Nidogen/entactin (Nid) maps to the proximal end of mouse chromosome 13 linked to beige (bg) and identifies a new region of homology between mouse and human chromosomes

Gene structure and functional analysis of the mouse nidogen-2 gene: nidogen-2 is not essential for basement membrane formation in mice

Nidogens are highly conserved proteins in vertebrates and invertebrates and are found in almost all basement membranes. According to the classical hypothesis of basement membrane organization, nidogens connect the laminin and collagen IV networks, so stabilizing the basement membrane, and integrate other proteins. In mammals two nidogen proteins, nidogen-1 and nidogen-2, have been discovered. Nidogen-2 is typically enriched in endothelial basement membranes, whereas nidogen-1 shows broader localization in most basement membranes. Surprisingly, analysis of nidogen-1 gene knockout mice presented evidence that nidogen-1 is not essential for basement membrane formation and may be compensated for by nidogen-2. In order to assess the structure and in vivo function of the nidogen-2 gene in mice, we cloned the gene and determined its structure and chromosomal location. Next we analyzed mice carrying an insertional mutation in the nidogen-2 gene that was generated by the secretory gene trap approach. Our molecular and biochemical characterization identified the mutation as a phenotypic null allele. Nidogen-2-deficient mice show no overt abnormalities and are fertile, and basement membranes appear normal by ultrastructural analysis and immunostaining. Nidogen-2 deficiency does not lead to hemorrhages in mice as one may have expected. Our results show that nidogen-2 is not essential for basement membrane formation or maintenance.

Mapping of five subtype genes for muscarinic acetylcholine receptor to mouse chromosomes

Muscarinic acetylcholine receptors in mammals consist of five subtypes (M1-M5) encoded by distinct genes. They are widely expressed throughout the body and play a variety of roles in the peripheral and central nervous systems. Although their pharmacological properties have been studied extensively in vitro, colocalization of the multiple subtypes in each tissue and lack of subtype-specific ligands have hampered characterization of the respective subtypes in vivo. We have mapped mouse genomic loci for all five genes (Chrm1-5) by restriction fragment length variant (RFLV) analyses in interspecific backcross mice. Chrm1, Chrm2, and Chrm3 were mapped to chromosome (Chr) 19, 6, and 13, respectively. Both Chrm4 and Chrm5 were mapped to Chr 2. Although a comparison of their map positions with other mutations in their vicinities suggested a possibility that the El2 (epilepsy 2) allele might be a mutation in Chrm5, sequencing analyses of the Chrm5 gene in the El2 mutant mice did not support such a hypothesis.

Genetic defects in Chediak-Higashi syndrome and the beige mouse

Chediak-Higashi syndrome (CHS) is a rare, autosomal recessive, multisystem disorder in which severe immune deficits are accompanied by abnormalities of pigmentation, blood clotting, and neurologic function. There is no specific treatment, and without bone marrow transplantation, most patients succumb to frequent bacterial infections or to a lymphoproliferative syndrome that appears to result principally from lack of natural killer cell function. Disorders similar to human CHS occur in many mammalian species, the most important being the beige mouse, long considered a likely homologue of human CHS. This supposition has recently been confirmed by the mapping, cloning, and mutation analysis of the homologous human CHS1 and mouse beige genes. Identification of the human CHS1 gene, and the availability of a ready mouse model for human CHS, will likely facilitate investigation of the disease pathophysiology and the development of novel and specific treatments for the disorder.

Complementation of the beige mutation in cultured cells by episomally replicating murine yeast artificial chromosomes

Chédiak-Higashi syndrome in man and the beige mutation of mice are phenotypically similar disorders that have profound effects upon lysosome and melanosome morphology and function. We isolated two murine yeast artificial chromosomes (YACs) that, when introduced into beige mouse fibroblasts, complement the beige mutation. The complementing YACs exist as extrachromosomal elements that are amplified in high concentrations of G418. When YAC-complemented beige cells were fused to human Chédiak-Higashi syndrome or Aleutian mink fibroblasts, complementation of the mutant phenotype also occurred. These results localize the beige gene to a 500-kb interval and demonstrate that the same or homologous genes are defective in mice, minks, and humans.

