PcG蛋白复合体对Hox基因调节的研究

PcG蛋白广泛参与到生长、发育、增殖、分化以及肿瘤发生等重要过程.而目前为止对PcG蛋白的靶基因研究最透彻的就是Hox家族. Hox基因存在于一个高度保守的基因簇内,在调控维持正常发育及肿瘤发生中有重要作用.一般认为,PcG蛋白复合物对Hox基因进行以组蛋白表观修饰为主的沉默作用,指导Hox基因适时适地发挥功能. 同时,这个过程还需要DNA连接蛋白、ncRNA等分子的辅助.本文对Hox基因和PcG蛋白的组成和功能进行介绍,并重点归纳总结了对二者关系的经典和最新认识.     

Hox基因及其在海胆中的研究进展

Hox(homeobox genes)基因是存在于染色体上的一段高度保守序列,其蛋白产物作为转录因子也是高度保守的。这些基因调节胚胎发育,尤其在脊椎动物前-后轴(antero-posterior axis)的发育过程中起着重要作用,并指导脊椎动物的体型形成。海胆是海洋中一类比较常见的无脊椎动物和主要的海水养殖动物,它的Hox基因对它动-植物轴(animal-vegetalaxis)的形成有调控作用,并对进化研究和养殖生产具有重要意义。综述了近年来Hox基因在海胆中的研究进展。     

Hox genes from the Polystomatidae (Platyhelminthes, Monogenea)

Hox genes form a multigenic family that play a fundamental role during the early stages of development. They are organised in a single cluster and share a 60 amino acid conserved sequence that corresponds to the DNA binding domain, i.e. the homeodomain. Sequence conservation in this region has allowed investigators to explore Hox diversity in the metazoan lineages. Within parasitic flatworms only homeobox sequences of parasite species from the Cestoda and Digenea have been reported. In the present study we surveyed species of the Polyopisthocotylea (Monogenea) in order to clarify Hox identification and diversification processes in the neodermatan lineage. From cloning of degenerative PCR products of the central region of the homeobox, we report one ParaHox and 25 new Hox sequences from 10 species of the Polystomatidae and one species of the Diclidophoridae, which extend Hox gene diversity from 46 to 72 within Neodermata. Hox sequences from the Polyopisthocotylea were annotated and classified from sequence alignments and Bayesian inferences of 178 Hox, ParaHox and related gene families recovered from all available parasitic platyhelminths and other bilaterian taxa. Our results are discussed in the light of the recent Hox evolutionary schemes. They may provide new perspectives to study the transition from turbellarians to parasitic flatworms with complex life-cycles and outline the first steps for evolutionary developmental biological approaches within platyhelminth parasites.     

Non-homeodomain regions of Hox proteins mediate activation versus repression of Six2 via a single enhancer site in vivo

Hox genes control many developmental events along the AP axis, but few target genes have been identified. Whether target genes are activated or repressed, what enhancer elements are required for regulation, and how different domains of the Hox proteins contribute to regulatory specificity are poorly understood. Six2 is genetically downstream of both the Hox11 paralogous genes in the developing mammalian kidney and Hoxa2 in branchial arch and facial mesenchyme. Loss-of-function of Hox11 leads to loss of Six2 expression and loss-of-function of Hoxa2 leads to expanded Six2 expression. Herein we demonstrate that a single enhancer site upstream of the Six2 coding sequence is responsible for both activation by Hox11 proteins in the kidney and repression by Hoxa2 in the branchial arch and facial mesenchyme in vivo. DNA-binding activity is required for both activation and repression, but differential activity is not controlled by differences in the homeodomains. Rather, protein domains N- and C-terminal to the homeodomain confer activation versus repression activity. These data support a model in which the DNA-binding specificity of Hox proteins in vivo may be similar, consistent with accumulated in vitro data, and that unique functions result mainly from differential interactions mediated by non-homeodomain regions of Hox proteins.     

Hox Genes from the Tapeworm Taenia asiatica (Platyhelminthes: Cestoda)

Hox genes are important in forming the anterior-posterior body axis pattern in the early developmental stage of animals. The conserved nature of the genomic organization of Hox genes is well known in diverse metazoans. To understand the Hox gene architecture in human-infecting Taenia tapeworms, we conducted a genomic survey of the Hox gene using degenerative polymerase chain reaction primers in Taenia asiatica. Six Hox gene orthologs from 276 clones were identified. Comparative analysis revealed that T. asiatica has six Hox orthologs, including two lab/Hox1, two Hox3, one Dfd/Hox4, and one Lox2/Lox4. The results suggest that Taenia Hox genes may have undergone independent gene duplication in two Hox paralogs. The failure to detect Post1/2 orthologs in T. asiatica may suggest that sequence divergence or the secondary loss of the posterior genes has occurred in the lineage leading to the cestode and trematode.