The Dlx5 and Dlx6 homeobox genes are essential for craniofacial,axial, and appendicular skeletal development

Dlx homeobox genes are mammalian homologs of the Drosophila Distal-less (Dll) gene. The Dlx/Dll gene family is of ancient origin and appears to play a role in appendage development in essentially all species in which it has been identified. In Drosophila, Dll is expressed in the distal portion of the developing appendages and is critical for the development of distal structures. In addition, human Dlx5 and Dlx6 homeobox genes have been identified as possible candidate genes for the autosomal dominant form of the split-hand/split-foot malformation (SHFM), a heterogeneous limb disorder characterized by missing central digits and claw-like distal extremities. Targeted inactivation of Dlx5 and Dlx6 genes in mice results in severe craniofacial, axial, and appendicular skeletal abnormalities, leading to perinatal lethality. For the first time, Dlx/Dll gene products are shown to be critical regulators of mammalian limb development, as combined loss-of-function mutations phenocopy SHFM. Furthermore, spatiotemporal-specific transgenic overexpression of Dlx5, in the apical ectodermal ridge of Dlx5/6 null mice can fully rescue Dlx/Dll function in limb outgrowth.     

Pituitary homeobox 2, a novel member of the bicoid-related family of homeobox genes, is a potential regulator of anterior structure formation

Genetic analysis of mouse mutants has demonstrated the importance of the homeobox genes Rpx, Lhx3 and Pit1 for anterior pituitary gland development. Pit1 mutations have also been identified in several human families with multiple pituitary hormone deficiencies. To identify additional homeobox regulators of pituitary development, we screened an adult pituitary gland cDNA library for homeobox sequences. Here, we report the identification of a novel bicoid-related homeodomain gene expressing two alternatively spliced mRNA products, which encode proteins of 271 and 317 amino acids, respectively. The proteins have been named Ptx2a and Ptx2b since they are highly related to Ptx1/P-OTX. Ptx2 is expressed in both developing and adult pituitary gland, eye and brain tissues, suggesting an important role in development and maintenance of anterior structures. Ptx2 was mapped close to Egf on mouse chromosome 3, in a region having extensive synteny homology with HSA 4q. These data make the human Ptx2 homologue a candidate gene for Rieger syndrome, an autosomal-dominant disorder with variable craniofacial, dental, eye and pituitary anomalies.      

Dlx and Other Homeobox Genes in the Morphological Development of the Dentition

The dentition is a segmental system whose evolution and morphology bears analogy to the evolution of segmentation in the vertebral column and limb. Combinatorial expression of members of the large “Hox” class of homeobox regulatory genes has been shown to play an important role in positional specification in these skeletal systems. This raises the possibility that homeobox genes are also used for positional specification in the dentition, and several homeobox genes are known to be expressed in developing teeth. To identify additional dentally expressed homeobox genes, cDNA from from murine tooth germs at 9.5, 14.5, and 17.5 days gestational age was amplified by PCR using sets of degenerate primers to the homeodomains of 18 different classes of homeobox genes. Amplification products were cloned and sequenced and compared to known gene sequences. To date this approach has confirmed the presence of Msx1, Msx2, Dlx1, and Dlx2, and identified several other homeobox genes not previously known to be expressed in teeth: Dbx, MHox, and Mox2A, plus an additional Dlx gene, Dlx7. The Msx and Dlx genes are the best current candidates for a combinatorial mechanism that controls the differentiation of structures within and between teeth, and perhaps also the evolution of those structures.     

Threading analysis of the Pitx2 homeodomain: predicted structural effects of mutations causing Rieger syndrome and iridogoniodysgenesis.

