Genetic and physical mapping of the mouse Ulnaless locus

Copy-number variations, noncoding sequences, and human phenotypes

Whereas single-nucleotide polymorphisms and their role in predisposition to disease have been studied extensively, the analysis of structural variants--genomic changes such as insertions, deletions, inversions, duplications, and translocations--is still in its infancy. Changes in copy number, also known as copy-number variations (CNVs), constitute one such group of these structural variants. CNVs are structural genomic variants that arise from deletions (loss) or duplications (gain), and as a consequence result in a copy-number change of the respective genomic region. CNVs may include entire genes or regions of transcribed sequence, or, indeed, comprise only nontranscribed sequences. Whereas the duplication or deletion of a gene can be expected to have an effect on gene dosage, the consequences of CNVs in nontranscribed sequences are less obvious. Here we review CNVs that involve regulatory nontranscribed regions of the genome, describe the associated human phenotypes, and discuss possible disease mechanisms.

Kantaputra mesomelic dysplasia: a second reported family

We present the clinical and radiographic findings in a mother and son with a dominantly inherited mesomelic skeletal dysplasia almost identical to that described in a large Thai family by Kantaputra et al., in which ankle, carpal and tarsal synostoses were noted. The proband in the family is a 48-year-old woman with mesomelic limb shortening, most pronounced in the upper limbs. Her parents were of normal stature and build. Her 15-year-old son has similar mesomelic limb shortening, and in addition talipes equinovarus. Radiological examination showed severe shortening of the radius and ulna with bowing of the radius and dislocation of the radial head. Multiple carpal and tarsal synostoses were present and in addition, the talus and calcaneum were fused. In the original Thai family, linkage to chromosome 2q24-q32, which contains the HOXD cluster has been reported, and it is postulated that the phenotype may result from a disturbance of regulation of the HOXD cluster. Although linkage analysis was not possible in our family, molecular analysis was undertaken and HOXD11 was sequenced, however, no mutations were detected. This is only the second reported family affected with Kantaputra mesomelic dysplasia (MIM 156232), a distinct mesomelic skeletal dysplasia.

A global control region defines a chromosomal regulatory landscape containing the HoxD cluster

During limb development, coordinated expression of several Hoxd genes is required in presumptive digits. We searched for the underlying control sequences upstream from the cluster and found Lunapark (Lnp), a gene which shares limb and CNS expression specificities with both Hoxd genes and Evx2, another gene located nearby. We used a targeted enhancer-trap approach to identify a DNA segment capable of directing reporter gene expression in both digits and CNS, following Lnp, Evx2, and Hoxd-specific patterns. This DNA region showed an unusual interspecies conservation, including with its pufferfish counterpart. It contains a cluster of global enhancers capable of controlling transcription of several genes unrelated in structure or function, thus defining large regulatory domains. These domains were interrupted in the Ulnaless mutation, a balanced inversion that modified the topography of the locus. We discuss the heuristic value of these results in term of locus specific versus gene-specific regulation.

Limb malformations and the human HOX genes

HOX genes encode a family of transcription factors of fundamental importance for body patterning during embryonic development. Humans, like most vertebrates, have 39 HOX genes organized into four clusters, with major roles in the development of the central nervous system, axial skeleton, gastrointestinal and urogenital tracts, external genitalia, and limbs. The first two limb malformations shown to be caused by mutations in the human HOX genes were synpolydactyly and hand-foot-genital syndrome, which result from mutations in HOXD13 and HOXA13, respectively. This review describes a variety of limb malformations now known to be caused by specific different mutations in these two genes, including polyalanine tract expansions, nonsense mutations, and missense mutations, many with phenotypic consequences that could not have been predicted from previous knowledge of mouse models or HOX protein function. Limb malformations may also result from chromosomal deletions involving the HOXD and HOXA clusters, and from regulatory mutations affecting single or multiple HOX genes.

