Chromosomal mapping of lysosomal enzyme structural genes in the domestic cat

A panel of 42 rodent x cat somatic cell hybrids has been used to assign seven structural genes for lysosomal enzymes to specific chromosomes in the domestic cat. The assignments include alpha-glucosidase (GANAB) to chromosome D1, alpha-galactosidase (GLA) to the X chromosome, beta-galactosidase 1 (GLB1) to chromosome B3, beta-glucuronidase (GUSB) to chromosome E3, alpha-mannosidase A (MANA) to chromosome B3, alpha-L-fucosidase (FUCA) to chromosome C1, and hexosaminidase A (HEXA) to chromosome B3. In all cases, the feline lysosomal enzyme genes were located in linkage groups which were syntenic with their homologous positions in the human gene map. These assignments expand the genetic map of the cat and reaffirm the extensive syntenic homology between the chromosome maps of man and cat.     

Molecular cloning, chromosomal assignment, and nucleotide sequence of the feline homeobox HOX3A.

The feline homolog to the mammalian homeobox locus, HOX3A, was isolated by screening a domestic cat genomic library with the murine Hox-3.1 probe. The nucleotide sequence similarity of the feline homeobox was 96% to human HOX3A, 94% to mouse Hox-3.1, and 94% to rat R4. The deduced amino acid sequence (homeodomain) of this feline homeobox was identical to all homeodomains of these cognate genes. Using a panel of feline x rodent somatic cell hybrids, the HOX3A locus was assigned to feline chromosome B4. Human HOX3A and mouse Hox-3.1 have been mapped previously to human chromosome 12 and mouse chromosome 15, respectively, both of which share syntenic homology to feline chromosome B4. These data demonstrate evolutionary conservation of both HOX3A gene sequences and chromosomal location during mammalian evolution.     

Sequences homologous to glutamic acid decarboxylase cDNA are present on mouse chromosomes 2 and 10

The chromosomal locations of mouse DNA sequences homologous to a feline cDNA clone encoding glutamic acid decarboxylase (GAD) were determined. Although cats and humans are thought to have only one gene for GAD, GAD cDNA sequences hybridize to two distinct chromosomal loci in the mouse, chromosomes 2 and 10. The chromosomal assignment of sequences homologous to GAD cDNA was determined by Southern hybridization analysis using DNA from mouse-hamster hybrid cells. Mouse genomic sequences homologous to GAD cDNA were isolated and used to determine that GAD is encoded by a locus on mouse chromosome 2 (Gad-1) and that an apparent pseudogene locus is on chromosome 10 (Gad-1ps). An interspecific backcross and recombinant inbred strain sets were used to map these two loci relative to other loci on their respective chromosomes. The Gad-1 locus is part of a conserved homology between mouse chromosome 2 and the long arm of human chromosome 2.     

Development of a feline whole genome radiation hybrid panel and comparative mapping of human chromosome 12 and 22 loci

A 5000-rad whole genome radiation hybrid panel is described for the domestic cat, derived from irradiated male feline fibroblasts fused to a recipient hamster cell line. A panel of 93 cell lines has an estimated retention frequency of 0.39 (range 0.13-0.71) based upon PCR typing of 54 feline markers. To test the panel's utility, we determined the order of 16 Type I (coding gene) loci, 14 Type II (microsatellite) loci, and 1 endogenous retroviral element on feline chromosomes B4 and D3. Assessment of marker order derived from the RH panel was compared to assignments of the same loci using interspecies backcross mapping data, human homologue positions, and human-cat chromosome painting homologies. Assessment of concordant and discordant marker order for these loci provides improved resolution into the evolution of subchromosomal genome organizations and the methods to track them in these species.     

