Use of PCR markers for mapping swine chromosome 12

Using PCR analysis of pig-mink and pig-Chinese hamster hybrid cell lines and heterologous and homologous primers of various types, chromosomal and subchromosomal mapping of genes TOP2A, THRA, BRCA1, GAS, HLR1, MYL4, LIS1, MCP1, ENO3, CRYB1, P4HB, STAT5B, and H3F3B to pig chromosome 12 was carried out. The efficiency of using different types of heterologous primers for pig chromosome mapping was compared.     

Linkage of Genes Controlling Morphological Traits with Isozyme Markers of Rye Chromosomes

Data on linkage of 12 rye genes controlling morphological traits (el, Vs, ln, w, np, ct2, Hs, Ddw, cb, mn, vi1, mp) with one or several isozyme markers of individual rye chromosomes (2R–7R) are presented. Linkage of the following gene pairs was established: chromosome 2R: Est3/5–el, el–-Glu, Sod2–el, Sod2–Vs; chromosome 3R: ln–Got4; chromosome 4R: w–Got1, np–Got1; chromosome 5R: Est4–ct2, Est6/9–ct2, ct2–Est2, ct2–Aco2, Est2–Hs, Aco2–Hs, Est2–Ddw, Aco2–Ddw; chromosome 6R:Lap2–cb, cb–Aco1, Est10–mn; chromosome 7R: Acph2/3–vi1, Got2–vi1, mp–Acph2/3. The reasons for mapping a very small number of genes in rye in spite of high intraspecific variability of this species are discussed. An approach is suggested to improve this situation by simultaneous identification and mapping of all diverse spontaneous mutations maintained in heterozygous state in various rye cultivars.     

Assignment of the βB1 Crystallin Gene (CRYBB1) to Human Chromosome 22 and Mouse Chromosome 5

By using primers complementary to the rat βB1 crystallin gene sequence, we amplified exons 5 and 6 of the orthologous human gene (CRYBB1). The amplified human segments displayed greater than 88% sequence homology to the corresponding rat and bovine sequences.CRYBB1was assigned to the group 5 region in 22q11.2–q12.1 by hybridizing the exon 6 PCR product to somatic cell hybrids containing defined portions of human chromosome 22. The exon 5 and exon 6 PCR products ofCRYBB1were used to localize, by interspecific backcross mapping, the mouse gene (Crybb1) to the central portion of chromosome 5. Three other β crystallin genes (βB2(−1), βB3, and βA4) have previously been mapped to the same regions in human and mouse. We demonstrate that the βB1 and βA4 crystallin genes are very closely linked in the two species. These assignments complete the mapping and identification of the human and mouse homologues of the major β crystallins genes that are expressed in the bovine lens.     

The Structure of a Conserved Region of Porcine Genome,Represented in Human Genome by Chromosome 17

Radiation mapping of nine genes (H3F3B, HLR1, MYL4,STAT5B, THRA1, TOP2A, MCP1, NF1, and MPO) to porcine chromosome 12 was carried out. Also, subchromosomal location of the NF1 gene along with the two loci containing the DNA sequences homologous to the DNA of the two human BAC clones was determined. The NF1 position was ascertained via microdissection of chromosome 12 with subsequent PCR amplification of the gene fragment with specific primers. BAC clones were mapped using FISH. Comparative analysis of the gene order in porcine chromosome 12 and in the homologous human chromosome 17 was performed. It was demonstrated that the gene orders in these chromosomes differed relative to the position of the MPO gene.     

High-Resolution Genetic Map of the Human Glutamyl Aminopeptidase Gene (ENPEP)

The murine B-lymphocyte differentiation antigen BP-1/6C3 has been identified as glutamyl aminopeptidase (EAP), the gene symbol for which isENPEP.Using genomic DNA encoding for human EAP as a probe, we identified theENPEPgene location on human chromosome 4q25 by polymerase chain reaction analysis of a human/rodent somatic cell hybrid mapping panel and by fluorescencein situhybridization. Using a radiation hybrid panel, the gene order aroundENPEPwas determined to be centromere–D4S1236–(570 kb)–ENPEP–(210 kb)–D4S262–(270 kb)–D4S953–(270 kb)–D4S474–(570 kb)–IF. The linkage ofENPEPto complement factor I (IF) confirms the human chromosome band 4q25 localization predicted from the chromosomal location of murineENPEP.HumanENPEPthus provides an additional marker for the long arm of chromosome 4 that should facilitate studies of this genomic region.     

