LIM同源框基因家族与神经系统

同源框基因是指一类含有同源序列的基因,它编码的蛋白质作为转录调节因子调节细胞的发育和分化,控制基因的表达形式。ＬＩＭ同源框基因不仅含有同源框基因也含有编码ＬＩＭ结构域的保守序列。     

Homeobox genes and development of the vertebrate CNS

The discovery of homeobox genes in vertebrates may allow analysis of a basic problem in developmental neurobiology: how regional differences in CNS organization are specified during development. This view is based on the roles defined for homologous genes in Drosophila development, and is supported by studies of the patterns of homeobox gene expression in vertebrate embryos. Homeobox genes comprise a multigene family, members of which are expressed in different spatially restricted domains along the anterior-posterior axis of the CNS. These observations are consistent with homeobox genes having roles in the positional specification of CNS organization, and experimental tests of this should be forthcoming shortly.     

青岛文昌鱼LIM类基因Bblim同源框区的cDNA克隆、序列分析及其在胚胎发育中的表达(英文)

不同卵裂球发育命运的特化、亦即胚胎细胞的分化是动物胚胎发育的重要特征。多数胚胎细胞尽管形态特征完全一致,却具有完全不同的发育命运。预示着：在这些细胞中存在有决定发育命运的因素———决定子。本工作克隆了青岛文昌鱼ＬＩＭ类同源框基因的同源框片段。目的在于揭示决定子的分子本质。青岛近海采集性成熟的成年青岛文昌鱼,收集未受精卵、受精卵以及各个不同时期的胚胎,液氮冻存备用。分别制备总ＲＮＡ。根据其它动物ＬＩＭ类同源框基因的序列设计引物（Ｔａｂ．１）,连续进行ＲＴＰＣＲ和ＰＣＲ两次扩增。其中,原肠胚来源的第二次ＰＣＲ产物经电泳鉴定（Ｆｉｇ．１）后,酶切、克隆入质粒、测序、将该片段所在的基因命名为Ｂｂｌｉｍ基因,该片段称为Ｂｂｌｉｍ同源框。根据Ｂｂｌｉｍ基因同源框的核苷酸序列推导出其相应的氨基酸序列（Ｆｉｇ．２）,与其它ＬＩＭ类同源框基因进行比较（Ｆｉｇ．３）后,认为：Ｂｂｌｉｍ基因可归入ｌｉｍ３类基因。比较胚胎发育各个不同时期第二次ＰＣＲ产物的含量———即Ｂｂｌｉｍ基因的转录（Ｆｉｇ．４）,提示：该基因可能在受·精·后·和·原·肠·形·成·期·前·后·两个发育阶段起作用。此外,Ｂｂｌｉｍ基因的同源域与海鞘Ｈｒｌｉｍ的     

Homeobox Genes in the Rodent Pineal Gland: Roles in Development and Phenotype Maintenance

The pineal gland is a neuroendocrine gland responsible for nocturnal synthesis of melatonin. During early development of the rodent pineal gland from the roof of the diencephalon, homeobox genes of the orthodenticle homeobox (Otx)- and paired box (Pax)-families are expressed and are essential for normal pineal development consistent with the well-established role that homeobox genes play in developmental processes. However, the pineal gland appears to be unusual because strong homeobox gene expression persists in the pineal gland of the adult brain. Accordingly, in addition to developmental functions, homeobox genes appear to be key regulators in postnatal phenotype maintenance in this tissue. In this paper, we review ontogenetic and phylogenetic aspects of pineal development and recent progress in understanding the involvement of homebox genes in rodent pineal development and adult function. A working model is proposed for understanding the sequential action of homeobox genes in controlling development and mature circadian function of the mammalian pinealocyte based on knowledge from detailed developmental and daily gene expression analyses in rats, the pineal phenotypes of homebox gene-deficient mice and studies on development of the retinal photoreceptor; the pinealocyte and retinal photoreceptor share features not seen in other tissues and are likely to have evolved from the same ancestral photodetector cell.     