Exon organization of the mouse entactin gene corresponds to the structural domains of the polypeptide and has regional homology to the low-density lipoprotein receptor gene

Entactin is a widespread basement membrane protein of 150 kDa that binds to type IV collagen and laminin. The complete exon-intron structure of the mouse entactin gene has been determined from lambda genomic DNA clones. The gene spans at least 65 kb and contains 20 exons. The exon organization of the mouse entactin gene closely corresponds to the organization of the polypeptide into distinct structural and functional domains. The two amino-terminal globular domains are encoded by three exons each. Single exons encode the two protease-sensitive, O-glycosylated linking regions. The six EGF-like repeats and the single thyroglobulin-type repeat are each encoded by separate exons. The carboxyl-terminal half of entactin displays sequence homology to the growth factor-like region of the low-density lipoprotein receptor, and in both genes this region is encoded by eight exons. The positions of four introns are also conserved in the homologous region of the two genes. These observations suggest that the entactin gene has evolved via exon shuffling. Finally, several sequence polymorphisms useful for gene linkage analysis were found in the 3' noncoding region of the last exon.

Localization of new genes and markers to the distal part of the human major histocompatibility complex (MHC) region and comparison with the mouse: new insights into the evolution of mammalian genomes

We have refined and extended the map of the distal half of the human major histocompatibility complex. The map is continuous from HLA-E to 1000 kb telomeric of HLA-F and includes six new markers and genes. In addition, the corresponding sequences that were not previously mapped in the mouse genome have been located. The human and the mouse organizations have therefore been compared. This comparison allows us to demonstrate that the structure of the distal part of the MHC is similar in the two species. In addition, this comparison shows the presence of a breakpoint of synteny telomeric of the distal part of the H-2 region. Indeed, the region telomeric of HLA in human is found on a chromosome different from that carrying H-2 in mouse. The mapping analysis of paralogous genes (structurally related genes) around the breakpoint shows that the human organization probably represents the putative human/mouse ancestral one. This evolutionary breakpoint was precisely mapped in human, and the surrounding region was cloned into yeast artificial chromosomes. Finally, we show that the region found around the breakpoint was involved several times in chromosome recombinations in the mouse lineage, as it seems to correspond also to the t-complex distal inversion point.

Complementation analysis of Chediak-Higashi syndrome: the same gene may be responsible for the defect in all patients and species

Chediak-Higashi Syndrome is an autosomal recessive disorder, characterized by the presence of large intracellular granules, particularly lysosomes and melanosomes. While the Chediak-Higashi Syndrome is a rare disorder in humans, phenotypically similar syndromes are found in other species. Fusion of normal fibroblasts to Chediak fibroblasts complements the Chediak disorder, restoring normal lysosome size and distribution. Fusion of wild-type with Chediak fibroblasts from human, mouse, or mink demonstrates that wild-type fibroblasts can complement any of the Chediak fibroblasts. Complementation was not observed in interspecific hybrids between Chediak fibroblasts from these species, suggesting that the same gene product is defective in humans, mice, and mink.

Linkage of Agt and Actsk-1 to distal mouse chromosome 8 loci: a new conserved linkage

Angiotensinogen is an alpha 2-globulin involved in the maintenance of blood pressure and electrolyte balance. We have refined the position of the mouse angiotensinogen locus (Agt) on Chromosome (Chr) 8 and have also confirmed the assignment of the human angiotensinogen locus (AGT) to Chr 1. The segregation of several restriction fragment length variants (RFLVs) was followed in two interspecific backcross sets and in four recombinant inbred (RI) mouse sets. Analysis of the segregation patterns closely linked Agt to Aprt and Emv-2, which places the angiotensinogen locus on the distal end of mouse Chr 8. Additionally, a literature search has revealed that the strain distribution pattern (SDP) for the mouse skeletal alpha-actin locus 1 (Actsk-1, previously Acta1, Acta, or Acts) is nearly identical to the SDP for Agt in two RI sets. On the basis of this information we were able to reassign Actsk-1 to mouse Chr 8. By screening a panel of human-mouse somatic cell hybrids, we confirmed that the human angiotensinogen locus lies on Chr 1. This information describes a new region of conserved linkage homology between mouse Chr 8 and human Chr 1. It also defines the end of a large region of conserved linkage homology between mouse Chr 8 and human Chr 16.

Mouse models of human single gene disorders. I: Nontransgenic mice

Mouse models of human genetic disorders provide a valuable resource for investigating the pathogenesis of genetic disease and for testing potential therapies. The high degree of resolution of linkage mapping in the mouse allows mutant phenotypes to be mapped precisely which, combined with the accurate definition of areas of homology between the mouse and human genomes, greatly facilitates the identification of mouse models. We describe here mouse models of human single gene disorders dividing them into three categories depending on the information available; phenotypic similarities, comparative mapping and identification of the underlying genetic lesion.