Assignment of the growth hormone gene locus to 19q26-qter in cattle and to 11q25-qter in sheep by in situ hybridization

The growth hormone gene locus (GH) of cattle and sheep was mapped to a chromosomal region in each species by using in situ hybridization. The probe employed was an 830-bp cDNA sequence from the ovine growth hormone gene. Based on QFQ chromosome preparations, our results show that the GH locus is on cattle chromosome 19 in the region of bands q26-qter and in sheep on chromosome region 11q25-qter. The GH assignments together with previous localizations of type I cytokeratin genes (KRTA) and one homeobox (HOX2) gene in cattle and one type I cytokeratin gene (KRTA) in sheep identify a strongly conserved chromosomal segment on human chromosome 17, bovine chromosome 19, and sheep chromosome 11.     

Chromosome banding and gene localizations support extensive conservation of chromosome structure between cattle and sheep.

By using three gene probes, one derived from the porcine major histocompatibility complex (MHC) and two from bovine cytokeratin genes, type I (KRTA) and type II (KRTB), the hypothesis of conservation of genome structure in two members of the family Bovidae was examined. Gene mapping data revealed the MHC to be in chromosome region 23q15----q23 in cattle (BOLA) and 20q15----q23 in sheep (OLA). KRTA was localized to chromosome region 19q25----q29 in cattle and 11q25----q29 in sheep and KRTB to 5q14----q22 in cattle and 3q14----q22 in sheep. The banding patterns of the chromosome arms to which the loci were assigned were identical in both species. Moreover, the resemblances of GTG- or QFQ-banding patterns between the cattle and sheep karyotypes illustrated further chromosome homologies. These studies, based on gene mapping comparisons and comparative cytogenetics, document that within bovid chromosomes, homology of banding patterns corresponds to a homologous genetic structure. Hence, we propose that gene assignments on identified chromosomal segments in one species of the Bovidae can be extrapolated, in general, to other bovid species based on the banding homologies presented here.     

Twelve loci from HSA10, HSA11 and HSA20 were comparatively FISH-mapped on river buffalo and sheep chromosomes

Ten type I loci from HSA10 (IL2RA and VIM), HSA11 (HBB and FSHB) and HSA20 (THBD, AVP/OXT, GNAS1, HCK and TOP1) and two domestic cattle type II loci (CSSM30 and BL42) were FISH mapped to R-banded river buffalo (BBU) and sheep (OAR) chromosomes. IL2RA (HSA10) maps on BBU14q13 and OAR13q13, VIM (HSA10) maps on BBU14q15 and OAR13q15, HBB (HSA11) maps on BBU16q25 and OAR15q23, FSHB (HSA11) maps on BBU16q28 and OAR15q26, THBD (HSA20) maps on BBU14q15 and OAR13q15 while AVP/OXT, GNAS1, HCK, and TOP1 (HSA20) as well as CSSM30 and BL42 map on the same large band of BBU14q22 and OAR13q22. All loci were mapped on the same homologous chromosomes and chromosome bands of the two species, and these results agree with those earlier reported in cattle homologous chromosomes 15 and 13, respectively, confirming the high degree of both banding and physical map similarities among the bovid species. Indirect comparisons between physical maps achieved on bovid chromosomes and those reported on HSA10, HSA11 and HSA20 were performed.     

Homology between a 173-kb Region from Mouse Chromosome 10, Telomeric to the Ifng Locus, and Human Chromosome 12q15

We sequenced a 173-kb region of mouse chromosome 10, telomeric to the Ifng locus, and compared it with the human homologous sequence located on chromosome 12q15 using various sequence analysis programs. This region has a low density of genes: one gene was detected in the mouse and the human sequences and a second gene was detected only in the human sequence. The mouse gene and its human orthologue, which are expressed in the immune system at a low level, produce a noncoding mRNA. Nonexpressed sequences show a higher degree of conservation than exons in this genomic region. At least three of these conserved sequences are also conserved in a third mammalian species (sheep or cow).     

The gene for the cell adhesion molecule M-cadherin maps to mouse chromosome 8 and human chromosome 16q24.1-qter and is near the E-cadherin (uvomorulin) locus in both species.

A mouse myotube-derived cDNA encoding the Ca(2+)-dependent cell adhesion molecule M-cadherin was used to study the segregation of the corresponding gene Cdh3 in a mouse interspecific backcross. Cdh3 was found to be unlinked to the N-cadherin gene but linked to the E-cadherin (uvomorulin) locus on chromosome 8 in a region of conserved synteny with human chromosome 16q. The gene order cen-Junb-Um-Tat-(Cdh3/Aprt) was determined. The human homologue CDH3 was mapped to chromosome 16q24.1-qter by analyzing human/mouse somatic cell hybrids.     

