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 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.     

Functional dissection of Ultrabithorax proteins in D. melanogaster

Expression of Ultrabithorax (UBX) proteins via a heat-inducible promoter generated homeotic transformations of segmental identities in the embryonic cuticle and peripheral nervous system (PNS) of Drosophila and transformed antennae into legs in the adult. The embryonic transformations were used to determine the identity functions of members of the UBX family and UBX mutant forms. Whereas UBX forms I and IV each induced the cuticle transformations, only form I induced the PNS transformations. Analysis of the transformations generated by UBX deletions and by a chimeric Ultrabithorax-Antennapedia protein demonstrated that the majority of the UBX identity information is contained within the C-terminal, homeodomain-containing portion of the protein. Implications of these results for how homeotic proteins select particular metameric identities are discussed.     

Primary structure, developmentally regulated expression and potential duplication of the zebrafish homeobox gene ZF-21.

We report the molecular cloning and characterization of a cDNA derived from a zebrafish gene (ZF-21) related to the mouse homeobox containing gene Hox2.1. Interesting information about the differential conservation of various domains was gained from comparisons between the putative protein sequences from ZF-21 (275 amino acids) and Hox2.1 (279 aa). A separate DNA binding domain including the ZF-21 homeodomain and 36 additional flanking residues is completely identical to the C-terminal part of Hox2.1. As a consequence, these two mouse and zebrafish proteins must have identical DNA binding properties. A lower level of sequence identity between the N-terminal coding regions of ZF-21 and Hox2.1 reduces the total protein homology to 81%. However, short stretches of perfect homology in these N-terminals suggests that the essential biochemical functions are the same. As expected for true homologues, the ZF-21 and Hox2.1 genes also share extensive similarities with respect to non-coding sequences and temporal expression during embryogenesis. The finding of a potential ZF-21 duplication is discussed in relation to functional and evolutionary aspects of vertebrate homeobox genes.     

Distinct Molecular Strategies for Hox-Mediated Limb Suppression in Drosophila: From Cooperativity to Dispensability/Antagonism in TALE Partnership

The emergence following gene duplication of a large repertoire of Hox paralogue proteins underlies the importance taken by Hox proteins in controlling animal body plans in development and evolution. Sequence divergence of paralogous proteins accounts for functional specialization, promoting axial morphological diversification in bilaterian animals. Yet functionally specialized paralogous Hox proteins also continue performing ancient common functions. In this study, we investigate how highly divergent Hox proteins perform an identical function. This was achieved by comparing in Drosophila the mode of limb suppression by the central (Ultrabithorax and AbdominalA) and posterior class (AbdominalB) Hox proteins. Results highlight that Hox-mediated limb suppression relies on distinct modes of DNA binding and a distinct use of TALE cofactors. Control of common functions by divergent Hox proteins, at least in the case studied, relies on evolving novel molecular properties. Thus, changes in protein sequences not only provide the driving force for functional specialization of Hox paralogue proteins, but also provide means to perform common ancient functions in distinct ways.     

东亚飞蝗UBX结构域包含蛋白基因 LmUBX2 的克隆和表达分析

【目的】UBX结构域包含蛋白是p97/CDC48的辅助因子。p97在泛素化相关的多种细胞过程中起着重要的作用,如依赖泛素 蛋白酶体系统的蛋白质降解和同型膜融合等。本研究旨在克隆东亚飞蝗 Locusta migratoria manilensis (Meyen)的UBX结构域包含蛋白基因,分析其组织和发育表达格局,为进一步研究UBX结构域包含蛋白基因的功能奠定基础。【方法】通过分析东亚飞蝗的转录组数据克隆UBX结构域包含蛋白基因,采用实时定量PCR技术分析该基因在不同发育时期和成虫不同组织中的表达水平。【结果】克隆到东亚飞蝗的一个UBX结构域包含蛋白基因,命名为 LmUBX2。 LmUBX2 开放阅读框长1 020 bp,编码399个氨基酸,预测分子量和等电点分别为37.8 kDa和6.03,与其他UBX结构域包含蛋白的氨基酸一致性为37%~64%,N端和C端分别有一个保守的UBA结构域和UBX结构域。序列比较和系统发育分析发现 LmUBX2 属于SAKS1亚家族。定量分析发现,LmUBX2 在整个生命周期中都有表达,但成虫期的表达水平最高;在检测的所有组织中都有表达,但在精巢和卵巢中表达水平最高。【结论】研究结果说明 LmUBX2 可能参与东亚飞蝗多种生理过程,尤其可能与东亚飞蝗的生殖有关,但还需深入研究。     

A comparison of Hox3 and Zen protein coding sequences in taxa that span the <Emphasis Type="Italic">Hox3</Emphasis>/<Emphasis Type="Italic">zen</Emphasis> divergence

The class 3 Hox genes of insects have diverged--in expression domain and functional role during embryogenesis--compared to those of other bilaterians. Whereas the canonical ortholog (Hox3) is involved in axial patterning of the embryonic body, the insect ortholog (zen) is involved in extraembryonic development. In this paper, we present sequence data from the centipede Strigamia maritima, the collembolan Folsomia candida, and the insect Thermobia domestica. With these data, complete coding sequences are now known for orthologs in all four arthropod classes and all three great bilaterian clades. We make use of this large Hox3/Zen ortholog data set to define differences in the protein sequences encoded by insect zen genes compared to all other Hox3 orthologs. Folsomia and Thermobia are particularly relevant to determining when zen diverged from Hox3 over evolutionary time. Intriguingly, the orthologs of these two species have some protein sequence features typical of Hox3 and some typical of Zen, and they differ from one another for these features.