Mutations in the homeobox gene PITX2 are responsible for a range of clinical phenotypes involving ocular and craniofacial development. Several mutations within the Pitx2 homeodomain region are specifically responsible for the development of the related autosomal-dominant disorders Rieger syndrome and iridogoniodysgenesis. To address the question of the structural effect of disease-causing mutations on the Pitx2 homeodomain, we used threading techniques to examine the tertiary structure of the Pitx2 wild-type and mutant homeodomain, using the crystal structure of Drosophila engrailed homeodomain bound with DNA as a template [Kissinger et al., 1990]. The threading analysis reveals that the wild-type Pitx2 homeodomain is indeed capable of forming the typical three-helical bundle-fold characteristic of homeodomain proteins. Energy calculations indicate that the homeodomain structure is stabilized primarily by hydrophobic interactions between residues at the helical interface. Point mutations responsible for the development of these genetic disorders were also examined; the results suggest that these mutations lead to the inability of Pitx2 to adopt its proper structure and bind to the regulatory sequences of its target gene(s), which in turn affects its metabolic role in the cell. Published 1999 Wiley-Liss, Inc.     

Dlx5, the mouse homologue of the human-imprinted DLX5 gene,is biallelically expressed in the mouse brain

The mouse Dlx5 gene encodes a distal-less-related DNA-binding homeobox protein first expressed during early embryonic development in anterior regions of mouse embryo and is located on chromosome 6, which is the syntenic region to the human chromosome 7q21–q31 imprinting cluster. Recently, its human homologue, DLX5, was identified to be imprinted and maternally expressed, at least in normal human lymphoblasts and in brain tissues. In our study, we analyzed the imprinting status of mouse Dlx5 by RT-PCR, first in the F1 of a reciprocal cross between two different mouse strains, and second in heterozygous Dlx5 mutant mice. Both approaches revealed that mouse Dlx5 followed a biallelic pattern of expression in brain tissue and in testis. Our findings suggest that the Dlx5 gene escapes genomic imprinting, at least in mice of certain genetic backgrounds.     

Characterization of the split hand/split foot malformation locus SHFM1 at 7q21.3-q22.1 and analysis of a candidate gene for its expression during limb development

Split hand/split foot malformation (SHFM) is a heterogeneous limb developmental disorder, characterized by missing digits and fusion of remaining digits. An autosomal dominant form of this disorder (SHFM1) has been mapped to 7q21.3-q22.1 on the basis of SHFM-associated chromosomal rearrangements. Utilizing a YAC contig across this region, we have defined a critical interval of 1.5 Mb by the analysis of six interstitial deletion patients and mapped the translocation breakpoints of seven ectrodactyly patients within the interval. To delineate the basic molecular defect underlying SHFM, we have searched for candidate genes in a 500 kb region containing five of the translocation breakpoints. Three genes were identified, two genes of the Distal-less (dii) homeobox gene family, DLX5 and DLX6 and a novel gene, which we named DSS1. DSS1 is predicted to encode a highly acidic polypeptide with no significant similarity to any known proteins but 100% amino acid sequence identify with its murine homolog (Dss1). Using RNA in situ hybridization analysis, we detected a tissue-specific expression profile for Dss1 in limb bud, craniofacial primordia and skin. A deficiency in expression of Dss1, DLX5 and/or DLX6 during development may explain the SHFM phenotypes.      

Spectrum of mutations and genotype-phenotype analysis in Currarino syndrome

The triad of a presacral tumour, sacral agenesis and anorectal malformation constitutes the Currarino syndrome which is caused by dorsal-ventral patterning defects during embryonic development. The syndrome occurs in the majority of patients as an autosomal dominant trait associated with mutations in the homeobox gene HLXB9 which encodes the nuclear protein HB9. However, genotype-phenotype analyses have been performed only in a few families and there are no reports about the specific impact of HLXB9 mutations on HB9 function. We performed a mutational analysis in 72 individuals from nine families with Currarino syndrome. We identified a total of five HLXB9 mutations, four novel and one known mutation, in four out of four families and one out of five sporadic cases. Highly variable phenotypes and a low penetrance with half of all carriers being clinically asymptomatic were found in three families, whereas affected members of one family showed almost identical phenotypes. However, an obvious genotype-phenotype correlation was not found. While HLXB9 mutations were diagnosed in 23 patients, no mutation or microdeletion was detected in four sporadic patients with Currarino syndrome. The distribution pattern of here and previously reported HLXB9 mutations indicates mutational predilection sites within exon 1 and the homeobox. Furthermore, sequence homology to Drosophila homeobox genes suggest that some of these mutations located within the homeobox may alter the DNA-binding specificity of HB9 while those in sequences homologous to a recently identified NLS motif of the human homeobox gene PDX-1 may impair nuclear translocation of the mutated protein.     