Comparative genomic structure of human, dog, and cat MHC: HLA, DLA, and FLA

Comparisons of the genomic structure of 3 mammalian major histocompatibility complexes (MHCs), human HLA, canine DLA, and feline FLA revealed remarkable structural differences between HLA and the other 2 MHCs. The 4.6-Mb HLA sequence was compared with the 3.9-Mb DLA sequence from 2 supercontigs generated by 7x whole-genome shotgun assembly and 3.3-Mb FLA draft sequence. For FLA, we confirm that 1) feline FLA was split into 2 pieces within the TRIM (member of the tripartite motif) gene family found in human HLA, 2) class II, III, and I regions were placed in the pericentromeric region of the long arm of chromosome B2, and 3) the remaining FLA was located in subtelomeric region of the short arm of chromosome B2. The exact same chromosome break was found in canine DLA structure, where class II, III, and I regions were placed in a pericentromeric region of chromosome 12 whereas the remaining region was located in a subtelomeric region of chromosome 35, suggesting that this chromosome break occurred once before the split of felid and canid more than 55 million years ago. However, significant differences were found in the content of genes in both pericentromeric and subtelomeric regions in DLA and FLA, the gene number, and amplicon structure of class I genes plus 2 other class I genes found on 2 additional chromosomes; canine chromosomes 7 and 18 suggest the dynamic nature in the evolution of MHC class I genes.     

Genomic homology of the domestic ferret with cats and humans

We used chromosome paints from both the domestic cat and humans to directly establish chromosomal homology between the genome of these species and the domestic ferret. The chromosome painting data indicate that the ferret has a highly conserved karyotype closer to the ancestral carnivore karyotype than that of the cat. The cat chromosome paints revealed 22 homologous autosomal regions in the ferret genome: 16 ferret chromosomes were hybridized by a single cat paint, while 3 ferret chromosomes were hybridized by two cat paints. In situ hybridization combined with banding showed that ferret Chromosome (Chr) 1 = cat A2p/C2, Chr 2 = F2/C1q, and Chr 3 = A2q/D2. Five ferret chromosomes are homologous to single arms of cat chromosomes: ferret 4 = A1q, 5 = B1q, 6 = C1p, 10 = A1p, and 12 = B1p. The human chromosome paints revealed 32 + XY homologous regions in the ferret genome: 9 ferret chromosomes were each hybridized by a single human paint, 7 by two paints, 3 by three paints. The 10 ferret chromosomes hybridized by multiple human paints produced the following associations: ferret 1 = human 19/3/21, 2 = 8q/2q, 3 = 10/7, 5 = 8/4, 8 = 15/14, 9 = 10/12/22, 11 = 20/2, 12 = 8/4, 14 = 12/22/18, 18 = 19/16. We present an index of genomic diversity, Z, based on the relative number of conserved whole chromosome and chromosome segments as a preliminary statistic for rapid comparison between species. The index of diversity between human-ferret (Z = 0.812) is slightly less than human-cat (Z = 0.843). The homology data presented here allow us to transfer gene mapping data from both cats and humans to the ferret. Received: 21 December 1999 / Accepted: 30 May 2000     

Genetic mapping of endogenous RD-114 retroviral sequences of domestic cats.

The RD-114 family of endogenous retroviral sequences in domestic cats has been shown to consist of approximately 20 copies of genetically divergent virogenes per haploid genome. The chromosomal localization for four endogenous sequences (RDV1-4) was accomplished by correlating the occurrence of specific feline chromosomes with diagnostic viral DNA fragments in a panel of cat X rodent somatic cell hybrids. Analysis of the hybrid panel revealed that endogenous RD-114 sequences are dispersed on multiple cat chromosomes, that certain proviral segments are polymorphic with respect to the presence or absence of virus, and that a restriction fragment characteristic of inducible RD-114 resides on a single feline chromosome (B3), probably at a single locus.     

Parallels of genomic organization and of endogenous retrovirus organization in cat and man

A combination of technical advances (most notably heterologous cell fusion, high resolution G-banding, and molecular cloning) has contributed to an accelerated advance in genetic analysis in mammals. The present human genetic map contains over 400 gene assignments and the map is growing rapidly as each new molecular clone or immunological reagent is developed. In our laboratory, we have developed a panel of rodent X human somatic cell hybrids that have been utilized in chromosome assignment of several classes of genes including oncogenes (ras, raf) and endogenous human retroviral sequences (ERVL, 2, etc). Using similar techniques, a biochemical genetic map of the domestic cat has been derived. The cat has 19 chromosome pairs and, to date, 40 genes have been mapped to 16 linkage or syntenic groups. Comparison of linkage relationships between homologous enzymes has revealed a striking conversation of chromosomal linkage association between cat and man. A comparison of syntenically homologous, highly extended high resoultion G-banded chromosomes between the two mammalian families revealed that 20–25%, by length, of the human karyotype can be precisely aligned (chromomere to chromomere) between cats and man despite the evolutionary divergence of the species nearly 80 million years ago. Moderately repetitive families of retrovirus-related DNAs exist within the feline and the human genomes. We have isolated molecular clones of several members of the feline RD-114 retrovirus family from a genomic library of normal cat cellular DNA. The endogenous sequences analyzed were similar to each other in that they were colinear with RD-114 proviral DNA, were bounded by long terminal redundancies, and conserved many restriction sites in the gag and pol regions. Several sequences were apparently deleted, relative to the previously characterized inducible RD-114 genome. The env regions of a number of endogenous RD-114 sequences examined were substantially deleted or diverged; a subset of these sequences contained information at the position of the env region that was not homologous to inducible RD-114. The RD-114 virogenes were dispersed to several cat chrosomes that were localized using a panel of rodent x cat somatic cell hybrids. A comparison of the genetic properties of endogenous human retroviral sequences revealed several similarities between the human and feline status of endogenous retroviruses.     