From Identification of Genomic Polymorphisms to Diagnostic and Prognostic Markers of Human Epithelial Tumors

The review considers the results obtained by several groups in the fields of identification of polymorphic loci in the human genome, localization and analysis of genes associated with epithelial tumors of various origins, and generation of molecular markers of socially important oncological diseases. In the first two cases, work was initiated and supported by the Russian program Human Genome. To find new polymorphic loci in the human genome, di-, tri-, and tetranucleotide repeats were searched for in an ordered cosmid library of chromosome 13, NotI and cosmid clones of chromosome 3, and in brain EST. In total, nine polymorphisms and almost 200 STS were identified. Markers of NotI clones of chromosome 3 were associated with particular genes. Polymorphic loci NL1-024, NL2-007, and EST04896 were employed in analysis of deletions from chromosome 3p in tumor DNA. Deletion mapping of 3p in epithelial tumors of five types revealed six critical regions containing potential tumor suppressor genes. Of these, two were in the distal region of chromosome 3p and four, in region 3p21.3. A significant correlation was observed for the frequency of allelic deletions and the stage and the grade of tumors (P < 0.05). On the strength of these findings, genes of region 3p were associated with both tumor development and progression, and proposed as prognostic markers. Regions LUCA and AP20 (3p21.3) showed a high (90%) frequency of aberrations, including homozygous deletions in almost 20% cases. The peak of allelic deletions from region D3S2409–D3S3667 (600 kb) was statistically valid (P = 10^–3). Regions AP20 and D3S2409–D3S3667 (3p21.3) were for the first time associated with tumorigenesis. Clusters of tumor suppressor genes were identified in regions LUCA, AP20, and D3S2409–D3S3667. Methylation of RASSF1A and RAR-beta2 (3p) was associated with early carcinogenesis, and that of SEMA3B, with tumor progression. These findings are useful for early diagnostics and post-surgery prognosis of tumors.     

Comparative Genome Mapping of the Ataxia–Telangiectasia Region in Mouse, Rat, and Syrian Hamster

Chromosomal locations of theAtm(ataxia–telangiectasia (AT)-mutated) andAcat1(mitochondrial acetoacetyl-CoA thiolase) genes in mouse, rat, and Syrian hamster were determined by direct R-banding FISH. Both genes were colocalized to the C-D band of mouse chromosome 9, the proximal end of q24.1 of rat chromosome 8, and qa4–qa5 of Syrian hamster chromosome 12. The regions in the mouse and rat were homologous to human chromosome 11q. Fine genetic linkage mapping of the mouse AT region was performed using the interspecific backcross mice.Atm, Acat1,andNpat,which is a new gene isolated from the AT region, and 12 flanking microsatellite DNA markers were examined. No recombinations were found among theAtm, Npat, Acat1,andD9Mit6loci, and these loci were mapped 2.0 cM distal toD9Mit99and 1.3 cM proximal toD9Mit102.Comparison of the linkage map of mouse chromosome 9 (MMU9) and that of human chromosome 11 (HSA11) indicates that there is a chromosomal rearrangement due to an inversion betweenEts1andAtm–Npat–Acat1and that the inversion of MMU9 originated from the chromosomal breakage at the boundary betweenGria4andAtm–Npat–Acat1on HSA11. This type of inversion appeared to be conserved in the three rodent species, mouse, rat, and Syrian hamster, using additional comparative mapping data with theRckgene.     

