Chromosomal Localization of the Human and Mouse Hyaluronan Synthase Genes

We have recently identified a new vertebrate gene family encoding putative hyaluronan (HA) synthases. Three highly conserved related genes have been identified, designatedHAS1, HAS2,andHAS3in humans andHas1, Has2,andHas3in the mouse. All three genes encode predicted plasma membrane proteins with multiple transmembrane domains and approximately 25% amino acid sequence identity to theStreptococcus pyogenesHA synthase, HasA. Furthermore, expression of any oneHASgene in transfected mammalian cells leads to high levels of HA biosynthesis. We now report the chromosomal localization of the threeHASgenes in human and in mouse. The genes localized to three different positions within both the human and the mouse genomes.HAS1was localized to the human chromosome 19q13.3–q13.4 boundary andHas1to mouse Chr 17.HAS2was localized to human chromosome 8q24.12 andHas2to mouse Chr 15.HAS3was localized to human chromosome 16q22.1 andHas3to mouse Chr 8. The map position forHAS1reinforces the recently reported relationship between a small region of human chromosome 19q and proximal mouse chromosome 17.HAS2mapped outside the predicted critical region delineated for the Langer–Giedion syndrome and can thus be excluded as a candidate gene for this genetic syndrome.     

Neuropeptide Y Receptor Genes on Human Chromosome 4q31–q32 Map to Conserved Linkage Groups on Mouse Chromosomes 3 and 8

Npy1randNpy2r,the genes encoding mouse type 1 and type 2 neuropeptide Y receptors, have been mapped by interspecific backcross analysis. Previous studies have localized the human genes encoding these receptors to chromosome 4q31–q32. We have now assignedNpy1randNpy2rto conserved linkage groups on mouse Chr 8 and Chr 3, respectively, which correspond to the distal region of human chromosome 4q. Using yeast artificial chromosomes, we have estimated the distance between the human genes to be approximately 6 cM. Although ancient tandem duplication events may account for some closely spaced G-protein-coupled receptor genes, the large genetic distance between the human type 1 and type 2 neuropeptide Y receptor genes raises questions about whether this mechanism accounts for their proximity.     

biparous:A Novel bHLH Gene Expressed in Neuronal and Glial Precursors inDrosophila

Genetic studies have uncovered many genes that are involved in the first steps of neuronal development inDrosophila.Less is known about the intermediate steps during which individual precursor cells follow either the neuronal pathway or the glial pathway. We report the identification of a novel bHLH gene,biparous,expressed in neuronal and glial precursors inDrosophila.Unlike most bHLH genes,biparousexpression continues to the final stages of neurogenesis in the embryo. Expression ofbiparousis not observed in end stage postmitotic neurons and precedes the expression ofrepo,a gene activated in later stages of glial differentiation. The bHLH domain is sufficiently different from previously described bHLH domains to imply a novel function.     

Mapping of FASN and ACACA on two chicken microchromosomes disrupts the human 17q syntenic group well conserved in mammals

Fatty acid synthase and Acetyl-CoA carboxylase are both key enzymes of lipogenesis and may play a crucial role in the weight variability of abdominal adipose tissue in the growing chicken. They are encoded by the FASN and ACACA genes, located on human Chromosome (Chr) 17q25 and on Chr 17q12 or 17q21 respectively, a large region of conserved synteny among mammals. We have localized the homologous chicken genes FASN and ACACA coding for these enzymes, by single-strand conformation polymorphism analysis on different linkage groups of the Compton and East Lansing consensus genetic maps and by FISH on two different chicken microchromosomes. Although synteny is not conserved between these two genes, our results revealed linkage in chicken between FASN and NDPK (nucleoside diphosphate kinase), a homolog to the human NME1 and NME2 genes (non-metastatic cell proteins 1 and 2), both located on human Chr 17q21.3, and also between FASN and H3F3B (H3 histone family 3B), located on human Chr 17q25. The analysis of mapping data from the literature for other chicken and mammalian genes indicates rearrangements have occurred in this region in the mammalian lineage since the mammalian and avian radiation. Received: 8 August 1997 / Accepted: 24 November 1997     

