Mammalian Genome

Cushman, Lisa J. ; Camper, Sally A.

doi: 10.1007/s003350040002pmid: 11420609

Purcell, Maureen K. ; Mu, Jian-Long ; Higgins, David C. ; Elango, Ramu ; Whitmore, Harry ; Harris, Stephen ; Paigen, Beverly

doi: 10.1007/s00335001-0006-9pmid: 11420610

Ath6 is a novel quantitative trait locus associated with differences in susceptibility to atherosclerosis between C57BL/6J (B6) and C57BLKS/J (BKS) inbred mouse strains. Combining data from an intercross and a backcross (1593 meioses) between mice from B6 and BKS strains and from The Jackson Laboratory interspecific backcross panels, (C57BL/6J ×Mus spretus) F1× C57BL/6J and (C57BL/6J × SPRET/Ei) F1× SPRET/Ei, we constructed a consensus genetic map and narrowed Ath6 to a 1.07 ± 0.26 cM interval between the anonymous DNA marker D12Pgn4 and the gene Nmyc1. This region is near the proximal end of murine Chromosome (Chr) 12, which is homologous to the human chromosomal region 2p24-p25. Marker order in the Ath6 region was concordant among the two crosses and The Jackson Laboratory interspecific backcross panels. This high resolution map rules out candidate genes encoding apolipoprotein B, syndecan 1, and Adam17. The two Ath6 crosses have a combined potential resolution of 0.06 cM.

Cohen, Robert M. ; Kang, Albert ; Gulick, Cindy

doi: 10.1007/s00335-001-2047-5pmid: 11420611

How allelic diversity affects neural mechanisms to produce behavioral variation is largely unknown. The elevated plus maze, consisting of open and closed arms, has been used as a model of behavioral variation in rodent exploration. Under dim illumination the nature of the sensory stimuli that influence arm choice is uncertain. Two inbred mouse strains, A/J (Tyr c /Tyr c , the albino phenotype, mutation in tyrosinase) with a strong preference for closed arm entry, and CBA/J (Pdeb rdl /Pdeb rdl , the retinal degeneration phenotype, mutation in the β-subunit of rod cGMP phosphodiesterase), with a weak preference for open arm entry, were studied under varying light. Because behavioral differences persist under red light, variation in light perception is not likely to fully account for variation in arm choice. To identify genetic factors influencing arm choice (100 × Open arm entries/Total arm entries) quantitative trait loci analyses (QTL) were performed on (A/J × CBA/J)F2 mice. Two QTLs, one of which includes PDEB, were identified on Chr 5 (LOD > 10) and account for > 30% of the behavioral variation in arm preference. Tyr (Chr 7, 44 cM) was linked to closed arm entries but not arm preference, and is unlikely to be acting through a direct effect on light perception, because A/J arm entries were not affected by red light and there was no interaction with PDEB in the (A/J × CBA/J)F2 mice. Whether the candidate QTLs on Chr 5 affect arm choice through an effect on light perception is unknown, but phenotypic differences between F2 mice with retinal degeneration and CBA/J mice and F2 mice with albinism and A/J mice suggest that factors other than light sensitivity contribute to arm preference in these two strains.

Summers, Tyrone J. ; Thomas, James W. ; Lee-Lin, Shih-Queen ; Maduro, Valerie V.B. ; Idol, Jacquelyn R. ; Green, Eric D.

doi: 10.1007/s003350020021pmid: 11420612

The comparative mapping and sequencing of vertebrate genomes is now a key priority for the Human Genome Project. In addition to finishing the human genome sequence and generating a `working draft' of the mouse genome sequence, significant attention is rapidly turning to the analysis of other model organisms, such as the laboratory rat (Rattus norvegicus). As a complement to genome-wide mapping and sequencing efforts, it is often important to generate detailed maps and sequence data for specific regions of interest. Using an adaptation of our previously described approach for constructing mouse comparative and physical maps, we have established a general strategy for targeted mapping of the rat genome. Specifically, we constructed a framework comparative map of human Chromosome (Chr) 7 and the orthologous regions of the rat genome, as well as two large (>1-Mb) P1-derived artificial chromosome (PAC)-based physical maps. Generation of these physical maps involved the use of mouse-derived probes that cross-hybridized with rat PAC clones. The first PAC map encompasses the cystic fibrosis transmembrane conductance regulator gene (Cftr), while the second map allows a three-species comparison of a genomic region containing intra- and inter-chromosomal evolutionary rearrangements. The studies reported here further demonstrate that cross-species hybridization between related animals, such as rat and mouse, can be readily used for the targeted construction of clone-based physical maps, thereby accelerating the analysis of biologically interesting regions of vertebrate genomes.