<Emphasis Type="Italic">Not</Emphasis>I Sequence-Tagged Sites as Markers of Genes on Human Chromosome 3

Using nucleotide sequences from jumping and linking NotI libraries of human chromosome 3, 94 NotI-STS markers for 72 individual NotI clones were developed. The positions of the NotI-STS markers and their order on the chromosome were determined by a combination of RH-mapping (our data), contig mapping, cytogenetic mapping, and in silico mapping. Comparison of NotI-STS DNAs with human genome sequences revealed two gaps in the regions 3p21.33 (marker NL1-256) and 3p21.31 (NL3-005), and a segmental duplication. Identical DNA fragments were found in the regions 12q and 3p22–21.33 (marker NL3-007). In the 3q28–q29 region (marker NLM-084), a fragment was detected whose identical copies were also present on chromosomes 1, 2, 15, and 19. For 69 NotI-STSs, significant homologies to nucleotide sequences of 70 genes and 2 cDNAs were detected (with homologies in NotI-STS 5′- and 3′-terminal sequences being taken into account). An association between NotI-STSs and genes is confirmed by a strong correlation between the density distributions of genes and NotI-STS markers on the map of human chromosome 3. Our results indicate that the NotI map may be regarded as a gene map of human chromosome 3. Thus, NotI-STSs are applicable as gene markers.__________Translated from Molekulyarnaya Biologiya, Vol. 39, No. 4, 2005, pp. 687–701.Original Russian Text Copyright © 2005 by Sulimova, Rakhmanaliev, Klimov, Kompaniytsev, Udina, Zabarovsky, Kisselev.     

Assignment of the Gene for Porcine Insulin-Like Growth Factor Binding Protein 1 to Chromosome 18 and Detection of Polymorphisms in Intron 2 by PCR–RFLP

We have obtained a partial cDNA and three BAC clones for the porcine insulin-like growth factor binding protein 1 gene (IGFBP-1). Results of fluorescence in situ and radiation hybrid (RH) mapping assigned this gene to porcine chromosome (SSC) 18q24-qter. We found two types of polymerase chain reaction–restriction-fragment-length polymorphisms (PCR–RFLP) in intron 2 by using FokI and AluI.     

Linkage and physical mapping of prolactin to porcine chromosome 7

Comparative mapping studies between human and pig have shown that there is conserved synteny between human chromosome 6 and pig chromosomes 1 and 7, but some gene locations are not well established. Prolactin ( PRL ), an anterior pituitary hormone, has been mapped to human chromosome 6, and has tentatively mapped to pig chromosome 7 using Southern-RFLP analysis with a limited number of meioses. To confirm the assignment of prolactin to porcine chromosome 7 by physical and linkage analysis, pig cDNA and human genomic DNA sequences were used to design pig-specific PCR primers. The primers amplified a fragment of ≈2·8 kb. Two polymorphic restriction sites were identified within this fragment with the restriction endonuclease Bst UI. Prolactin was significantly linked to six markers on the published PiGMaP map of pig chromosome 7. Prolactin was physically mapped using a pig × rodent somatic cell hybrid panel. An analysis of these data placed PRL on pig 7p1·1–p1·2 with 100% concordance and was in complete agreement with the linkage data. Both mapping techniques placed PRL in a conserved order with the loci in the syntenic region of human chromosome 6.     

Genetic Analysis of the Epidermal Differentiation Complex (EDC) on Human Chromosome 1q21: Chromosomal Orientation, New Markers, and a 6-Mb YAC Contig

The epidermal differentiation complex (EDC) unites a remarkable number of structurally, functionally, and evolutionarily related genes that play an important role in terminal differentiation of the human epidermis. It is localized within 2.05 Mb of region q21 on human chromosome 1. We have identified and characterized 24 yeast artificial chromosome (YAC) clones by mapping individual EDC genes, sequence-tagged site (STS) markers (D1S305, D1S442, D1S498, D1S1664), and 10 new region-specific probes (D1S3619–D1S3628). Here we present a contig that covers about 6 Mb of 1q21 including the entire EDC. Fluorescencein situhybridization on metaphase chromosomes with two YACs flanking the EDC determined its chromosomal orientation and established, in conjunction with physical mapping results, the following order of genes and STSs: 1cen–D1S442–D1S498–S100A10–THH–FLG–D1S1664–IVL–SPRR3–SPRR1–SPRR2–LOR–S100A9–S100A8–S100A7–S100A6–S100A5–S100A4–S100A3–S100A2–S100A1–D1S305–1qtel. These integrated physical, cytogenetic, and genetic mapping data will be useful for linkage analyses of diseases associated with region 1q21 and for the identification of novel genes and regulatory elements in the EDC.     