Mutations in mouse Aristaless-like4 cause Strong's luxoid polydactyly

Mutations that affect vertebrate limb development provide insight into pattern formation, evolutionary biology and human birth defects. Patterning of the limb axes depends on several interacting signaling centers; one of these, the zone of polarizing activity (ZPA), comprises a group of mesenchymal cells along the posterior aspect of the limb bud that express sonic hedgehog (Shh) and plays a key role in patterning the anterior-posterior (AP) axis. The mechanisms by which the ZPA and Shh expression are confined to the posterior aspect of the limb bud mesenchyme are not well understood. The polydactylous mouse mutant Strong's luxoid (lst) exhibits an ectopic anterior ZPA and expression of Shh that results in the formation of extra anterior digits. Here we describe a new chlorambucil-induced deletion allele, lstAlb, that uncovers the lst locus. Integration of the lst genetic and physical maps suggested the mouse Aristaless-like4 (Alx4) gene, which encodes a paired-type homeodomain protein that plays a role in limb patterning, as a strong molecular candidate for the Strong's luxoid gene. In genetic crosses, the three lst mutant alleles fail to complement an Alx4 gene-targeted allele. Molecular and biochemical characterization of the three lst alleles reveal mutations of the Alx4 gene that result in loss of function. Alx4 haploinsufficiency and the importance of strain-specific modifiers leading to polydactyly are indicative of a critical threshold requirement for Alx4 in a genetic program operating to restrict polarizing activity and Shh expression in the anterior mesenchyme of the limb bud, and suggest that mutations in Alx4 may also underlie human polydactyly.

The mouse Ulnaless mutation deregulates posterior HoxD gene expression and alters appendicular patterning

The semi-dominant mouse mutation Ulnaless alters patterning of the appendicular but not the axial skeleton. Ulnaless forelimbs and hindlimbs have severe reductions of the proximal limb and less severe reductions of the distal limb. Genetic and physical mapping has failed to separate the Ulnaless locus from the HoxD gene cluster (Peichel, C. L., Abbott, C. M. and Vogt, T. F. (1996) Genetics 144, 1757–1767). The Ulnaless limb phenotypes are not recapitulated by targeted mutations in any single HoxD gene, suggesting that Ulnaless may be a gain-of-function mutation in a coding sequence or a regulatory mutation. Deregulation of 5′ HoxD gene expression is observed in Ulnaless limb buds. There is ectopic expression of Hoxd-13 and Hoxd-12 in the proximal limb and reduction of Hoxd-13, Hoxd-12 and Hoxd-11 expression in the distal limb. Skeletal reductions in the proximal limb may be a consequence of posterior prevalence, whereby proximal misexpression of Hoxd-13 and Hoxd-12 results in the transcriptional and/or functional inactivation of Hox group 11 genes. The Ulnaless digit phenotypes are attributed to a reduction in the distal expression of Hoxd-13, Hoxd-12, Hoxd-11 and Hoxa-13. In addition, Hoxd-13 expression is reduced in the genital bud, consistent with the observed alterations of the Ulnaless penian bone. No alterations of HoxD expression or skeletal phenotypes were observed in the Ulnaless primary axis. We propose that the Ulnaless mutation alters a cis-acting element that regulates HoxD expression specifically in the appendicular axes of the embryo.

Ulnaless (Ul), a regulatory mutation inducing both loss-of-function and gain-of-function of posterior Hoxd genes

Ulnaless (Ul), an X-ray-induced dominant mutation in mice, severely disrupts development of forearms and forelegs. The mutation maps on chromosome 2, tightly linked to the HoxD complex, a cluster of regulatory genes required for proper morphogenesis. In particular, 5′-located (posterior) Hoxd genes are involved in limb development and combined mutations within these genes result in severe alterations in appendicular skeleton. We have used several engineered alleles of the HoxD complex to genetically assess the potential linkage between these two loci. We present evidence indicating that Ulnaless is allelic to Hoxd genes. Important modifications in the expression patterns of the posterior Hoxd-12 and Hoxd-13 genes at the Ul locus suggest that Ul is a regulatory mutation that interferes with a control mechanism shared by multiple genes to coordinate Hoxd function during limb morphogenesis.