Defects in the cappuccino (cno) gene on mouse chromosome 5 and human 4p cause Hermansky-Pudlak syndrome by an AP-3-independent mechanism.

Defects in a triad of organelles (melanosomes, platelet granules, and lysosomes) result in albinism, prolonged bleeding, and lysosome abnormalities in Hermansky-Pudlak syndrome (HPS). Defects in HPS1, a protein of unknown function, and in components of the AP-3 complex cause some, but not all, cases of HPS in humans. There have been 15 inherited models of HPS described in the mouse, underscoring its marked genetic heterogeneity. Here we characterize a new spontaneous mutation in the mouse, cappuccino (cno), that maps to mouse chromosome 5 in a region conserved with human 4p15-p16. Melanosomes of cno/cno mice are immature and dramatically decreased in number in the eye and skin, resulting in severe oculocutaneous albinism. Platelet dense body contents (adenosine triphosphate, serotonin) are markedly deficient, leading to defective aggregation and prolonged bleeding. Lysosomal enzyme concentrations are significantly elevated in the kidney and liver. Genetic, immunofluorescence microscopy, and lysosomal protein trafficking studies indicate that the AP-3 complex is intact in cno/cno mice. It was concluded that the cappuccino gene encodes a product involved in an AP-3-independent mechanism critical to the biogenesis of lysosome-related organelles. (Blood. 2000;96:4227-4235)

The mouse adducin gene family: alternative splicing and chromosomal localization.

Mouse cDNA sequences encoding alpha, beta, and gamma adducins were cloned from a mouse reticulocyte cDNA library. The purified clones contain alternatively spliced exons from all three adducin genes. In the case of alpha and beta, the inclusion of the alternatively spliced exons results in truncated polypeptide isoforms (called alpha-2 and beta-2). The mouse predicted amino acid sequences are compared with published rat and human sequences. For completion of this comparison, cDNA encoding the rat beta-1 carboxy terminus was cloned by PCR. The carboxy terminal region containing MARCKS homology, calmodulin-binding region-2, and spectrin-actin-binding site, is conserved among alpha-1, beta-1, and gamma-1 isoforms in mouse, rat, and humans. We also report here the localization of the gene encoding gamma adducin (Add3) to murine Chr 19, in a region that shows conserved synteny with human Chr 10.

cDNA sequence and chromosomal localization of mouse Dlgh3 gene adjacent to the BRCA1 tumor suppressor locus.

Membrane associated guanylate kinase homologues (MAGUKs) function in tumor suppression and receptor clustering pathways presumably by modulating signaling events at the interface of the membrane cytoskeleton. The p55 subclass of MAGUKs includes two novel cDNAs that were originally identified by virtue of their genomic location to human chromosome 17q12-21 where the BRCA1 tumor suppressor gene has been mapped. The predicted primary structure of the human MPP3 contains a single copy of the PDZ domain, an SH3 motif, and a carboxy-terminal guanylate kinase-like domain. Here we report the full-length coding cDNA sequence of the mouse homologue of MPP3. The translated amino acid sequence of murine Dlgh3 contains 568 amino acids that show 87% sequence identity with the human MPP3 protein. Northern blot analysis shows abundant expression of a approximately 3.0 kb transcript of Dlgh3 in mouse brain and skeletal muscle, and a relatively less abundant approximately 5.0 kb transcript in skeletal muscle, testis, kidney, and lung. Using an interspecific backcross panel, the Dlgh3 gene was mapped to a segment of mouse chromosome 11 that is conserved with human chromosome 17q12-21. The close proximity of murine Dlgh3 gene to the BRCA1 locus and the high conservation of the primary structure of human and murine proteins provide a framework for testing the role of Dlgh3 in cell proliferation pathways using the mouse as a model system.

The gene encoding protein 4.2 is distinct from the mouse platelet storage pool deficiency mutation pallid.

Previous studies identified the gene encoding the erythrocyte membrane protein 4.2 (Epb4.2) as a candidate for the mouse mutation pallid (pa); Epb4.2 genetically colocalized near pa on mouse Chromosome 2, and a truncated Epb4.2 transcript was present in tissues derived from pallid mice. We report here evidence that Epb4.2 and pa are not allelic. The pallid cDNA and intron/exon boundaries show no significant variation from the known BALB/c and C57BL/6J Epb4.2 sequence, and normal immunoreactive 72-kDa protein 4.2 is present in pallid tissues. Two recombinations between Epb4.2 and pa were identified in 173 phenotypically mutant (C57BL/6J-pa/pa x Mus castaneus) F2 animals. Northern blotting reveals a truncated Epb4.2 transcript in kidney mRNA from normal wild Mus domesticus (WSB/Ei) mice that comigrates with the pallid Epb4.2 mRNA. As the pa mutation originally arose in a wild M. domesticus mouse, we conclude that the Epb4.2 mRNA characteristic of pallid is a normal polymorphism derived from its wild ancestor and that Epb4.2 and pa are distinct loci.

Limatin (LIMAB1), an actin-binding LIM protein, maps to mouse chromosome 19 and human chromosome 10q25, a region frequently deleted in human cancers.

LIM domains, found in over 60 proteins, play key roles in the regulation of developmental pathways. They were first identified as cysteine-rich motifs found in the three proteins Lin-11, Isl-1, and Mec-3. LIM proteins frequently contain DNA-binding homeodomains, allowing these proteins to activate transcription. LIM domains also function as protein-binding interfaces, mediating specific protein-protein interactions. Limatin is a novel LIM protein that binds to actin filaments via a domain that is homologous to erythrocyte dematin. Here we report the murine and human chromosomal localizations of limatin (LIMAB1). Limatin was mapped to mouse Chromosome 19 by restriction fragment length polymorphism analysis and to human chromosome region 10q25 by fluorescence in situ hybridization. Radiation hybrid mapping placed LIMAB1 in a 37-cR interval between markers D10S554 and D10S2390. Interestingly, 10q25 is a region of frequent loss of heterozygosity in human tumors, thus identifying limatin as a candidate tumor suppressor gene.