Molecular characterization and genetic mapping of class I and class II MHC genes of the domestic cat

The major histocompatibility complex (MHC) of the domestic cat has been poorly characterized to date, primarily because of numerous difficulties in the preparation of allotypic sera. We present here a comparative analysis of class I and class II genes in domestic cat populations using molecular probes of the MHC from man and mouse. The cat possesses a minimum of 20 class I loci and 5 class II genes per haploid genome. Class I genes of the domestic cat expressed limited restriction fragment length polymorphism. The average percent difference of the size of DNA fragments between individual cats was 9.0 %, a value five times lower than the value for mice, but comparable to the human DNA polymorphism level. Class I and class II genes were both genetically mapped to feline chromosome B2 using a panel of rodent x cat somatic cell hybrids. Since feline chromosome B2 is syntenically homologous to human chromosome 6 and mouse chromosome 17, these results affirm the linkage conservation of the MHC-containing linkage group in the three mammalian orders.     

Zoo-FISH analysis of dog chromosome 5: identification of conserved synteny with human and cat chromosomes

Conserved segments of synteny between the human genome and chromosome 5 (CFA 5) of the domestic dog (Canis familiaris) have been identified by reciprocal chromosome painting analysis. A CFA 5 paint probe was applied to human metaphase spreads, revealing distinct hybridisation sites on human (HSA) chromosomes 1, 11, 16, and 17. Paint probes for these human chromosomes were then hybridised to dog metaphase spreads, identifying the regions of CFA 5 with which homology is shared with the corresponding human chromosome. Application of the CFA 5 paint probe to metaphase spreads of the domestic cat (Felis catus, FCA) demonstrated hybridisation to cat chromosomes C1, D1, E1, and E2. Dog PCR primers for type 1 markers known to lie in the corresponding regions of HSA 11, 16, and 17 were used to isolate dog BAC clones representing four genes. Fluorescence in situ hybridisation analysis confirmed their localisation to CFA 5 and suggested that two of the conserved segments lie in opposing orientations on CFA 5, compared to the human chromosome concerned. A third segment appears to lie in the same orientation on both human and dog chromosomes. No suitable gene markers were available for analysis of the fourth segment. The significance of these findings is discussed with reference to current and future dog genome mapping efforts.     

A high-resolution cat radiation hybrid and integrated FISH mapping resource for phylogenomic studies across Felidae

We describe the construction of a high-resolution radiation hybrid (RH) map of the domestic cat genome, which includes 2662 markers, translating to an estimated average intermarker distance of 939 kilobases (kb). Targeted marker selection utilized the recent feline 1.9x genome assembly, concentrating on regions of low marker density on feline autosomes and the X chromosome, in addition to regions flanking interspecies chromosomal breakpoints. Average gap (breakpoint) size between cat-human ordered conserved segments is less than 900 kb. The map was used for a fine-scale comparison of conserved syntenic blocks with the human and canine genomes. Corroborative fluorescence in situ hybridization (FISH) data were generated using 129 domestic cat BAC clones as probes, providing independent confirmation of the long-range correctness of the map. Cross-species hybridization of BAC probes on divergent felids from the genera Profelis (serval) and Panthera (snow leopard) provides further evidence for karyotypic conservation within felids, and demonstrates the utility of such probes for future studies of chromosome evolution within the cat family and in related carnivores. The integrated map constitutes a comprehensive framework for identifying genes controlling feline phenotypes of interest, and to aid in assembly of a higher coverage feline genome sequence.     

