Genomic structure, chromosomal localization, and expression pattern of the human LIM-homeobox3 (LHX 3) gene

Lhx3 is a LIM-homeobox protein essential for pituitary development in mice. The human homologue gene spans 7.2 kb and contains 7 exons, including two alternatively spliced first exons. This structure encodes two distinct protein isoforms, LHX3a and LHX3b, that differ exclusively in their amino-terminus. The LHX3 gene was localized at 9q34.2-34.3. The predicted protein sequence is highly homologous to other known Lhx3 proteins, the highest degree of homology being in the conserved domains. The highest expression of LHX3 was found in pituitary gland, spinal cord, and lung. Among different pituitary cell types, corticotrophs appear to express preferentially LHX3b isoform, suggesting a distinct role of the b-form in the development of this cell lineage. Although the human LHX3 gene structure would provide a ground for clarification of the molecular basis of complete anterior pituitary deficiency, we were unable to identify any mutation in the LHX3 gene of 46 such patients.     

Syndromic short stature in patients with a germline mutation in the LIM homeobox LHX4

Studies of genetically engineered flies and mice have revealed the role that orthologs of the human LIM homeobox LHX4 have in the control of motor-neuron-identity assignment and in pituitary development. Remarkably, these mouse strains, which bear a targeted modification of Lhx4 in the heterozygous state, are asymptomatic, whereas homozygous animals die shortly after birth. Nevertheless, we have isolated the human LHX4 gene, as well as the corresponding cDNA sequence, to test whether it could be involved in developmental defects of the human pituitary region. LHX4, which encodes a protein 99% identical to its murine counterpart, consists of six coding exons and spans >45 kb of the q25 region of chromosome 1. We report a family with an LHX4 germline splice-site mutation that results in a disease phenotype characterized by short stature and by pituitary and hindbrain (i.e., cerebellar) defects in combination with abnormalities of the sella turcica of the central skull base. This intronic mutation, which segregates in a dominant and fully penetrant manner over three generations, abolishes normal LHX4 splicing and activates two exonic cryptic splice sites, thereby predicting two different proteins deleted in their homeodomain sequence. These findings, which elucidate the molecular basis of a complex Mendelian disorder, reveal the fundamental pleiotropic role played by a single factor that tightly coordinates brain development and skull shaping during head morphogenesis.     

Mapping of adenylyl cyclase genes type I,II, III,IV, V,and VI in mouse

The adenylyl cyclases (AC) act as second messengers in regulatory processes in the central nervous system. They might be involved in the pathophysiology of diseases, but their biological function is unknown, except for AC type I, which has been implicated in learning and memory. We previously mapped the gene encoding AC I to human Chromosome (Chr) 7p12. In this study we report the mapping of the adenylyl cyclase genes type I–VI to mouse chromosomes by fluorescence in situ hybridization (FISH): Adcy1 to Chr 11A2, Adcy2 to 13C1, Adcy3 to 12A-B, Adcy4 to 14D3, Adcy5 to 16B5, and Adcy6 to 15F. We also confirmed previously reported mapping results of the corresponding human loci ADCY2, ADCY3, ADCY5, and ADCY6 to human chromosomes and, in addition, determined the chromosomal location of ADCY4 to human Chr 14q11.2. The mapping data confirm known areas of conservation between mouse and human chromosomes.