Assignment of the pig apolipoprotein B locus (APOB) to chromosome region 3q24-qter

The locus for apolipoprotein-B (APOB) has been chromosomally assigned in swine by in situ hybridization of a genomic probe to metaphase chromosomes. As expected based on the observation of extensive linkage conservation and based on the previous assignment of the malate dehydrogenase locus (MDH1) in swine, APOB maps to chromosome 3, specifically to region 3q24-qter. Variations at APOB may represent both in humans and in swine risk factors for hypercholesterolaemia and atherosclerosis. Evidence presented here that the human and porcine APOB occupy evolutionarily conserved chromosome regions provides a basis for using the pig as an animal model to study the APOB associated atherosclerosis risk.     

Physical mapping confirms that sheep chromosome 10 has extensive conserved synteny with cattle chromosome 12 and human chromosome 13

The following loci, on human chromosome 13, have been newly assigned to sheep chromosome 10 using chromosomally characterized sheep-hamster cell hybrids: gap junction protein, beta 2, 26 kDa (connexin 26) (GJB2); gap junction protein, alpha 3, 46 kDa (connexin 46) (GJA3), and esterase D/formylglutathione hydrolase (ESD). This assignment of ESD is consistent with comparative mapping evidence, but not with an earlier report of it on sheep chromosome 3p26-p24. Cell hybrid analysis confirmed the location of another human chromosome 13 locus, retinoblastoma 1 (including osteosar-coma) (RBI), and the anonymous ovine genomic sequence RP11 on sheep chromosome 10. Isotopic in situ hybridization was used to regionally localize RP11 on to sheep 10q15-q22. The location of microsatellites AGLA226, OarDB3, OarHH41, OarVH58, and TGLA441, previously assigned to sheep chromosome 10 by linkage analysis, was confirmed by polymerase chain reaction using the cell hybrid panel. These mapping data provide further evidence that sheep chromosome 10 is the equivalent of cattle chromosome 12, and that these chromosomes show extensive conserved synteny with human chromosome 13.     

FISH-mapping of LEP and SLC26A2 genes in sheep, goat and cattle R-banded chromosomes: comparison between bovine, ovine and caprine chromosome 4 (BTA4/OAR4/CHI4) and human chromosome 7 (HSA7)

Sheep (OAR), goat (CHI) and cattle (BTA) R-banded chromosome preparations, obtained from synchronized cell cultures, were used to FISH-map leptin (LEP) and solute carrier family 26 member 2 (SLC26A2) genes on single chromosome bands. LEP maps on OAR4q32 and CHI4q32, being the first assignment of this gene to these two species. SLC26A2 maps on BTA7q24, OAR5q24 and CHI7q24. This gene, too, was assigned for the fist time to both sheep and goat chromosomes, while it was more precisely localized on a single chromosome band in cattle. Improved cytogenetic maps of BTA4/OAR4/CHI4 were constructed and compared with HSA7 revealing five main conserved segments and complex chromosome rearrangements, including a centromere repositioning, differentiating HSA7 and BTA4/OAR4/CHI4.     

Conserved autosomal syntenic group on mouse (MMU) chromosome 15 and human (HSA) chromosome 22: assignment of a gene for arylsulfatase A to MMU 15 and regional mapping of DIA1, ARSA, and ACO2 on HSA 22

We have utilized a panel of Chinese hamster x mouse somatic cell hybrids segregating mouse chromosomes to assign a gene for arylsulfatase A (ARSA) to mouse chromosome 15. Considering our previous assignment of a gene for diaphorase-1 (DIA1) to the same mouse chromosome, we have evidence for another syntenic relationship that has been conserved, since the homologous loci for human ARSA and DIA1 are both located on human chromosome 22. Because MMU 15 and HSA 22 are quite dissimilar in size and banding patterns, we have attempted to identify the conserved portion by regional mapping of human DIA1 and ARSA using somatic cell hybrids segregating a human chromosome translocation t(15;22)(q14;q13.31). The results assign human DIA1 and ARSA to the distal sub-band of 22q13 (region 22q13.31 leads to qter). The locus for mitochondrial aconitase (ACO2) has been separated by the breakpoint from DIA1 and ARSA and is located more proximally.     