Killian, J. Keith ; Buckley, Thomas R. ; Stewart, Niall ; Munday, Barry L. ; Jirtle, Randy L.

doi: 10.1007/s003350020026pmid: 11420613

The three living monophyletic divisions of Class Mammalia are the Prototheria (monotremes), Metatheria (marsupials), and Eutheria (`placental' mammals). Determining the sister relationships among these three groups is the most fundamental question in mammalian evolution. Phylogenetic comparison of these mammals by either anatomy or mitochondrial DNA has resulted in two conflicting hypotheses, Theria and Marsupionta, and has fueled a ``genes versus morphology'' controversy. We have cloned and analyzed a large nuclear gene, the mannose 6-phosphate/insulin-like growth factor II receptor (M6P/IGF2R), from representatives of all three mammalian groups, including platypus, echidna, opossum, wallaby, hedgehog, mouse, rat, rabbit, cow, pig, bat, tree shrew, colugo, ringtail lemur, and human. Statistical analysis of this nuclear gene unambiguously supports the morphology-based Theria hypothesis that excludes monotremes from a clade of marsupials and eutherians. The M6P/IGF2R was also able to resolve the finer structure of the eutherian mammalian family tree. In particular, our analyses support sister group relationships between lagomorphs and rodents, and between the primates and Dermoptera. Statistical support for the grouping of the hedgehog with Feruungulata and Chiroptera was also strong.

Karnuah, Arthur Bob ; Uenishi, Hirohide ; Kiuchi, Sachiko ; Kojima, Misaki ; Onishi, Akira ; Yasue, Hiroshi ; Mitsuhashi, Tadayoshi

doi: 10.1007/s003350020035pmid: 11420614

A swine resource family was constructed at the National Institute of Animal Industry, Japan, in order to determine the genetic regions responsible for economically important traits, including fetus development. To identify genes expressed in the early stage of embryo development, we cataloged and mapped genes expressed in a 28-day-old normal pig embryo. In this effort, we have mapped 64 genes, which have map information in human genome onto a swine radiation hybrid (RH) map, IMpRH. These mappings provided additional chromosomal homologies between swine and human to improve the comparative map between the two species. The distribution of the genes assigned to swine chromosomes are as follows: 9 genes were assigned on SSC6; 6 genes each assigned on SSC5 and SSC14; 5 genes each assigned on SSC3, SSC4, and SSC8; 4 genes each assigned on SSC1, SSC7, SSC9, and SSC15; 3 genes each assigned on SSC2, SSC13 and SSCX; and 1 gene each assigned on SSC10, SSC11, and SSC16. Moreover, the present findings revealed 18 new chromosomal homologies between pig and human. Briefly, SSC3 regions were indicated to correspond with HSA1 and HSA10; SSC4 with HSA6; SSC5 with HSA2, HSA15, and HSA16; SSC6 with HSA3, HSA6, and HSA20; SSC7 with HSA11; SSC8 with HSA3, HSA6, and HSA7; SSC9 with HSA8; SSC13 with HSA1; SSC14 with HSA13; SSC15 with HSA19; SSC16 with HSA9.

Sarker, Nitish ; Hawken, Rachel J. ; Takahashi, Seiya ; Alexander, Leeson J. ; Awata, Takashi ; Schook, Lawrence B. ; Yasue, Hiroshi

doi: 10.1007/s003350020034pmid: 11420615

Several quantitative trait loci (QTLs) (vertebrate number, birth weight, age at puberty, growth rate, gestation length, and backfat depth) have been independently mapped to the distal region of swine Chromosome (SSC) 1q in several resource populations. In order to improve the map resolution and refine these QTLs more precisely on SSC1q, we have isolated and mapped additional microsatellites (ms), using chromosome microdissection and radiation hybrid (RH) mapping. Five copies of the telomeric region of SSC1q were microdissected from metaphase spreads and pooled. The chromosomal fragment DNA was randomly amplified by using degenerate oligonucleotide primed polymerase chain reaction (DOP-PCR), enriched for ms, and subcloned into a PCR vector. Screening of subsequent clones with ms probes identified 23 unique ms sequences. Fifteen of these (65%) were subjected to radiation hybrid (RH) mapping by using the INRA-University of Minnesota porcine RH panel (IMpRH); and the remaining eight were not suited for the RH mapping. Twelve microsatellites were assigned to SSC1q telomeric region of IMpRH map (LOD >6), and three remain unlinked (LOD <6). Out of the 15 microsatellite markers, 9 were polymorphic in NIAI reference population based on the Meishan and Göttingen miniature pig. In summary, we have used microdissection and radiation hybrid mapping to clone and map 12 new microsatellites to the swine gene map to increase the resolution of SSC1q in the region of known QTLs.