A genetic linkage map of microsatellites in the domestic cat (Felis catus)

Of the nonprimate mammalian species with developing comparative gene maps, the feline gene map (Felis catus, Order Carnivora, 2N = 38) displays the highest level of syntenic conservation with humans, with as few as 10 translocation exchanges discriminating the human and feline genome organization. To extend this model, a genetic linkage map of microsatellite loci in the feline genome has been constructed including 246 autosomal and 7 X-linked loci. Two hundred thirty-five dinucleotide (dC. dA)n. (dG. dT)n and 18 tetranucleotide repeat loci were identified and genotyped in a two-family, 108-member multigeneration interspecies backcross pedigree between the domestic cat (F. catus) and the Asian leopard cat (Prionailurus bengalensis). Two hundred twenty-nine loci were linked to at least one other marker with a lod score >/=3.0, identifying 34 linkage groups. Representative markers from each linkage group were assigned to specific cat chromosomes by somatic cell hybrid analysis, resulting in chromosomal assignments to 16 of the 19 feline chromosomes. Genome coverage spans approximately 2900 cM, and we estimate a genetic length for the sex-averaged map as 3300 cM. The map has an average intragroup intermarker spacing of 11 cM and provides a valuable resource for mapping phenotypic variation in the species and relating it to gene maps of other mammals, including human.     

Chromosomal and regional localization of the genes for UMPH2, APRT, PEPD, PEPS, PSP, and PGP in mink: comparison with man and mouse

Segregation of mink biochemical markers uridine 5'-monophosphate phosphohydrolase-2 (UMPH2), adenine phosphoribosyltransferase (APRT), phosphoserine phosphatase (PSP), phosphoglycolate phosphatase (PGP), peptidases D (PEPD) and S (PEPS), as well as mink chromosomes, was investigated in a set of mink x mouse hybrid clones. The results obtained allowed us to make the following mink gene assignments: UMPH2, chromosome 8; PEPD and APRT, chromosome 7; PEPS, chromosome 6; and PSP and PGP, chromosome 14. The latter two genes are the first known markers for mink chromosome 14. For regional mapping, UMPH2 was analyzed in mouse cell clones transformed by means of mink metaphase chromosomes (Gradov et al., 1985) and also in mink x mouse hybrid clones carrying fragments of mink chromosome 8 of different sizes. Based on the data obtained, the gene for UMPH2 was assigned to the region 8pter----p26 of mink chromosome 8. The present data is compared with that previously established for man and mouse with reference to the conservation of syntenic gene groups and G-band homoeologies of chromosomes in mammals.     

Comparative feline genomics: a BAC/PAC contig map of the major histocompatibility complex class II region

The genome organization of the human major histocompatibility complex (MHC) will be best understood in a comparative evolutionary context. We describe here the construction of a physical map for the feline MHC. A large-insert domestic cat genomic DNA library was developed using a P1 artificial chromosome (PAC) with a genomic representation of 2.5x and an average insert size of 80 kb. A sequence-ready 660-kb bacterial artificial chromosome/PAC contig map of the domestic cat MHC class II region was constructed with a gene order similar to, but distinct from, that of human and mice: DPB/DPA, Ring3, DMB, TAP1, DOB, DRB2, DRA3, DRB1, DRA2, and DRA1. Fluorescence in situ hybridization analyses of selected class II PAC clones confirmed that the class II region lies in the pericentromeric region of cat chromosome B2. However, apparently unlike the human and mouse MHCs, the domestic cat DRA and DRB genes have undergone multiple duplications and the DQ region has been deleted.     

Targeting a newly established spontaneous feline fibrosarcoma cell line by gene transfer