Identification of the Human βA2 Crystallin Gene (CRYBA2): Localization of the Gene on Human Chromosome 2 and of the Homologous Gene on Mouse Chromosome 1

By using primers synthesized on the basis of the bovine βA2 crystallin gene sequence, we amplified exons 5 and 6 of the human gene (CRYBA2). CRYBA2 was assigned to human chromosome 2 by concordance analysis in human × rodent somatic cell hybrids using the amplified PCR products as probe. Regional localization to 2q34-q36 was established by hybridizing the CRYBA2 probe to microcell and radiation hybrids containing defined fragments of chromosome 2 as the only human contribution. The CRYBA2 probe was also used to localize, by interspecific backcross mapping, the mouse gene (Cryba2) to the central portion of chromosome 1 in a region of known human chromosome 2 homology. Finally, we demonstrate that in both species the βA2 crystallin gene is linked but separable from the γA crystallin gene. The βA2 crystallin gene is a candidate gene for human and mouse hereditary cataract.     

Assignment of 19 porcine type I loci by somatic cell hybrid analysis detects new regions of conserved synteny between human and pig

Nineteen so-called type I-loci, including ACO2, ADRA2, CAST, CCK, CHAT, IGKC, IGLV, IL4, IL6, INHA, LIF, MX1, PTH, RBP2, TCRA, TCRB, TGFB2, TGFB3, and UOX have been mapped in the pig with an informative somatic cell hybrid panel. By analyzing these new assignments in the knowledge of heterologous chromosome painting (Zoo-FISH) data for the porcine genome, it is possible to predict subchromosomal locations for most of these loci. Previously defined regions of conserved synteny were confirmed, and the extent of six of these regions was refined. These improvements in the porcine gene map facilitate the transfer of gene mapping data from ``map-rich' species such as humans and mice. Received: 25 September 1995 / Accepted: 11 December 1995     

Mitochondrial GTPase mitofusin 2 mutation in Charcot–Marie–Tooth neuropathy type 2A

Charcot–Marie–Tooth disease (CMT) has been classified into two types, CMT1 and CMT2, demyelinating and axonal forms, respectively. CMT2 has been further subdivided into eight groups by linkage studies. CMT2A is linked to chromosome 1p35–p36 and mutation in the kinesin family member 1B-ß (KIF1B) gene had been reported in one pedigree. However, no mutation in KIF1B was detected in other pedigrees with CMT2A and the mutations in the mitochondrial fusion protein mitofusin 2 (MFN2) gene were recently detected in those pedigrees. MFN2, a mitochondrial transmembrane GTPase, regulates the mitochondrial network architecture by fusion of mitochondria. We studied MFN2 in 81 Japanese patients with axonal or unclassified CMT and detected seven mutations in seven unrelated patients. Six of them were novel and one of them was a de novo mutation. Most mutations locate within or immediately upstream of the GTPase domain or within two coiled-coil domains, which are critical for the functioning or mitochondrial targeting of MFN2. Formation of a mitochondrial network would be required to maintain the functional peripheral nerve axon.     

Esr,a second locus in the house mouse controlling esterase-5

Electrophoretic variation characterized by the presence (ES-5B⁺) or absence (ES-5B^–) of esterase-5B in the plasma of the house mouse has been observed. It is suggested that the expression of esterase-5B is controlled by an autosomal locus, Esr, linked to Ldr-1 on chromosome 6, in addition to the presumptive structural locus Es-5, which is located on chromosome 8. A gene order of Lyt-3-Esr-Ldr-1 was determined by two crosses.Supported by the Deutsche Forschungsgemeinschaft (SFB 46).This is communication No. 33 of a research program devoted to the investigation of cellular distribution and genetics of nonspecific esterases.     