Msx homeobox genes inhibit differentiation through upregulation of cyclin D1

During development, patterning and morphogenesis of tissues are intimately coordinated through control of cellular proliferation and differentiation. We describe a mechanism by which vertebrate Msx homeobox genes inhibit cellular differentiation by regulation of the cell cycle. We show that misexpression of Msx1 via retroviral gene transfer inhibits differentiation of multiple mesenchymal and epithelial progenitor cell types in culture. This activity of Msx1 is associated with its ability to upregulate cyclin D1 expression and Cdk4 activity, while Msx1 has minimal effects on cellular proliferation. Transgenic mice that express Msx1 under the control of the mouse mammary tumor virus long terminal repeat (MMTV LTR) display impaired differentiation of the mammary epithelium during pregnancy, which is accompanied by elevated levels of cyclin D1 expression. We propose that Msx1 gene expression maintains cyclin D1 expression and prevents exit from the cell cycle, thereby inhibiting terminal differentiation of progenitor cells. Our model provides a framework for reconciling the mutant phenotypes of Msx and other homeobox genes with their functions as regulators of cellular proliferation and differentiation during embryogenesis.     

Homeobox Genes in the Developing Mouse Brain

Abstract: Any list of past and recent findings on vertebrate brain prenatal development would have to include the fundamental roles of homeobox genes, the genes encoding the nuclear regulatory homeodomain proteins. The discovery of homeobox genes and their involvement as master regulatory elements in programing the development of an embryo into a complete adult organism has provided a key to our understanding of ontogenesis. Also, the correlation of mouse developmental mutants and their corresponding human syndromes with mutations in homeobox genes has provided further evidence for the fundamental role of homeobox genes during the vertebrate brain embryonic development. Here, we review the expression patterns and the phenotypes of gene mutations that implicate a large repertoire of mouse homeobox genes in the specification of neuronal functions during brain embryogenesis.     

Regulated expression patterns of IRX-2, an Iroquois-class homeobox gene, in the human breast

In the mouse mammary gland, homeobox gene expression patterns suggest roles in development and neoplasia. In the human breast, we now identify a family of Iroquois-class (IRX) homeobox genes. One gene, IRX-2, is expressed in discrete epithelial cell lineages being found in ductal and lobular epithelium, but not in myoepithelium. Expression is absent from associated mesenchymal adipose stroma. During gland development, expression is concentrated in terminal end buds and terminal lobules and is reduced in a subset of epithelial cells during lactation. In contrast to observations for many homeobox genes in the mouse mammary gland in which homeobox gene expression is lost on neoplastic progression, IRX-2 expression is maintained in human mammary neoplasias. Data suggest IRX-2 functions in epithelial cell differentiation and demonstrate regulated expression during ductal and lobular proliferation as well as lactation.     

Whole‐genome sequencing reveals a large deletion in the MITF gene in horses with white spotted coat colour and increased risk of deafness

White spotting phenotypes in horses are highly valued in some breeds. They are quite variable and may range from the common white markings up to completely white horses. EDNRB, KIT, MITF, PAX3 and TRPM1 represent known candidate genes for white spotting phenotypes in horses. For the present study, we investigated an American Paint Horse family segregating a phenotype involving white spotting and blue eyes. Six of eight horses with the white‐spotting phenotype were deaf. We obtained whole‐genome sequence data from an affected horse and specifically searched for structural variants in the known candidate genes. This analysis revealed a heterozygous ~63‐kb deletion spanning exons 6–9 of the MITF gene (chr16:21 503 211–21 566 617). We confirmed the breakpoints of the deletion by PCR and Sanger sequencing. PCR‐based genotyping revealed that all eight available affected horses from the family carried the deletion. The finding of an MITF variant fits well with the syndromic phenotype involving both depigmentation and an increased risk for deafness and corresponds to human Waardenburg syndrome type 2A. Our findings will enable more precise genetic testing for depigmentation phenotypes in horses.     