Dorroch, Ute ; Goldammer, Tom ; Brunner, Ronald M. ; Kata, Srivanas R. ; Kühn, Christa ; Womack, James E. ; Schwerin, Manfred

doi: 10.1007/s003350020031pmid: 11420616

mRNA differential display was applied to identify hepatic and intestinal expressed sequence tags (ESTs) in lactating cows of different metabolic types (milk type, meat/milk type, meat type) that are potentially associated with energy turnover and involved in the regulation of these processes. Altogether, 277 ESTs (liver: 161, intestine: 116) were identified. For 150 transcripts (liver: 99, intestine: 51), the sequences showed similarity to previously described genes and ESTs. Many of these homologous sequences are reported to be involved in hepatic metabolism. Ninety-four ESTs (liver: 43, intestine: 51) did not match with any database entries. Semi-quantitative RT-PCR revealed quantitative differences in transcript represented by randomly chosen ESTs in liver samples of animals of the Holstein and Charolais breeds. One hundred twenty-two ESTs were mapped physically by using a bovine-hamster somatic cell hybrid panel (SCP) and a 5000-rad bovine whole genome radiation hybrid panel (WGRH). These ESTs were assigned to the bovine syntenic groups and positioned in the recently established RH-based ordered comparative map of the cattle and human genomes. The mapped, differentially expressed sequence tags are a useful prerequisite for cloning of genetic variation underlying economic traits.

Lingenfelter, Patricia A. ; Delbridge, Margaret L. ; Thomas, Sushma ; Hoekstra, Hopi E. ; Mitchell, Michael J. ; Marshall Graves, Jennifer A. ; Disteche, Christine M.

doi: 10.1007/s00335001-0003-zpmid: 11420617

RBMX and RBMY are members of an ancient pair of genes located on the sex chromosomes that encode RNA-binding proteins involved in splicing. These genes have differentiated and evolved separately on the X and Y Chromosomes. RBMY has acquired a testis-specific function, whereas, as shown here, RBMX is ubiquitously expressed and is subject to X inactivation. We have also found that multiple processed copies of RBMX are present in the human genome. RBMX-like sequences (RBMXLs) located on human Chrs 1, 4, 6, 9 (9p13 and 9p24), 11, 20, and X lack introns and thus probably result from retroposition events. We found RBMXLs to be conserved in primates and great apes at corresponding chromosomal locations, indicating that they arose prior to the divergence of human. Some of the RBMXLs show insertions, deletions, and stop codons, which would probably result in nonfunctional proteins. The RBMXL on Chr 20 is deleted in some individuals. Two of the largely intact RBMXLs, located on Chrs 1 and 9p13, are expressed in different tissues and may encode novel proteins involved in splicing in a tissue-specific manner. The RBMXL located at 9p13 is specifically expressed in testis, and to a lesser extent in brain, and may therefore play a role in testis function. This autosomal, testis-specific copy of RBMX could potentially compensate for RBMX that is presumably inactivated in male germ cells, in a manner analogous to autosomal retroposed copies of other X-linked genes.

Bergeson, Susan E. ; Helms, Melinda L. ; O'Toole, Laurie A. ; Jarvis, Mark W. ; Hain, Heather S. ; Mogil, Jeffrey S. ; Belknap, John K.

doi: 10.1007/s003350020022pmid: 11420618

Analgesia (pain reduction, or antinociception) is a classical and clinically important effect of morphine administration, and in rodent models sensitivity to morphine has been shown to be strongly influenced by genotype. For example, several studies have reported marked differences in morphine antinociception between the insensitive C57BL/6 (B6) and sensitive DBA/2 (D2) inbred mouse strains on the hot-plate assay. This prompted the present genome-wide search for quantitative trait loci (QTLs) that are chromosomal sites influencing the magnitude of antinociception, by using four mapping populations derived from the B6 and D2 progenitor inbred strains. These four were the BXD recombinant inbred (RI) strain set, an F2 (B6D2F2) population, short-term selective breeding for antinociception from a B6D2F2 founding population, and incipient or completed congenic strains. In the BXD RI set and in the B6D2F2, a genome-wide search identified 10–12 provisional QTLs at a nominal p < .05. The other populations were subsequently used as confirmation steps to test each of the provisional QTL regions. Based on all available mapping populations, four QTLs emerged as significant (p < .00005) on proximal Chromosome (Chr) 1 (females only), proximal Chr 9 (females only), mid Chr 9, and proximal Chr 10. The Chr 10 QTL comaps to the same region as the μ-opioid receptor gene (Oprm); this receptor is a known mediator of morphine's antinociceptive effects. The Chr 1 QTL was evident only in females and comapped with the κ-opioid receptor gene, Oprk.