R factor variants with enhanced sex factor activity in Pseudomonas aeruginosa

Summary The R factor R68 readily promotes chromosome transfer in Pseudomonas aeruginosa strain PAT, but shows little such sex factor activity in strain PAO. A variant of this plasmid, R68.45, has been isolated which produces recombinants in PAO plate matings at frequencies of 10^-3–10^-5 per donor cell for markers in the 0–60 min region of the chromosome. Little or no chromosome transfer was shown in liquid media. The kinetics of chromosome transfer were studied by interrupting matings on solid media with nalidixic acid. Five chromosomal markers, mapping in widely spaced regions of the chromosome all entered 3–5 min after initiation of mating. These results, combined with linkage studies, indicate that R68.45, unlike the Pseudomonas sex factors FP2 and FP39, promotes chromosome transfer from a range of origin sites and can thus be used for mapping the region of the P. aeruginosa chromosome later than 40 min.R68.45 and other similar variants were isolated from rare chromosomal recombinants appearing in crosses between PAO(R68) donors and PAO recipients in which selection for argB ⁺ was made. Selection for other chromosomal markers did not result in such variants suggesting that plasmids of the R68.45 type arise by recombination of genetic material between the R68 plasmid and certain regions of the bacterial chromosome.     

Replication of single-stranded porcine circovirus DNA by DNA polymerases α and δ

Porcine circovirus is the only mammalian DNA virus so far known to contain a single-stranded circular genome (Tischer et al. (1982) Nature 295, 64–66). Replication of its small viral DNA (1.76 kb) appears to be dependent on cellular enzymes expressed during S-phase of the cell cycle (Tischer et al. (1987) Arch. Virol. 96, 39–57). In this paper we have exploited the porcine circovirus genome to probe for in vitro initiation and elongation of DNA replication by different preparations of calf thymus DNA polymerase α and δ as well as by a partially purified preparation from pig thymus. The results indicated that three different purification fractions of calf thymus DNA polymerase α and one from pig thymus initiate DNA synthesis at several sites on the porcine circovirus DNA. It appears that the sites at which DNA primase synthesizes primers are not entirely random. Subsequent DNA elongation by a highly purified DNA polymerase α holoenzyme which had been isolated by the criterion of replicating single-stranded M13 DNA (Ottiger et al. (1987) Nucleic Acids Res. 15, 4789–4807) is very efficient. Complete conversion to the double-stranded form is obtained in less than 1 min. When the DNA synthesis by DNA polymerase α is blocked with the DNA polymerase α specific monoclonal antibody SJK 132-20 after initiation by DNA primase, DNA polymerase δ can efficiently replicate from the primers. This in vitro DNA replication system may be used in analogy to the bacteriophage systems in E. coli to study initiation and elongation of DNA replication.     

The Gene Encoding Protein Kinase SEK1 Maps to Mouse Chromosome 11 and Human Chromosome 17

We report the mapping of the human and mouse genes encoding SEK1 (SAPK/ERK kinase-1), a newly identified protein kinase that is a potent physiological activator of the stress-activated protein kinases. The human SERK1 gene was assigned to human chromosome 17 using genomic DNAs from human–rodent somatic cell hybrid lines. A specific human PCR product was observed solely in the somatic cell line containing human chromosome 17. The mouseSerk1gene was mapped to chromosome 11, closely linked toD11Mit4,using genomic DNAs from a (C57BL/6J ×Mus spretus)F₁×M. spretusbackcross.     

A hypervariable repeated sequence on human chromosome 1p36

Summary When used to probe Southern blots of TaqI-digested DNAs from unrelated individuals, p1–79, a 900 bp subclone of a random human cosmid, revealed at least 50 fragments, many of which were polymorphic. Each of 27 unrelated individuals tested with p1–79 displayed a distinct band pattern. Similar variation was seen with several other enzymes, including HaeIII, MspI, PstI and PvuII, whereas other enzymes yielded primarily large fragments of greater than 40 kb. In situ hybridization of p1–79 showed that the loci of hybridization are clustered on human chromosome band 1p36; localization of all TaqI fragments to chromosome 1 was confirmed with a human-rodent somatic cell hybrid panel. DNA sequencing of p1–79 revealed several copies of a 39 bp repeat whose variation in copy number might be the basis of the observed length polymorphisms. Studies of 3-generation Utah families suggest that the numerous restriction fragments homologous to p1–79 are inherited as haplotypes, implying that recombination within this cluster of loci is rare and allowing the cluster to serve as a useful marker for human gene mapping.