     

基于SSR标记的寒地水稻品种骨干亲本分析

富士光、藤系138、上育397和五优稻1是20世纪90年代至今寒地水稻品种选育的骨干亲本。利用50对SSR引物对上述骨干亲本及其衍生品种进行聚类分析和主坐标分析(principal coordinate analysis, PCO),结果表明,50对SSR引物在51份供试材料中共检测到150个等位基因,变化范围为2~6个,平均为3个;引物PIC的变化范围为0.0725~ 0.6845,平均0.3655;聚类分析将51份材料分为4类,4个骨干亲本分别被聚到4类中;PCO分析显示,四个骨干亲本相距较远,呈独立的分支,衍生品种围绕着骨干亲本分布;在检测出的39个稀有等位基因中,仅有3个存在骨干亲本中。表明近年寒地水稻品种遗传改良是围绕少数骨干亲本进行的,骨干亲本将大部分优良基因传递到了衍生品种中,SSR分析和PCO分析与系谱分析得到了一致的结果。     

Characterization of Notch-class gene expression in segmentation stem cells and segment founder cells in Helobdella robusta (Lophotrochozoa; Annelida; Clitellata; Hirudinida; Glossiphoniidae)

To understand the evolution of segmentation, we must compare segmentation in all three major groups of eusegmented animals: vertebrates, arthropods, and annelids. The leech Helobdella robusta is an experimentally tractable annelid representative, which makes segments in anteroposterior progression from a posterior growth zone consisting of 10 identified stem cells. In vertebrates and some arthropods, Notch signaling is required for normal segmentation and functions via regulation of hes-class genes. We have previously characterized the expression of an hes-class gene (Hro-hes) during segmentation in Helobdella, and here, we characterize the expression of an H. robusta notch homolog (Hro-notch) during this process. We find that Hro-notch is transcribed in the segmental founder cells (blast cells) and their stem-cell precursors (teloblasts), as well as in other nonsegmental tissues. The mesodermal and ectodermal lineages show clear differences in the levels of Hro-notch expression. Finally, Hro-notch is shown to be inherited by newly born segmental founder cells as well as transcribed by them before their first cell division.     

Hmga1 is required for normal sperm development

The Hmgi protein family of chromosomal architectural factors is extensively studied for its roles in embryogenesis and its association with benign mesenchymal tumors. Although the biochemical function of Hmga1 has been studied in vitro, to provide in vivo insight into its biological function, a targeted disruption of Hmga1 was initiated. Chimeric founder mice were derived from embryonic stem (ES) cells harboring a targeted mutation in a single Hmga1 allele. These 14 different chimeric founders produced 494 black progeny. Since none of these 494 progeny were agouti, none of them were derived from ES cells. Control injections of the wild-type ES cell lines resulted in ES cell derived agouti mice, indicating that the ES cells were totipotent. Therefore, our results indicate that one intact Hmga1 allele was not sufficient for germ-line transmission of the ES cells. Seven chimeric founder mice that were examined histologically demonstrated aberrant regions in their reproductive organs. Aberrant regions of seminiferous tubules were reduced in diameter, demonstrated vacuolated Sertoli cells, and had an absolute deficiency of sperm. While the Hmga1(+/-) ES cells were shown to contribute to the formation of the epididymides, they did not significantly contribute to the testes of chimeric founder mice. No sperm isolated from any of the Hmga1(+/-) chimeric mice were shown to arise from the ES cells, as none of them contained the targeted disruption of the Hmga1 gene. Our results suggest that both alleles of Hmga1 are required for normal sperm production in the mouse.     

Germ plasm in Caenorhabditis elegans, Drosophila and Xenopus

Special cytoplasm, called germ plasm, that is essential for the differentiation of germ cells is localized in a particular region of Caenorhabditis elegans, Drosophila and Xenopus eggs. The mode of founder cell formation of germline, the origin and behavior of the germline granules, and the molecules localized in germline cells are compared in these organisms. The common characteristics of the organisms are mainly as follows. First, the founder cells of germline are established before the intiation of gastrulation. Second, the germline granules or their derivatives are always present in germline cells or germ cells throughout the life cycle in embryos, larvae, and adults. Lastly, among the proteins localized in the germ plasm, only Vasa protein or its homolog is detected in the germline cells or germ cells throughout the life cycle. As the protein of vasa homolog has been reported to be also localized in the germline-specific structure or nuage in some of the organisms without the germ plasm, the possibility that the mechanism for differentiation of primordial germ cells is basically common in all organisms with or without the germ plasm is discussed.     

Segregation of oral from aboral ectoderm precursors is completed at fifth cleavage in the embryogenesis of Strongylocentrotus purpuratus

A specific set of founder cells uniquely gives rise to the oral and aboral ectoderms in the regularly developing sea urchin Strongylocentrotus purpuratus. We showed earlier that the polar No and Na (animal oral and animal aboral) blastomeres are specified by third cleavage, while the respective oral and aboral lineage contributions of the left and right NL (animal lateral) blastomeres have not yet segregated from one another at third cleavage. Here we demonstrate by iontophoretic injection of lysyl rhodamine dextran lineage tracer that segregation of oral vs aboral cell fates in the lineages of the NL blastomeres has still not occurred by fourth cleavage, but at fifth cleavage there arise from the NL sublineages founder cells whose progeny contribute exclusively to the aboral ectoderm. The sister cells of these fifth cleavage blastomeres are founder cells that contribute exclusively to oral structures. The aboral ectoderm tracts to which NL derivatives give rise occupy lateral regions of the anterior aboral ectoderm, while the oral structures deriving from the NL blastomeres are the lateral sectors of the ciliated bands. The cells of the ciliated bands do not express aboral ectoderm markers and are considered to constitute the border of the oral region. With these new findings we complete our knowledge of the origins, identities, and fates of the 11 founder cells, the progeny of which exclusively give rise to the aboral ectoderm, and of the 5 founder cells, the progeny of which exclusively produce the oral ectoderm and its derivatives.     

Over-expression of an endogenous milk protein gene in transgenic mice is associated with impaired mammary alveolar development and a milchlos phenotype.

The whey acidic protein (WAP) gene is expressed in mammary epithelial cells at late pregnancy and throughout lactation. We have generated transgenic mice in which a mouse WAP transgene is expressed precociously in pregnancy. From 13 founder mice bearing WAP transgenes, two female founders and the daughters from a male founder failed to lactate and nurture their offspring. We named this phenotype milchlos. Mammary tissue from postpartum milchlos mice was underdeveloped, contained too few alveoli and resembled the glands of non-transgenic mid-pregnant mice. The hypothesis that alveolar development in milchlos mice was functionally arrested in a prelactational state is consistent with low levels of alpha-lactalbumin mRNA, and an unidentified keratin RNA in mammary tissue from postpartum mice. Defects in alveolar function in milchlos mice were detected at mid-pregnancy; in non-transgenic mice, WAP was secreted into the alveolar lumen but remained preferentially in the cytoplasm of the alveolar epithelial cells in the milchlos mice. Since deregulated WAP expression resulted in impaired mammary development, it is possible that WAP plays a regulatory role in the terminal differentiation and development of mammary alveolar cells.