Gene expression profiling identifies eleven DNA repair genes down-regulated during mouse neural crest cell migration

Neural Crest Cells (NCCs) are transient multipotent migratory cells that derive from the embryonic neural crest which is itself derived from the margin of the neural tube. DNA repair genes are expressed in the early stages of mammalian development to reduce possible replication errors and genotoxic damage. Some birth defects and cancers are due to inappropriate or defective DNA repair machinery, indicating that the proper functioning of DNA repair genes in the early stages of fetal development is essential for maintaining DNA integrity. We performed a genome-wide expression analysis combining laser capture microdissection (LCM) and high-density oligo-microarray of murine NCCs at pre-migratory embryonic days 8.5 (E8.5), and at E13.5, as well as on neural crest-derived cells from the adrenal medulla at postnatal day 90. We found 11 genes involved in DNA repair activity (response to DNA damage stimulus, DNA damage checkpoint, base-excision repair, mismatch repair), over-expressed in the early stages of mouse embryo development. Expression of these 11 genes was very low or undetectable in the differentiated adrenal medulla of the adult mouse. Amongst the 11 genes, 6 had not been previously reported as being over-expressed during mouse embryonic development. High expression of DNA repair genes in enriched NCCs during early embryonic development may contribute to maintaining DNA integrity whilst failure of some of these genes may be associated with the onset of genetic disease and cancer. Our model of enriched murine NCCs and neural crest-derived cells can be used to elucidate the key roles of genes during normal embryonic development and in cancer pathogenesis.     

Genomic screen for genes involved in mammalian craniofacial development

Using a subtractive hybridisation approach, we enriched for genes likely to play a role in embryonic development of the mammalian face and other structures. This was achieved by subtracting cDNA derived from adult mouse liver from that derived from 10.5 dpc mouse embryonic branchial arches 1 and 2. Random sequencing of clones from the resultant library revealed that a high percentage correspond to genes with a previously established role in embryonic development and disease, while 15% represent novel or uncharacterised genes. Whole mount in situ hybridisation analysis of novel genes revealed that approximately 50% have restricted expression during embryonic development. In addition to expression in branchial arches, these genes showed a range of expression domains commonly including neural tube and somites. Notably, all genes analysed were found to be expressed not only in the branchial arches but also in the developing limb buds, providing support for the hypothesis that development of the limbs and face is likely to involve analogous molecular processes.     

mED2-一个小鼠胚胎发育的新基因

克隆参与胚胎发育的新基因并研究其表达规律和功能是揭示胚胎发育的基因调控机理的重要途径。囊胚形成和原肠形成是哺乳动物胚胎发育过程中的两个关键阶段。囊胚阶段发生了胚胎的第一次分化,是细胞多能性和分化的一个转折点。此时涉及的基因活动,既有维持胚胎干细胞全能性或多能性的基因活动,又有按照预定发育模式参与胚胎定向分化的基因活动。原肠期是胚胎发育过程中的第二个关键转折点,涉及到3个胚层的形成和细胞命运决定等多种变化。在这个时期胚胎获得了胎儿原基的所有信息,新组织的产生和细胞迁移的再生组织与形态发生、细胞增殖、细胞分化、模式形成等存在着非常复杂而相互协调的关联。大多数细胞正由原来的多潜能逐渐向寡潜能发展,控制组织器官形态建成的基因正逐渐开启。这两个时期的基因表达图式、特征和种类会有很大的差异和变化,因此研究这两个时期的新基因的表达规律和功能,将是了解胚胎发育的基因调控机理的重要途径。文章以这两个时期胚胎为原始材料,利用减法杂交方法克隆到一新的小鼠胚胎基因mED2,对其进行了表达规律和生物学功能的初步分析。RT-PCR-Southern和原位杂交实验表明,mED2基因转录水平具有发育阶段的依赖性;随着发育过程的进行,其表达主要在胚神经系统和中胚层衍生的组织表达。mED2基因活性的knockdown对于合子的卵裂和植入前早期胚胎发育均有抑制作用。亚细胞定位实验表明,mED2基因编码的蛋白基本定位于细胞核膜及其临近的内膜细胞器（粗糙内质网和高尔基体）。根据生物信息学分析,mED2蛋白可能为一跨膜蛋白且与含有硫氧还蛋白结构域的蛋白有部分匹配。由此推测mED2基因参与了小鼠植入前早期胚胎发育,其基因产物可能通过蛋白之间的相互作用,即对蛋白进行后期修饰、折叠及行使分子伴侣等作用来活化或抑制其靶蛋白的活性,进而参与小鼠的早期胚胎发育。     

The X-linked imprinted gene family Fthl17 shows predominantly female expression following the two-cell stage in mouse embryos

Differences between male and female mammals are initiated by embryonic differentiation of the gonad into either a testis or an ovary. However, this may not be the sole determinant. There are reports that embryonic sex differentiation might precede and be independent of gonadal differentiation, but there is little molecular biological evidence for this. To test for sex differences in early-stage embryos, we separated male and female blastocysts using newly developed non-invasive sexing methods for transgenic mice expressing green fluorescent protein and compared the gene-expression patterns. From this screening, we found that the Fthl17 (ferritin, heavy polypeptide-like 17) family of genes was predominantly expressed in female blastocysts. This comprises seven genes that cluster on the X chromosome. Expression analysis based on DNA polymorphisms revealed that these genes are imprinted and expressed from the paternal X chromosome as early as the two-cell stage. Thus, by the time zygotic genome activation starts there are already differences in gene expression between male and female mouse embryos. This discovery will be important for the study of early sex differentiation, as clearly these differences arise before gonadal differentiation.     