Localization of the IGHG,PRKACB, and TNP2 genes in pigs by in situ hybridization

The porcine genes encoding the immunoglobulin gamma heavy chain (IGHG), cAMP-dependent protein kinase catalytic beta subunit (PRKACB), and transition protein 2 (TNP2) were mapped to Chromosomes (Chrs) 7 q25–q26, 6q31–q33, and 3p13-cent, respectively, by in situ hybridization. Localization of the IGHG gene confirms the assignment of linkage group III to Chr 7. Our results show that the IGHG locus in pigs, similar to the situation in other mammalian species, viz. humans, mouse, cattle, and river buffaloes, is located on the terminal region of the chromosome. The assignment of the PRKACB gene extends the homology observed between porcine Chr 6q and human Chr 1p. Mapping of the TNP2 gene provides the first marker assigned to the p arm of Chr 3 in pigs. The present study contributes to the development of the physical gene map in pigs and also bears significance in terms of comparative gene mapping.     

Physical and Genetic Maps of thedeafwaddlerRegion on Distal Mouse Chr 6

Thedeafwaddler(dfw) mutation, displaying motor ataxia and profound deafness, arose spontaneously in a C3H/HeJ colony and was mapped previously to distal mouse Chr 6. In this study, a high-resolution genetic map was generated by positioning 10 microsatellite markers and 5 known genes on a 968-meioses intersubspecific backcross segregating fordfw[(CAST/Ei–+/+ × C3HeB/FeJ–dfw/dfw) × C3HeB/FeJ–dfw/dfw], giving the following marker order and sex-averaged distances:D6Mit64–(0.10 + 0.10 cM)–Pang–(1.24 + 0.36 cM)–Itpr1–(0.62 + 0.25 cM)–D6Mit108–(0.52 + 0.23 cM)–D6Mit54–(0.21 + 0.15 cM)–D6Mit23, D6Mit107, D6Mit328–(0.72 + 0.27 cM)–D6Mit11–(0.21 + 0.15 cM)–dfw–(0.93 + 0.31 cM)–Gat4, D6Mit55–(0.10 + 0.10 cM)–D6Mit63–(0.31 + 0.18 cM)–Syn2–(0.62 + 0.25 cM)–D6Mit44(Rho). Female and male genetic maps are similar immediately surrounding thedfwlocus, but show marked differences in other areas. A yeast artificial chromosome-based physical map suggests that the closest markers flanking thedfwlocus,D6Mit11(proximal) andGat4, D6Mit55(distal), are contained within 650–950 kb. The human homologues of the flanking lociItpr1(proximal) andSyn2(distal) map to chromosome 3p25–p26, suggesting that the human homologue of thedfwgene is located within this same region.     

Genetic and physical mapping of the natural resistance-associated macrophage protein 1 (NRAMP1) in chicken

The chicken natural resistance-associated macrophage protein 1 (NRAMP1) gene has been mapped by linkage analysis by use of a reference panel to develop the chicken molecular genetic linkage map and by fluorescence in situ hybridization. The chicken homolog of the murine Nramp1 gene was mapped to a linkage group located on Chromosome (Chr) 7q13, which includes three genes (CD28, NDUSF1, and EF1B) that have previously been mapped either to mouse Chr 1 or to human Chr 2q. Physical mapping by pulsed-field gel electrophoresis revealed that NRAMP1 is tightly linked to the villin gene and that the genomic organization (gene order and presence of CpG islands) of the chromosomal region carrying NRAMP1 is well conserved between the chicken and mammalian genomes. The regions on mouse Chr 1, human Chr 2q, and chicken Chr 7q that encompass NRAMP1 represent large conserved chromosomal segments between the mammalian and avian genomes. The chromosome mapping of the chicken NRAMP1 gene is a first step in determining its possible role in differential susceptibility to salmonellosis in this species.     

Genetic mapping of the human and mouse phospholipase C genes

To determine chromosome positions for 10 mouse phospholipase C (PLC) genes, we typed the progeny of two sets of genetic crosses for inheritance of restriction enzyme polymorphisms of each PLC. Four mouse chromosomes, Chr 1, 11, 12, and 19, contained single PLC genes. Four PLC loci, Plcb1, Plcb2, Plcb4, and Plcg1, mapped to three sites on distal mouse Chr 2. Two PLC genes, Plcd1 and Plcg2, mapped to distinct sites on Chr 8. We mapped the human homologs of eight of these genes to six chromosomes by analysis of human × rodent somatic cell hybrids. The map locations of seven of these genes were consistent with previously defined regions of conserved synteny; Plcd1 defines a new region of homology between human Chr 3 and mouse Chr 8. Received: 24 January 1996 / Accepted: 2 April 1996     