Sheep linkage mapping: RFLP markers for comparative mapping studies

Restriction fragment length polymorphisms (RFLPs) detected using cDNA probes for conserved genes provide an important set of markers that anchor or link syntenic groups in a range of divergent mammalian species. DNA probes from sheep, cattle, pig, human and mouse were screened against sheep DNA samples and 24 new RFLP markers for sheep were identified. Among the loci tested, 22 had a homologue that has been mapped in humans. An RFLP for fibronectin (FN1) was linked to α-inhibin (INHA) at a distance of 5cM. The FN1 locus has been assigned to sheep chromosome 2q41–q44 and linkage between FN1 and INHA assigns INHA to the same chromosome in sheep. In addition to the new loci reported here, 28 RFLPs have been published previously by this group and these are collated together with RFLPs published from other laboratories. RFLPs have been reported for 86 loci in sheep. Fifty-four loci have been mapped to 16 different chromosomes.     

Comparative mapping of sheep inhibin subunit βb to chromosome 2 in sheep and cattle by fluorescence in situ hybridization

A cosmid clone containing the complete sheep inhibin subunit β_B gene (INHBB) was assigned to sheep and cattle homologous chromosome bands 2q31-q33 by fluorescence in situ hybridization. The assignment of INHBB in sheep excludes another candidate gene as the site of the Fec^B mutation.     

Evidence for locus heterogeneity in human autosomal dominant split hand/split foot malformation.

Split hand/split foot (SHSF; also known as ectrodactyly) is a human developmental disorder characterized by missing central digits and other distal limb malformations. An association between SHSF and cytogenetically visible rearrangements of chromosome 7 at bands q21-q22 provides compelling evidence for the location of a causative gene at this location, and the locus has been designated SHFD1. In the present study, marker loci were localized to the SHFD1 critical region through the analysis of somatic cell hybrids derived from individuals with SHSF and cytogenetic abnormalities involving the 7q21-q22 region. Combined genetic and physical data suggest that the order of markers in the SHFD1 critical region is cen-D7S492-D7S527-(D7S479-D7S491)-SHFD1-++ +D7S554-D7S518-qter. Dinucleotide repeat polymorphisms at three of these loci were used to test for linkage of SHSF to this region in a large pedigree that demonstrates autosomal dominant SHSF. Evidence against linkage of the SHSF gene to 7q21-q22 was obtained in this pedigree. Therefore, combined molecular and genetic data provide evidence for locus heterogeneity in autosomal dominant SHSF. We propose the name SHSF2 for this second locus.     

Mapping of MYF5, GlR, MYHL, TPIl, IAPP, A2MR and RNR onto sheep chromosome 3q

Five new loci, myogenic factor 5 (MYF5), complement 1 receptor (CIR), myosin-like heavy chain (MYHL), islet amyloid polypeptide (IAPP), and alpha-2-macroglobulin receptor (A2MR), were mapped onto sheep chromosome 3q by Southern hybridization to a panel of chro-mosomally characterized sheep × hamster cell hybrid lines. The location of the triose phosphate isomerase (TPI1) gene and one of the nucleolar organizer regions (RNR) on sheep 3q was confirmed by Southern analysis. This study provides further evidence for the existence of a large conserved chromosomal segment comprising much of sheep chromosome 3q, cattle chromosome 5, and human chromosome 12. The distal evolutionary breakpoint on human chromosome 12, producing the chromosomal segment U23 in cattle marked by aldehyde dehydrogenase (ALDH2), also produces a separate segment in sheep. Neither ALDH2 nor pancreatic lipase (PLA2), which is also distally located on human chromosome 12, were mapped onto sheep chromosome 3q.     

Regional Assignment of Conserved Reference Loci Anchors Unassigned Linkage and Syntenic Groups to Ovine Chromosomes

Seven loci that have been previously mapped to human and mouse chromosomes have now been regionally assigned to six sheep chromosomes. Nerve growth factor β (NGFB), antigen CD3 ζ polypeptide (CD3Z), inhibin β A (INHBA), estrogen receptor (ESR), rhodopsin (RHO), insulin-like growth factor 2 (IGF2), and myelin basic protein (MBP) were mapped by in situ hybridization to sheep chromosomes 1p24-p21, 1p14-p11, 4q26-q31, 8q25-q27, 19q23-qter, 21q21-qter, and 23q11-q12.3, respectively. ESR, RHO, IGF2, and MBP are the first markers to be assigned to their respective sheep chromosomes. These new data allow the previously unassigned sheep linkage groups H, J, K, and S to be provisionally assigned to chromosomes 21, 19, 4, and 8, respectively. The unassigned sheep syntenic groups U8 and U13 are provisionally assigned to sheep chromosomes 8 and 21, respectively. The new assignments support the emerging picture that there is extensive conservation of human chromosomal segments in the sheep and cattle genomes. The position of another evolutionary breakpoint on human chromosome 1q is suggested.     