Fibrosarcoma is a deadly disease in cats and is significantly more often located at classical vaccine injections sites. More rare forms of spontaneous non-vaccination site (NSV) fibrosarcomas have been described and have been found associated to genetic alterations. Purpose of this study was to compare the efficacy of adenoviral gene transfer in NVS fibrosarcoma. We isolated and characterized a NVS fibrosarcoma cell line (Cocca-6A) from a spontaneous fibrosarcoma that occurred in a domestic calico cat. The feline cells were karyotyped and their chromosome number was counted using a Giemsa staining. Adenoviral gene transfer was verified by western blot analysis. Flow cytometry assay and Annexin-V were used to study cell-cycle changes and cell death of transduced cells. Cocca-6A fibrosarcoma cells were morphologically and cytogenetically characterized. Giemsa block staining of metaphase spreads of the Cocca-6A cells showed deletion of one of the E1 chromosomes, where feline p53 maps. Semi-quantitative PCR demonstrated reduction of p53 genomic DNA in the Cocca-6A cells. Adenoviral gene transfer determined a remarkable effect on the viability and growth of the Cocca-6A cells following single transduction with adenoviruses carrying Mda-7/IL-24 or IFN-γ or various combination of RB/p105, Ras-DN, IFN-γ, and Mda-7 gene transfer. Therapy for feline fibrosarcomas is often insufficient for long lasting tumor eradication. More gene transfer studies should be conducted in order to understand if these viral vectors could be applicable regardless the origin (spontaneous vs. vaccine induced) of feline fibrosarcomas.     

Gene mapping in Mus musculus by interspecific cell hybridization: assignment of the genes for tripeptidase-1 to chromosome 10, dipeptidase-2 to chromosome 18, acid phosphatase-1 to chromosome 12, and adenylate kinase-1 to chromosome 2.

Chinese hamster X mouse somatic cell hybrids segregating mouse chromosomes were examined for their mouse chromosome content using trypsin-Giemsa (GTG) banding and Hoechst 33258 staining techniques. Simultaneously, they were scored for the presence of 24 mouse enzymes. The results confirm the assignments of 11 genes previously mapped by sexual genetics: Dip-1 and Id-1 to chromosome 1; Pgm-2 and Pgd to 4; Pgm-1 to 5; Gpi-1 to 7; Gr-1 to 8; Mpi-1 and Mod-1 to 9; Np-1 and Es-10 to 14. They also confirm chromosomally the assignments of 3 genes that were made by other somatic cell genetic studies: Aprt to 8; Hprt and alpha-gal to the X chromosome. But most importantly, four enzyme loci are assigned to four chromosomes that until now were not known to carry a biochemical marker which is expressed in cultured cells: Trip-1 to 10; Dip-2 to 18; Acp-1 to 12; and Ak-1 to 2. Cytogenetic examination of clones showing discordant segregation of HPRT and A-GAL, suggested the assignment of alpha-gal to region XE leads to XF of the mouse X chromosome. The cytologic studies provide a comparison between data from sexual genetics and somatic cell hybrids and validate hybrid cell techniques. They provide evidence of the reliability of scoring chromosomes by GTG and Hoechst staining and stress the importance of identifying clones with multiple chromosome rearrangements. Striking examples of norandom segregation of mouse chromosomes were observed in these hybrids with preferential retention of 15 and segregation of 11 and the Y chromosome.     

Amplification of the major satellite DNA family (FA-SAT) in a cat fibrosarcoma might be related to chromosomal instability

Most mammalian chromosomes have satellite DNA sequences located at or near the centromeres, organized in arrays of variable size and higher order structure. The implications of these specific repetitive DNA sequences and their organization for centromere function are still quite cloudy. In contrast to most mammalian species, the domestic cat seems to have the major satellite DNA family (FA-SAT) localized primarily at the telomeres and secondarily at the centromeres of the chromosomes. In the present work, we analyzed chromosome preparations from a fibrosarcoma, in comparison with nontumor cells (epithelial tissue) from the same individual, by in situ hybridization of the FA-SAT cat satellite DNA family. This repetitive sequence was found to be amplified in the cat tumor chromosomes analyzed. The amplification of these satellite DNA sequences in the cat chromosomes with variable number and appearance (marker chromosomes) is discussed and might be related to mitotic instability, which could explain the exhibition of complex patterns of chromosome aberrations detected in the fibrosarcoma analyzed.     

Chromosomal localization of the genes encoding ALDH, BMP-2, R-FABP, IFN-gamma, RXR-gamma, and VIM in chicken by fluorescence in situ hybridization

Six structural genes encoding ALDH, BMP-2, R-FABP, IFN-gamma, RXR-gamma and VIM were mapped in the chicken by fluorescence in situ hybridization (FISH) using genomic and cDNA clones as probes. The genes were found to be located on four different macrochromosomes: chromosome 1 (IFNG and FABP), chromosome 2 (VIM and ALDH), chromosome 3 (BMP2) and a smaller macrochromosome, most probably chromosome 7 (RXRG). With the exception of IFNG none of the newly mapped sites corresponds to known orthologous regions between chicken and human chromosomes.