A sensitised mutagenesis screen in the mouse to explore the bovine genome: study of muscle characteristics

Meat yield and quality are closely related to muscle development. The muscle characteristics mainly take place during embryonic and postnatal phases. Thus, genetic control of muscle development in early stages represents a significant stake to improve product quality and production efficiency. In bovine, several programmes have been developed to detect quantitative trait loci (QTL) affecting growth, carcass composition or meat quality traits. Such strategy is incontestably very powerful yet extremely cumbersome and costly when dealing with large animals such as ruminants. Furthermore, the fine mapping of the QTL remains a real challenge. Here, we proposed an alternative approach based on chemical mutagenesis in the mouse combined with comparative genomics to identify regions or genes controlling muscle development in cattle. At present, we isolated seven independent mouse lines of high interest. Two lines exhibit a hypermuscular phenotype, and the other five show various skeletomuscular phenotypes. Detailed characterisation of these mouse mutants will give crucial input for the identification and the mapping of genes that control muscular development. Our strategy will provide the opportunity to understand the function and control of genes involved in improvement of animal physiology.     

mED2—A Novel Gene Involved in Mouse Embryonic Development

Dissection of new genes underlying embryonic development is important for our understanding of the molecular mechanism of vertebrate embryonic development. In this study, the expression pattern and functional analysis of a new gene, called mED2, originally cloned from mouse embryos using subtractive hybridization was reported. mED2 expression patterns were characterized by RT-PCR-Southern hybridization and in situ hybridization. The results showed that mED2 was mainly expressed in the embryonic nervous system and mesoderm-derived tissues and its expression varied depending on the embryonic developmental stages. The knockdown of mED2 activity by antisense RNA injection inhibited zygote cleavage and blastocyst formation during pre-implantation in mice. Subcellular localization of mED2-eGFP fusion protein revealed a pattern of nuclear membrane and juxta-/perinuclear location such as in the rough endoplasmic reticulum and Golgi apparatus. This finding was supported by bioinformatics analysis, which indicated mED2 protein to be a transmembrane protein with partial homology to the thioredoxin family of proteins. It is inferred that mED2 gene can probably take part in early embryonic development in mouse and may be involved in target protein posttranslational modification, turnover, folding, and stability at the endoplasmic reticulum and/or the Golgi apparatus.     

The mouse ascending: perspectives for human-disease models

The laboratory mouse is widely considered the model organism of choice for studying the diseases of humans, with whom they share 99% of their genes. A distinguished history of mouse genetic experimentation has been further advanced by the development of powerful new tools to manipulate the mouse genome. The recent launch of several international initiatives to analyse the function of all mouse genes through mutagenesis, molecular analysis and phenotyping underscores the utility of the mouse for translating the information stored in the human genome into increasingly accurate models of human disease.     

More to learn from gene knockouts

Gene targeting by homologous recombination in mouse embryonic stem cells is a powerful technique to determine the physiological function of any gene product in embryonic and postnatal development and in molecular pathogenesis. Although the technique is very demanding and still in its developing stage several knockout mice carrying disrupted genes, which were once thought important for the development or molecular pathogenesis of certain tissues, have given unexpected results. A gene/function redundancy or superfluous and on-functional theory has been advanced by many investigatiors to explain the unexpected results. These surprising results may teach us a new lesson and lead to a revision of the strongly held view that highly conserved and abundantly expressed genes have a prominent role and function in cell physiology and development Additional, they may also support the notion that molecular cross-talk among the genes may play an important role in determining the minimal phenotype.     

Proto-oncogenes in mammalian development.

The phenotypic analysis of mice carrying germline mutations in protooncogenes is beginning to provide convincing genetic evidence for the important role that these genes play in mammalian development and differentiation. Two approaches are being taken to elucidate the biological function of proto-oncogenes in vivo. The first involves the molecular analysis of existing mouse developmental mutants, while the second approach involves the generation of specific germline mutations by gene targeting using homologous recombination in embryonic stem cells. Several key points have already emerged from these genetic approaches. First, many proto-oncogenes are important to more than one cell lineage and function both during embryogenesis and in the adult. Second, the patterns of expression of these genes provide only a guide to their biological function. Third, mutant phenotypes are generally less severe than would be expected from their expression patterns, suggesting that there may be functional overlap between two or more members of a gene family.