Altered Hox expression and increased cell death distinguish Hypodactyly from Hoxa13 null mice.

Hypodactyly (Hoxa13Hd) mice have a small deletion within the coding sequence of Hoxa13 and a limb phenotype that is more severe than that of mice with an engineered null allele of Hoxa13. We used whole-mount in situ hybridization, Nile blue sulfate staining and genetic crosses to determine the basis for the phenotypic differences between these two mutants. Expression of Hoxd13 was unaffected in Hoxa13-/- mice, but its domain was reduced at the anterior and posterior margins of the autopod in Hoxa13Hd/Hd limb buds. The maturation of Hoxd11 expression was delayed and expression of Hoxa11 failed to become restricted to the autopod/zeugopod junction in both Hoxa13Hd/Hd and Hoxa13-/- limb buds compared to wild-type mice. Fgf8 expression was normal in both Hoxa13Hd/Hd and Hoxa13-/- mice throughout limb development. A dramatic increase in cell death was observed in limb bud mesenchyme of Hoxa13Hd/Hd mice as early as E11.5 but not in mice homozygous for the null allele. Genetic background was excluded as the basisforthe phenotypic differences. Compound heterozygotes (Hoxa13-/Hd) displayed an intermediate phenotype relative to both homozygotes suggesting that Hoxa13Hd has an effect on the development of the autopod beyond that which may result from a loss of HOXA13 protein. These results showthat Hoxa13Hd has a negative effect on the survival of the mesenchyme in the autopod, unlike the Hoxa13 null mutation, that cannot be explained by a failure of the AER to express Fgfs. In addition, at least one target of HOXA13 may be Hoxa11.     

热带爪蟾Hoxa11基因克隆及序列的进化分析

 H oxa1 1基因是控制脊椎动物肢发育的重要基因 .根据人和鼠 H oxa1 1基因外显子 区和 区的保守序列设计了简并引物 ,采用 PCR法从热带爪蟾基因组 DNA中扩增和克隆到了H oxa1 1基因 ,并测定了核苷酸序列 .克隆的热带爪蟾 H oxa1 1基因片段长 1 598bp,由外显子 、内含子和外显子 三部分组成 ,其中外显子 60 4 bp,外显子 49bp.将该片段的核苷酸序列与人、鼠、斑马鱼 H oxa1 1基因的相应区域进行比较 ,发现该基因的内含子长度存在明显差异 .斑马鱼、热带爪蟾、鼠和人的内含子长度分别为 632 bp,945bp,1 42 1 bp和 1 41 2 bp,随动物进化阶梯的提高而变长 .外显子 区则高度保守 ,都是 49bp,外显子 区在长度上呈现约 1 0 %的变异 .将热带爪蟾 H oxa1 1基因编码的氨基酸序列与人、鼠、斑马鱼进行比较 ,它们之间分别有 67.0 %、66.5%和 46.0 %的同源性 .热带爪蟾与哺乳动物的同源性高于鱼类 ,可能反映了脊椎动物从鳍到肢的进化过程中 ,H oxa1 1基因经历了较多的变异 .     

Chicken HOXA3 gene: its expression pattern and role in branchial nerve precursor cell migration

In vertebrates, the proximal and distal sensory ganglia of the branchial nerves are derived from neural crest cells (NCCs) and placodes, respectively. We previously reported that in Hoxa3 knockout mouse embryos, NCCs and placode-derived cells of the glossopharyngeal nerve were defective in their migration. In this report, to determine the cell-type origin for this Hoxa3 knockout phenotype, we blocked the expression of the gene with antisense morpholino oligonucleotides (MO) specifically in either NCCs/neural tube or placodal cells of chicken embryos. Our results showed that HOXA3 function was required for the migration of the epibranchial placode-derived cells and that HOXA3 regulated this cell migration in both NCCs/neural tube and placodal cells. We also report that the expression pattern of chicken HOXA3 was slightly different from that of mouse Hoxa3.     

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.