Genetic control of macrochaetae development in Drosophila melanogaster

The Drosophila head and body have a regular species-specific pattern of strictly defined number of external sensory organs--macrochaetae (large bristles). The pattern constancy and relatively simple organization of each bristle organ composed of only four specialized cells makes macrochaetae a convenient model to study the developmental patterns of spatial structures with a fixed number of elements in specific positions as well as the mechanisms of cell differentiation. The experimental data on the major genes and their products controlling three stages of macrochaetae development--the emergence of proneural clusters in the imaginal disc ectoderm, the precursor cell determination in the proneural clusters, and the specialization of cells of the definitive sensory organ--were reviewed. The role of the achaeta-scute gene complex, EGFR and Notch signaling, and selector genes in these processes was considered. Analysis of published data allowed us to propose an integrated diagram of the system controlling macrochaetae development in D. melanogaster.     

Drosophila single-minded gene and the molecular genetics of CNS midline development.

Our goal is to understand the molecular mechanisms that govern the formation of the central nervous system. In particular, we have focused on the development of a small group of neurons and glia that lie along the midline of the Drosophila CNS. These midline cells possess a number of unique attributes which make them particularly amenable to molecular, cellular, and genetic examinations of nervous system formation and function. In addition, the midline cells exhibit distinctive ontogeny, morphology, anatomical position, and patterns of gene expression which suggest that they may provide unique functions to the developing CNS. The single-minded gene encodes a nuclear protein which is specifically expressed in the midline cells and has been shown to play a crucial role in midline cell development and CNS formation. Genetic experiments reveal that sim is required for the expression of many CNS midline genes which are thought to be involved in the proper differentiation of these cells. In order to identify additional genes which are expressed in some or all of the midline cells at different developmental stages, a technique known as enhancer trap screening was employed. This screen led to the identification of a large number of potential genes which exhibit various midline expression patterns and may be involved in discrete aspects of midline cell development. Further molecular, genetic, and biochemical analyses of sim and several of the enhancer trap lines are being pursued. This should permit elucidation of the genetic hierarchy which acts in the specification, differentiation, and function of these CNS midline cells.     

Genetic control of macrochaetae development in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

The Drosophila head and body have a regular species-specific pattern of strictly defined number of external sensory organs—macrochaetae (large bristles). The pattern constancy and relatively simple organization of each bristle organ composed of only four specialized cells makes macrochaetae a convenient model to study the developmental patterns of spatial structures with a fixed number of elements in specific positions as well as the mechanisms of cell differentiation. The experimental data on the major genes and their products controlling three stages of macrochaetae development—the emergence of proneural clusters in the imaginal disc ectoderm, the precursor cell determination in the proneural clusters, and the specialization of cells of the definitive sensory organ—were reviewed. The role of the achaete-scute gene complex, EGFR and Notch signaling, and selector genes in these processes was considered. Analysis of published data allowed us to propose an integrated diagram of the system controlling macrochaetae development in D. melanogaster.     

Transient transcriptional activation of gastrin during sodium butyrate-induced differentiation of islet cells

Transient expression of pancreatic gastrin corresponds to a period of rapid islet cell development. After birth gastrin expression silencing is coincidental with islet cell terminal differentiation, while persistent expression is accompanied with nesidioblastosis and reexpression observed in islet cell tumors. Experiments with transgenic animals suggested that gastrin might act synergistically with growth factors to stimulate islet cell development. The present study intended to establish an in vitro cell culture model to analyse the molecular events controlling gastrin gene activation and repression dependent on islet cell differentiation. Sodium butyrate, a proliferation-arresting compound has previously been shown to differentiate insulinoma cells while increasing insulin production. The present paper demonstrates concomitant transient increase in gastrin mRNA, intracellular and secreted gastrin during sodium butyrate treatment. Increased gastrin expression was due to activation or derepression of gastrin promoter activity as revealed by promoter analyses. This in vitro model mimics the expression pattern of gastrin and insulin observed during fetal islet cell development and provides an excellent tool to analyse the molecular mechanisms controlling gastrin gene activation and selective repression during islet cell differentiation.     

Molecular analysis of gene expression in the developing pontocerebellar projection system

As an approach toward understanding the molecular mechanisms of neuronal differentiation, we utilized DNA microarrays to elucidate global patterns of gene expression during pontocerebellar development. Through this analysis, we identified groups of genes specific to neuronal precursor cells, associated with axon outgrowth, and regulated in response to contact with synaptic target cells. In the cerebellum, we identified a phase of granule cell differentiation that is independent of interactions with other cerebellar cell types. Analysis of pontine gene expression revealed that distinct programs of gene expression, correlated with axon outgrowth and synapse formation, can be decoupled and are likely influenced by different cells in the cerebellar target environment. Our approach provides insight into the genetic programs underlying the differentiation of specific cell types in the pontocerebellar projection system.     

