同源盒基因和肿瘤

同源盒基因是一族含有共同的183个核苷酸序列的调节基因,在生物的发育分化中起重要的作用,具有高度保守性,是转录过程的主控基因,本文结合有关文献,探讨同源盒基因在各种恶性肿瘤中的表达与肿瘤发生,发展相关的分子机制及其常用的分子生物学研究方法。     

同源异形基因浅说

同源异形基因是决定果蝇体节形成的发育基因,其同源异形盒子编码同源异形结构域蛋白,在进化上极为保守,从低等到高等动物的基因组中都有存在。其表达具严格的时、空特异性,可控制细胞的分化状态及表型,推测可能是通过对其他基因的调节而发挥作用。最近表明线虫及哺乳类细胞中的转录因子也具有同源异形蛋白,初步证明它们也是转录因子,这对解释同源异形蛋白的功能、探索基因表达的调节机制有重要意义。     

植物同源异型基因及同源异型盒基因的研究进展

植物同源异型基因及同源异型盒基因是涉及植物个体发育调节的两类重要转录因子编码基因.近10年来的研究表明,这两类基因及其产物的结构与功能具有明显的差异.深入研究这两类基因的结构与功能对揭示植物的发育机制具有重要意义.     

同源异型盒基因Emx在人胎盘绒毛膜中的扩增

以鹌鹑Emx cDNA片段作为探针,对人胎盘绒毛膜细胞和成人血细胞的基因组DNA进行DNA印迹分析. 结果表明,在人胎盘绒毛膜细胞中Emx基因剂量较成人血细胞高6倍,显示Emx基因在人胎盘绒毛膜细胞基因组中发生了扩增.     

Rx同源异型盒基因与视觉神经系统发育的关系

Rx (retinal homeobox)家族是新发现的一类与视觉神经系统发育密切相关的同源异型盒基因,调控眼基质、视泡、视网膜、前脑以及中脑部分区域的发育.Rx基因的研究将对视觉神经系统发育的调控机制提供新的认识.     

同源盒蛋白与人类白血病

同源盒蛋白是一类具有特定的时空表达模式的转录调控因子,本对造血细胞内同源盒基因的表达特点及因同源盒蛋白表达异常所致白血病的各种分子机制加以综述,提出同源盒基因的结构与功能异常是人类种瘤发生的重要原因之一。     

为什么鸟能飞,人不能飞：——同源异形基因与进化

为什么鸟能飞,人不能飞？──同源异形基因与进化关键词同源异形基因,进化［编者按：１００年前（１８８４）发现了生物的同源异形性（ｈｏｍｅｏｓｉｓ）。９０年后（１９８４）找到了同源异形基因,并认为它是所有生物个体发育中的共同开关。近十年来对它进行了广泛研...     

同源盒基因A10编码蛋白的靶调节基因的筛选与鉴定

目的：筛选和鉴定同源盒基因A10编码蛋白（HOXA10）的靶调节基因。方法：以人子宫内膜细胞系AN3CA为实验对象,采用染色质免疫沉淀方法筛选HOXA10靶基因;采用平端克隆方法构建HOXA10靶基因库;采用DNA序列分析结合生物信息学方法鉴定HOXA10靶基因。结果：共获得含有HOXA10结合片段的克隆197个,选取插入片段大于100bp的质粒67个进行DNA序列分析,其中含有HOXA10结合序列TTAT的基因16个。结论：初步筛选出16个HOXA10候选靶基因,为进一步研究HOXA10的基因调节机理提供了新的思路。     

Evolution of Antennapedia-Class Homeobox Genes

Antennapedia (Antp)-class homeobox genes are involved in the determination of pattern formation along the anterior-posterior axis of the animal embryo. A phylogenetic analysis of Antp-class homeodomains of the nematode, Drosophila, amphioxus, mouse, and human indicates that the 13 cognate group genes of this gene family can be divided into two major groups, i.e., groups I and II. Group I genes can further be divided into subgroups A (cognate groups 1-2), B (cognate group 3), and C (cognate groups 4-8), and group II genes can be divided into subgroups D (cognate groups 9-10) and E (cognate groups 11-13), though this classification is somewhat ambiguous. Evolutionary distances among different amino acid sequences suggest that the divergence between group I and group II genes occurred ~1000 million years (MY) ago, and the five different subgroups were formed by ~600 MY ago, probably before the divergence of Pseudocoelomates (e.g., nematodes) and Coelomates (e.g., insects and chordates). Our results show that the genes that are phylogenetically close are also closely located in the chromosome, suggesting that the colinearity between the gene expression and gene arrangement was generated by successive tandem gene duplications and that the gene arrangement has been maintained by some sort of selection.     

植物同源盒基因的克隆与功能研究

同源盒基因在植物、动物、菌物的广泛存在说明这种结构在真核生物进化的早期就已出现,并暗示其具有重要功能。本文对植物同源盒基因的克隆与功能研究进行了综述,包括同源盒基因编码蛋白的结构特点、类型,并以玉米Knl、水稻OSH1及拟南芥STM为例,介绍了同源盒基因功能研究的现状。现有证据表明,同源盒基因与植物的发育过程有关。     

Homeobox Genes Expressed During Echinoderm Arm Regeneration

Regeneration in echinoderms has proved to be more amenable to study in the laboratory than the more classical vertebrate models, since the smaller genome size and the absence of multiple orthologs for different genes in echinoderms simplify the analysis of gene function during regeneration. In order to understand the role of homeobox-containing genes during arm regeneration in echinoderms, we isolated the complement of genes belonging to the Hox class that are expressed during this process in two major echinoderm groups: asteroids (Echinaster sepositus and Asterias rubens) and ophiuroids (Amphiura filiformis), both of which show an extraordinary capacity for regeneration. By exploiting the sequence conservation of the homeobox, putative orthologs of several Hox genes belonging to the anterior, medial, and posterior groups were isolated. We also report the isolation of a few Hox-like genes expressed in the same systems.     

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.     

植物同源异型枢基因的研究进展

植物同源异型枢基因是涉及到植物个体发育的一类重要转录因子编码基因.这类基因及其编码蛋白的结构具有明显的保守性,在植物中广泛存在,研究这类基因,对于揭示植物的发育机制具有重要意义.     

Expression of Regulatory Homeobox Genes during Retina Regeneration in Adult Newts

We studied molecular-genetic mechanisms of retina regeneration in amphibians and, specifically, expression of the homeobox genes Pax6, Prox1, and Six3 in normal development and during retina regeneration in the newt. Based on the structural analysis of genes in closely related amphibian species, primers were constructed that flank certain regions of these genes. PCR fragments of calculated length were obtained. The relationship of PCR products to the above genes was confirmed by sequencing. A comparative PCR analysis of expression of Pax6, Prox1, and Six3 was carried out in the native and regenerating newt retina, which allowed estimation of the level of expression. cDNA libraries obtained from the native and regenerating retina were used as templates. The libraries were preliminary standardized according to glyceraldehydes-3-phosphate dehydrogenase, an enzyme of general cell metabolism. The genes we studied were expressed in both native and regenerating retina. The level of Pax6 and Prox1 expression increased during regeneration, while that of Six3 decreased. The decrease in the level of Six3 expression could be due to antagonistic interrelations of Prox1 and Six3. The changed level of Prox1 and Six3 expression is a new fact and requires further studies. The interactions between these and other regulatory genes and localization of their expression in the cells of native and regenerating retina will be studied using in situ hybridization and immunohistochemistry.