Genetic Mapping of the Mouse Genes Encoding the Voltage-Sensitive Calcium Channel Subunits

The genes encoding the α₁ and β subunits of voltage-sensitive calcium channel were mapped in the mouse by analysis of the progeny of two multilocus crosses. The α₁, β₂, and β₄ subunit genes, termed Cchna1, Cchb2, and Cchb4, are located at different sites on proximal Chr 2, while the β₃ subunit gene Cchb3 maps to Chr 15 near Wnt1. These results together with previous mapping data indicate that the calcium channel genes are dispersed in the mouse genome, unlike the sodium channel genes, which are clustered.     

Quantitative trait loci for baseline white blood cell count, platelet count, and mean platelet volume

A substantial genetic contribution to baseline peripheral blood counts has been established. We performed quantitative trait locus/loci (QTL) analyses to identify chromosome (Chr) regions harboring genes influencing the baseline white blood cell (WBC) count, platelet (Plt) count, and mean platelet volume (MPV) in F₂ intercrosses between NZW/LacJ, SM/J, and C57BLKS/J inbred mice. We identified six significant WBC QTL: Wbcq1 (peak LOD score at 38 cM, Chr 1), Wbcq2 (42 cM, Chr 3), Wbcq3 (0 cM, Chr 15), Wbcq4 (58 cM, Chr 1), Wbcq5 (82 cM, Chr 1), and Wbcq6 (8 cM, Chr 14). Three significant Plt QTL were identified: Pltq1 (24 cM, Chr 2), Pltq2 (36 cM, Chr 7), and Pltq3 (10 cM, Chr 12). Two significant MPV QTL were identified, Mpvq1 (62 cM, Chr 15) and Mpvq2 (44 cM, Chr 8). In total, the WBC QTL accounted for up to 31% of the total variance in baseline WBC count, while the Plt and MPV QTL accounted for up to 30% and 49% of the total variance, respectively. These analyses underscore the genetic complexity underlying these traits in normal populations and provide the basis for future studies to identify novel genes involved in the regulation of mammalian hematopoiesis.     

Phenotypes of lethal alleles of the recessive temperature sensitive paralytic mutantstambh A ofDrosophila melanogaster suggest its neurogenic function

The mutantstambhA ¹ (2–56.8) ofDrosophila melanogaster was identified as a reversible temperature sensitive adult and larval paralytic. We have (i) isolated and analysed phenotypes of one new homozygous viable paralytic allele and two recessive unconditional embryonic lethal alleles ofstmA and (ii) studied the interaction of the viable paralytic alleles with ts paralytic mutantsnap ^ts1 (2–55.2) andpara ^ts1 (1–53.9). The homozygous viable paralytic allelesstmA ² andstmA ¹ are semi dominant neomorphs. The lethal allelesstmA ¹² andstmA ⁷ appear to be amorphs. Unhatched embryos expressing lethalstmA alleles showed hypotrophy of the anterior dorsal cuticle overlying the brain with a concomitant hypertrophy of the anterior dorsal neurogenic region (the brain). The ventral cuticle was poorly differentiated, and the ventral nerve chord showed mild hypertrophy and poor organisation. The epidermal cells in 12–13 h old embryos did not show the normal palisade layer arrangement. These phenotypes are similar to mutant phenotypes of the neurogenic class of genes whose wild type functions are necessary for intercellular communication. The allelesstmA ¹ andstmA ² do not appear to interact with the paralytic mutantsnap ^ts1 orpara ^ts1 in double mutant combinations. On the basis of our results it is proposed thatstmA may belong to the neurogenic class of genes.     