Assignment of the gene coding for the alpha 2-macroglobulin receptor to mouse chromosome 15 and to human chromosome 12q13-q14 by isotopic and nonisotopic in situ hybridization.

The assignment of the gene encoding the alpha 2-macroglobulin receptor (A2MR), which was first described as the low-density lipoprotein receptor-related protein, was confirmed by nonisotopic and isotopic in situ hybridizations on normal human metaphases to the region 12q13-q14. The same human cDNA, which has 95% sequence identity with the mouse A2mr, was hybridized to metaphases containing the Robertsonian translocation Rb(6;15)1Ald. The mouse A2mr gene was assigned to chromosome 15 in the region B2-D1. This locus and other loci on mouse chromosome 15 have been shown to be homologous with loci on human chromosome 12q.     

Highly prolific Booroola sheep have a mutation in the intracellular kinase domain of bone morphogenetic protein IB receptor (ALK-6) that is expressed in both oocytes and granulosa cells

The Booroola fecundity gene (FecB) increases ovulation rate and litter size in sheep and is inherited as a single autosomal locus. The effect of FecB is additive for ovulation rate (increasing by about 1.6 corpora lutea per cycle for each copy) and has been mapped to sheep chromosome 6q23-31, which is syntenic to human chromosome 4q21-25. Bone morphogenetic protein IB (BMP-IB) receptor (also known as ALK-6), which binds members of the transforming growth factor-beta (TGF-beta) superfamily, is located in the region containing the FecB locus. Booroola sheep have a mutation (Q249R) in the highly conserved intracellular kinase signaling domain of the BMP-IB receptor. The mutation segregated with the FecB phenotype in the Booroola backcross and half-sib flocks of sheep with no recombinants. The mutation was not found in individuals from a number of sheep breeds not derived from the Booroola strain. BMPR-IB was expressed in the ovary and in situ hybridization revealed its specific location to the oocyte and the granulosa cell. Expression of mRNA encoding the BMP type II receptor was widespread throughout the ovary. The mutation in BMPR-IB found in Booroola sheep is the second reported defect in a gene from the TGF-beta pathway affecting fertility in sheep following the recent discovery of mutations in the growth factor, GDF9b/BMP15.     

The L-isoaspartyl/D-aspartyl protein methyltransferase gene (PCMT1) maps to human chromosome 6q22.3-6q24 and the syntenic region of mouse chromosome 10.

We have mapped the genes for the human and mouse L-isoaspartyl/D-aspartyl protein carboxyl methyltransferase (EC 2.1.1.77) using cDNA probes. We determined that the human gene is present in chromosome 6 by Southern blot analysis of DNA from a panel of mouse-human somatic cell hybrids. In situ hybridization studies allowed us to confirm this identification and further localize the human gene (PCMT1) to the 6q22.3-6q24 region. By analyzing the presence of an EcoRI polymorphism in DNA from backcrosses of C57BL/6J and Mus spretus strains of mice, we localized the mouse gene (Pcmt-1) to chromosome 10, at a position 8.2 +/- 3.5 cM proximal to the Myb locus. This region of the mouse chromosome is homologous to the human 6q24 region.     

Regional assignments of NP and MPI on chromosome 7 in pig, Sus scrofa

Summary. Fibroblasts from a pig with a spontaneous reciprocal translocation involving chromosome 7, were used to prepare a set of pig-mouse somatic cell hybrids. The isozyme analysis strongly indicated that in pigs, the NP (nucleoside phosphorylase) gene is located on the distal part of the long arm of chromosome 7, (q21-qter), while the MPI (mannose phosphate isomerase) gene is in the region q21-pter. This confirmed previously reported chromosomal assignment of these genes in pigs and that this synteny has been evolutionarily conserved in several different animal species.     

Localization of the tumour protein, TP53, on porcine chromosome 12q12-q14

A human cDNA probe of the tumour protein p53 (TP53) was used to localize the homologous porcine gene by in situ hybridization. The gene was mapped to chromosome 12q12-q14. Together with already known mapping data, these results confirm the localization of an evolutionary conserved linkage group on porcine chromosome 12 which is localized in man on chromosome 17, in cattle on chromosome 19, and in mice on chromosome 11.