Leech segmentation: A molecular perspective

A variety of leech homeobox genes have been identified by homology with genes that are known to bring about the regionalization and segmentation of the anteroposterior body axis in other organisms. Embryonic expression patterns suggest a number of interphyletic similarities in the way that these genes are utilized. However, several interesting differences have also been observed. In particular, transplantation experiments in the leech embryo have shown that axially aligned patterns of homeobox gene expression are not specified by a global pattern of positional cues. Rather, the leech independently establishes anteroposterior patterns of gene expression in each of five discrete stem cell lineages, and these patterns are brought into their final alignment through a process of morphogenetic assembly.     

A novel KIT deletion variant in a German Riding Pony with white‐spotting coat colour phenotype

White spotting phenotypes in horses may be caused by developmental alterations impairing melanoblast differentiation, survival, migration and/or proliferation. Candidate genes for white‐spotting phenotypes in horses include EDNRB, KIT, MITF, PAX3 and TRPM1. We investigated a German Riding Pony with a sabino‐like phenotype involving extensive white spots on the body together with large white markings on the head and almost completely white legs. We obtained whole genome sequence data from this horse. The analysis revealed a heterozygous 1273‐bp deletion spanning parts of intron 2 and exon 3 of the equine KIT gene (Chr3: 79 579 925–79 581 197). We confirmed the breakpoints of the deletion by PCR and Sanger sequencing. Knowledge of the functional impact of similar KIT variants in horses and other species suggests that this deletion represents a plausible candidate causative variant for the white‐spotting phenotype. We propose the designation W28 for the mutant allele.     

Regional expression of the rice KN1-type homeobox gene family during embryo, shoot, and flower development.

We report the isolation, sequence, and pattern of gene expression of members of the KNOTTED1 (KN1)-type class 1 homeobox gene family from rice. Phylogenetic analysis and mapping of the rice genome revealed that all of the rice homeobox genes that we have isolated have one or two direct homologs in maize. Of the homeobox genes that we tested, all exhibited expression in a restricted region of the embryo that defines the position at which the shoot apical meristem (SAM) would eventually develop, prior to visible organ formation. Several distinct spatial and temporal expression patterns were observed for the different genes in this region. After shoot formation, the expression patterns of these homeobox genes were variable in the region of the SAM. These results suggest that the rice KN1-type class 1 homeobox genes function cooperatively to establish the SAM before shoot formation and that after shoot formation, their functions differ.     

Impact of white-spotting alleles,including W20, on phenotype in the American Paint Horse

The American Paint Horse Association (APHA) records pedigree and performance information for their breed, a stock-type horse valued as a working farm or ranch horse and as a pleasure horse. As the name implies, the breed is also valued for its attractive white-spotting patterns on the coat. The APHA utilizes visual inspections of photographs to determine if coat spotting exceeds threshold anatomical landmarks considered characteristic of desirable patterns. Horses with sufficient white patterning enter the ‘Regular’ registry, rather than the ‘Solid Paint-Bred’ division, providing a threshold modeled phenotype. Genetic studies previously defined sequence variants corresponding to 35 alleles for white spotting in the horse. Here, we calculate the allele frequencies for nine common white-spotting alleles in the American Paint Horse using a sample of 1054 registered animals. The APHA spotting phenotype is altered by additive interactions among spotting loci, and epistatically by the MC1R and ASIP genes controlling pigment production. The W20 allele within the KIT gene, independent of other known spotting alleles, was strongly associated with the APHA-defined white-spotting phenotype (P = 1.86 × 10⁻¹⁸), refuting reports that W20 acts only as a modifier of other underlying white-spotting patterns. The parentage of an individual horse, either American Paint or American Quarter Horse, did not alter the likelihood of its entering the APHA Regular Registry. An empirical definition of the action of these genetic loci on the APHA-defined white-spotting phenotype will allow more accurate application of genome-assisted selection for improving color production and the marketability of APHA horses.