性腺母细胞瘤的分子遗传机制研究进展

性腺母细胞瘤(Gonadoblastoma, GB)是一种由性索和生殖细胞演化而来的罕见原位性腺肿瘤,与性腺遗传物质异常有密切联系。80%的GB患者表现为46,XY女性表型,其余为45,XY 和46,XX性别发育异常患者等。35%的GB会进一步演化为无性细胞瘤和精原细胞瘤等恶性肿瘤。由于表型与遗传的异质性,GB的分子遗传机制还未完全揭示。越来越多的研究显示GB的发生与性别分化和决定调控基因(如SRY、WT1、SOX9、Foxl2和TSPY等)之间存在密切关联,且表现出遗传与表观遗传调控相互作用。本文综述了GB的临床表现、病理特征、诊断与治疗措施,总结了性腺遗传异常导致GB的分子遗传与表观遗传调控机制,分析并归纳参与GB形成相关基因的共同表达调控网络,指出了当前研究中的障碍与不足,为进一步研究GB致病分子机制提供新思路。     

Drosophila mechanoreceptors as a model for studying asymmetric cell division

Asymmetric cell division (ACD) is one of the processes creating the overall diversity of cell types in multicellular organisms. The essence of this process is that the daughter cells exit from it being different from both the parental cell and one another in their ability to further differentiation and specialization. The large bristles (macrochaetae) that are regularly arranged on the surface of the Drosophila adult function as mechanoreceptors, and since their development requires ACD, they have been extensively used as a model system for studying the genetic control of this process. Each macrochaete is composed of four specialized cells, the progeny resulting from several ACDs from a single sensory organ precursor (SOP) cell, which differentiates from the ectodermal cells of the wing imaginal disc in the third-instar larva and pupa. In this paper we review the experimental data on the genes and their products controlling the ACDs of the SOP cell and its daughter cells, and their further specialization. We discuss the main mechanisms determining the time when the cell enters ACD, as well as the mechanisms providing for the structural characteristics of asymmetric division, namely, polar distribution of protein determinants (Numb and Neuralized), orientation of the division spindle relative to these determinants, and unequal segregation of the determinants specifying the direction of daughter cell development.     

Molecular Genetics and the Ontogeny of Pigment Patterns in Mammals

The conclusion that animal development is guided by a hierarchical system of gene expression and interaction has gained considerable support from recent molecular genetic studies on fruit flies (Drosophila melanogaster) and mice (Mus musculus). They demonstrate that the patterns of organization revealed by terminal differentiation of cells is anticipated by a myriad of transient prepatterns that channel the developing embryo toward its genetically-programmed target. The numerous white spotting mutants in mice exhibit some of the most dramatic and variable patterns of cutaneous melanin pigmentation. Until recently, the mechanisms of action of white spotting genes and their relationship to the developmental genetic hierarchy remained unknown. It now appears that certain white spotting genes may encode growth factors essential for melanoblast development. Others may be related to homeobox genes that play a number of developmental roles, the primary one being the determination of regional organization along the anterior-posterior axis of the early embryo. The patterns of homeobox gene expression are consistent with several of the developmental models for white spotting in mice and other mammals. It is evident that white spotting genes are not solely concerned with the terminal differentiation of melanoblasts into melanocytes. They are heterogeneous with regard to action and level of expression within the developmental hierarchy.     

The molecular basis of pattern formation in the developing compound eye of Drosophila

Throughout metazoan development cells select pathways of specialization that lead to the differentiation of specific cell types. Differential gene activation converts initially homogeneous populations of cells into spatial arrangements of diverse cell types. As discussed in other articles in this issue, the signals specifying divergent pathways can be encoded in a cell's lineage, its environment, or a combination of both. This article reviews recent analyses of the developing Drosophila compound eye which have focussed upon the mechanisms by which cells assess environmental information in order to determine their fate. More specifically, it examines the molecular mechanisms used by cells to communicate signals which instruct the developmental pathways of other cells.     

Efficient GFP‐labeling and analysis of spermatogenic cells using the IRG transgene and flow cytometry

Spermatogenesis is a highly ordered developmental program that produces haploid male germ cells. The study of male germ cell development in the mouse has provided unique perspectives into the molecular mechanisms that control cell development and differentiation in mammals, including tissue‐specific gene regulatory programs. An intrinsic challenge in spermatogenesis research is the heterogeneity of germ and somatic cell types present in the testis. Techniques to separate and isolate distinct mouse spermatogenic cell types have great potential to shed light on molecular mechanisms controlling mammalian cell development, while also providing new insights into cellular events important for human reproductive health. Here, we detail a versatile strategy that combines Cre‐lox technology to fluorescently label germ cells, with flow cytometry to discriminate and isolate germ cells in different stages of development for cellular and molecular analyses.     