Regulatory roles of conserved intergenic domains in vertebrate Dlx bigene clusters

Dlx homeobox genes of vertebrates are generally arranged as three bigene clusters on distinct chromosomes. The Dlx1/Dlx2, Dlx5/Dlx6, and Dlx3/Dlx7 clusters likely originate from duplications of an ancestral Dlx gene pair. Overlaps in expression are often observed between genes from the different clusters. To determine if the overlaps are a result of the conservation of enhancer sequences between paralogous clusters, we compared the Dlx1/2 and the Dlx5/Dlx6 intergenic regions from human, mouse, zebrafish, and from two pufferfish, Spheroides nephelus and Takifugu rubripes. Conservation between all five vertebrates is limited to four sequences, two in Dlx1/Dlx2 and two in Dlx5/Dlx6. These noncoding sequences are >75% identical over a few hundred base pairs, even in distant vertebrates. However, when compared to each other, the four intergenic sequences show a much more limited similarity. Each intergenic sequence acts as an enhancer when tested in transgenic animals. Three of them are active in the forebrain with overlapping patterns despite their limited sequence similarity. The lack of sequence similarity between paralogous intergenic regions and the high degree of sequence conservation of orthologous enhancers suggest a rapid divergence of Dlx intergenic regions early in chordate/vertebrate evolution followed by fixation of cis-acting regulatory elements.     

DLX genes as targets of ALL-1: DLX 2,3,4 down-regulation in t(4;11) acute lymphoblastic leukemias

Dlx genes constitute a gene family thought to be essential in morphogenesis and development. We show here that in vertebrate cells, Dlx genes appear to be part of a regulatory cascade initiated by acute lymphoblastic leukemia (ALL)-1, a master regulator gene whose disruption is implicated in several human acute leukemias. The expression of Dlx2, Dlx3, Dlx5, Dlx6, and Dlx7 was absent in All-1 -/- mouse embryonic stem cells and reduced in All-1 +/- cells. In leukemic patients affected by the t(4;11)(q21;q23) chromosomal abnormality, the expression of DLX2, DLX3, and DLX4 was virtually abrogated. Our data indicate that Dlx genes are downstream targets of ALL-1 and could be considered as important tools for the study of the early leukemic cell phenotype.     

远端同源异型盒2和叉头盒O3a在大鼠脑皮质发育过程中的分布与表达

目的 了目的 探讨远端同源异型盒2（Dlx2）和叉头盒O3a（FoxO3a）在SD大鼠脑皮质发育过程中的表达特点。 方法 应用Real-time PCR法检测Dlx2 mRNA和FoxO3a mRNA分别在受孕11d（E11）、E13、E15、E17、E19及生后1d（P1）的表达情况;应用免疫组织化学技术显示Dlx2和FoxO3a在E11、E13、E15、E17、E19及P1蛋白的表达情况。 结果 FoxO3a与Dlx2 mRNA在E11～P1均有表达,而FoxO3a mRNA表达高峰明显早于Dlx2 mRNA;Dlx2 mRNA表达在E15～E17时大幅度上升,而在此之后始终保持这一高水平的表达;Dlx2 mRNA与FoxO3a mRNA的表达在E15～P1呈现出一致的变化趋势;Dlx2基因在E19时出现mRNA水平的高表达而未见蛋白表达。 结论 Dlx2和FoxO3a基因在胚胎后期鼠脑皮质中均有表达,且其表达趋势具有一定的一致性;两基因的分布随皮质分层而改变。