New seizure frequency QTL and the complex genetics of epilepsy in EL mice

EL/Suz (EL) mice experience recurrent seizures that are similar to common partial complex epilepsy in humans. In the mice, seizures occur naturally at 90–100 days of age, but can be induced in younger mice and analyzed as a semi-quantitative trait after gentle rhythmic stimulation. A previous genetic mapping study of EL backcrosses to the strains ABP/LeJ or DBA/2J showed two quantitative trait loci (QTL) with large effects on seizure frequency (El1, Chr 9; El2, Chr 2) and implied the existence of other QTL with lesser effects. To further the understanding of EL-derived seizure alleles, we examined intercross progeny of EL and the strains ABP/LeJ and DDY/Jcl, and also a backcross of (EL x DDY)F₁ hybrids to DDY. A new large-effect seizure frequency QTL was found (El5, Chr 14), a more minor QTL confirmed (El3, Chr 10), and two additional QTL proposed (El4, Chr 9; El6, Chr 11). The serotonin receptor gene, Htr2a, maps near and is a candidate for El5, and linkages of other serotonin receptor genes to seizure frequency QTL are noted. In addition, a strong gender effect was revealed, and epistasis was found between Chr 9 and Chr 14 markers. Despite this progress, however, our results revealed a more complex determinism of epilepsy in EL mice than previously described. In particular, no single El locus or pair was essential for frequent seizures, as QTL with large effects, such as El5, El2, and El1, were highly dependent on genetic context. Our studies highlight the importance of gene interaction in some complex mammalian traits defined by natural variation.     

Human Mucin Genes Assigned to 11p15.5: Identification and Organization of a Cluster of Genes

Four distinct genes that encode mucins have previously been mapped to chromosome 11p15.5. Three of these genes (MUC2, MUC5AC,andMUC6) show a high level of genetically determined polymorphism and were analyzed in the CEPH families. Linkage analysis placed all three genes on the genetic map in a cluster betweenHRASandINS,and more detailed analysis of recombinant breakpoints revealed thatMUC6is telomeric toMUC2.Using these recombinantsD11S150was mapped close toMUC2.Ten of the 11 recombinant chromosomes studied in detail were paternal, and the recombinant events were distributed throughout the 11p15 region, suggesting that the high level of recombination observed in 11p15.5 is not due to a particular recombinational hot spot. Pulsed-field gel electrophoresis was used to make a detailed physical map of theMUCcluster and to integrate the physical and genetical maps. The gene order was determined to beHRAS–MUC6–MUC2–MUC5AC–MUC5B–IGF2.TheMUCgenes span a region of some 400 kb and the map extends 770 kb and contains 15 putative CpG islands. The order of theMUCgenes on the map corresponds to the relative order of their expression along the anterior–posterior axis of the body, suggesting a possible functional significance to the gene order.     

Identification and genetic mapping of the murine gene and 20 related sequences encoding chromosomal protein HMG-17

HMG-17 is an abundant, nonhistone chromosomal protein that binds preferentially to nucleosomal core particles of mammalian chromatin. The human gene for HMG-17 has been localized to Chromosome (Chr) 1p, but the murine gene has not been previously mapped. Here we identify the murine functional gene, Hmg17, from among more than 25 related sequences (probably processed pseudogenes) and show that it is located on mouse Chr 4, in a region known to have conserved linkage relationships with human Chr 1p. We also report the map locations of 20 additional Hmg17-related sequences on mouse Chrs 1, 2, 3, 5, 7, 8, 9, 13, 15, 16, 17, 18, and X. The multiple, dispersed members of the Hmg17 multigene family can be detected efficiently with a single cDNA probe and provide useful markers for genetic mapping studies in mice.     

Snail-type zinc finger proteins prevent neurogenesis in Scutoid and transgenic animals of Drosophila

Scutoid is a classical dominant gain-of-function mutation of Drosophila, causing a loss of bristles and roughening of the compound eye. Previous genetic and molecular analyses have shown that Scutoid is associated with a chromosomal transposition resulting in a fusion of no-oceli and snail genes. How this gene fusion event leads to the defects in neurogenesis was not known until now. Here have found that snail is ectopically expressed in the eye-antennal and wing imaginal discs in Scutoid larvae, and that this expression is reduced in Scutoid revertants. We have also shown that the expressivity of Scutoid is enhanced by zeste mutations. snail and escargot encode evolutionarily conserved zinc-finger proteins involved in the development of mesoderm and limbs. Snail and Escargot proteins share a common target DNA sequence with the basic helix-loop-helix (bHLH) type proneural gene products. When expressed in the developing external sense organ precursors of the thorax and the eye, these proteins cause a loss of mechanosensory bristles in the thorax and perturbed the development of the compound eye. Such phenotypes resemble those associated with Scutoid. Furthermore, the effect of ectopic Escargot on bristle development is antagonized by coexpression of the bHLH gene asense. Thus, our results suggest that the Scutoid phenotype is due to an ectopic snail expression under the control of no-oceli enhancer, antagonizing neurogenesis through its inhibitory interaction with bHLH proteins. Received: 8 February 1999 / Accepted: 24 May 1999