Applications of immortalized cells in basic and clinical neurology

Immortalized cell lines can serve as model systems for studies of neuronal development and restoration of function in models of neurological disease. Cell lines which result from spontaneous or experimentally-induced tumors have been used for these purposes. More recently, the techniques of genetic engineering have resulted in the production of cell lines with specific desired characteristics. This has been accomplished by insertion of a desired gene into a pre-existing immortal cell or by immortalizing primary cells. The production of immortal cell lines using temperature-sensitive immortalizing genes offers an additional method of controlling gene expression, and thereby controlling cell proliferation and differentiation. In the nervous system, these techniques have produced immortal cell lines with neuronal and glial properties.     

Genetic networks in nonpermissive temperature-induced cell differentiation of Sertoli TTE3 cells harboring temperature-sensitive SV40 large T-antigen

To identify the molecular basis by which nonpermissive temperature (NPT) induces cell differentiation in Sertoli TTE3 cells harboring temperature-sensitive SV40 large T-antigen, we performed global scale microarray and computational gene network analyses. In TTE3 cells, inactivation of the large T-antigen by a NPT at 39 degrees C led to cell differentiation accompanying elevation of transferrin, a marker for differentiation of Sertoli cells, and CDKN1A, a cyclin-dependent kinase inhibitor. Of the 22,690 probe sets analyzed, NPT down-regulated 498 probe sets and up-regulated 432 probe sets by >2.0-fold. Hierarchical clustering analysis showed six gene clusters. In the down-regulated cluster I, a significant genetic network including fibronectin 1 was associated with cellular growth and proliferation. In up-regulated cluster IV, a significant genetic network including CDKN1A was associated with cellular differentiation. The present results provide additional novel insights into the molecular basis of cell differentiation induced by NPT in cells.     

Overlapping Genes May Control Reprogramming of Mouse Somatic Cells into Induced Pluripotent Stem Cells (iPSCs) and Breast Cancer Stem Cells

Recent findings suggest the possibility that tumors originate from cancer cells with stem cell properties. The cancer stem cell (CSC) hypothesis provides an explanation for why existing cancer therapies often fail in eradicating highly malignant tumors and end with tumor recurrence. Although normal stem cells and CSCs both share the capacity for self-renewal and multi-lineage differentiation, suggesting that CSC may be derived from normal SCs, the cellular origin of transformation of CSCs is debatable. Research suggests that the tightly controlled balance of self-renewal and differentiation that characterizes normal stem cell function is dis-regulated in cancer. Additionally, recent evidence has linked an embryonic stem cell (ESC)-like gene signature with poorly differentiated high-grade tumors, suggesting that regulatory pathways controlling pluripotency may in part contribute to the somatic CSC phenotype. Here, we introduce expression profile bioinformatic analyses of mouse breast cells with CSC properties, mouse embryonic stem (mES) and induced pluripotent stem (iPS) cells with an emphasis on how study of pluripotent stem cells may contribute to the identification of genes and pathways that facilitate events associated with oncogenesis. Global gene expression analysis from CSCs and induced pluripotent stem cell lines represent an ideal model to study cancer initiation and progression and provide insight into the origin cancer stem cells. Additionally, insight into the genetic and epigenomic mechanisms regulating the balance between self-renewal and differentiation of somatic stem cells and cancer may help to determine whether different strategies used to generate iPSCs are potentially safe for therapeutic use.     

Proteomic analysis of membrane rafts of melanoma cells identifies protein patterns characteristic of the tumor progression stage

The molecular mechanisms controlling the progression of melanoma from a localized tumor to an invasive and metastatic disease are poorly understood. In the attempt to start defining a functional protein profile of melanoma progression, we have analyzed by LC-MS/MS the proteins associated with detergent resistant membranes (DRMs), which are enriched in cholesterol/sphingolipids-containing membrane rafts, of melanoma cell lines derived from tumors at different stages of progression. Since membrane rafts are involved in several biological processes, including signal transduction and protein trafficking, we hypothesized that the association of proteins with rafts can be regulated during melanoma development and affect protein function and disease progression. We have identified a total of 177 proteins in the DRMs of the cell lines examined. Among these, we have found groups of proteins preferentially associated with DRMs of either less malignant radial growth phase/vertical growth phase (VGP) cells, or aggressive VGP and metastatic cells suggesting that melanoma cells with different degrees of malignancy have different DRM profiles. Moreover, some proteins were found in DRMs of only some cell lines despite being expressed at similar levels in all the cell lines examined, suggesting the existence of mechanisms controlling their association with DRMs. We expect that understanding the mechanisms regulating DRM targeting and the activity of the proteins differentially associated with DRMs in relation to cell malignancy will help identify new molecular determinants of melanoma progression.     

Gene targeting and gene trap screens using embryonic stem cells: new approaches to mammalian development.

Mouse embryonic stem cell lines offer an attractive route for introducing rare genetic alternations into the gene pool since the cells can be pre-screened in culture and the mutations then transmitted into the germline through chimera production. Two applications of this technique that seem ideally suited for a genetic analysis of development are enhancer and gene trap screens for loci expressed during gastrulation and production of targeted mutations using homologous recombination. These approaches should greatly increase the number of mouse developmental mutants available and help to elucidate the genetic hierarchy controlling embryogenesis.