The Structure of the Gene Encoding the Human Skeletal Muscle α1Subunit of the Dihydropyridine-Sensitive L-type Calcium Channel (CACNL1A3)

The structure of the gene encoding the human skeletal muscle α₁subunit (CACNL1A3) of the dihydropyridine-sensitive voltage-dependent calcium channel was determined by isolation of overlapping genomic DNA clones from human cosmid, phage, and P1 libraries. Genomic fragments containing exons were subcloned, and the sequences of the exons and flanking introns were defined. Knowledge of the genomic structure of the CACNL1A3 gene, which spans 90 kb and consists of 44 exons, will facilitate the search for additional mutations in CACNL1A3 that cause neuromuscular disease.     

Chromosomal Localization of the Human Genes for α1A, α1B, and α1E Voltage-Dependent Ca Channel Subunits

The α₁ subunit genes encoding voltage-dependent Ca²⁺ channels are members of a gene family. We have used human brain cDNA probes to localize the neuronal isoform genes CACNL1A4 (α_1A), CACNL1A5 (α_1B), and CACNL1A6 (α_1E) to 19p13, 9q34, and 1q25-q31, respectively, using fluorescence in situ hybridization on human chromosomes. These genes are particularly interesting gene candidates in the pathogenesis of neuronal disorders. Although genetic disorders have been linked to loci 9q34 and 19p13, no genetic disease related to Ca²⁺ signaling defects has yet been linked to these loci.     

Localization of the human soluble epoxide hydrolase gene (EPHX2) to chromosomal region 8p21-p12

Epoxide hydrolases have an important function in organisms in that they catalyze the transformation of potentially toxic or carcinogenic epoxides into the corresponding diols. In this study, the chromosomal localization was determined for the human gene encoding soluble epoxide hydrolase. A polymerase chain reaction fragment corresponding to the C-terminal region of the mouse protein was used to isolate a cosmid clone from a human genomic library. By fluorescence in situ hybridization to metaphase chromosomes, the soluble epoxide hydrolase gene was then localized to chromosomal region 8p21-p12.     

Fiber-FISH analysis of the 3'-terminal region of the human L-type Ca2+ channel alpha 1C subunit gene

Human L-type Ca2+ channel alpha 1C subunit gene (CACNL1A1) maps to the distal region of chromosome 12p13, and is composed of approximately 50 exons spanning over 150 kb of the human genome as estimated by restriction map analysis. However, the structure and the total length of the 3'-end of the gene is not clear because the size of several big introns remains unknown. Here the fiber-FISH technique was used to determine the relative order and size of eight partial genomic DNA clones from the central and 3'-terminal regions of CACNL1A1. The total physical distance of this region, including the size and gap distances between the clones were re-estimated. The results show that the physical order of the tested clones was 5'-g14-5 > g12-2 > g10-8 > g4-5 > g16-7 > g8-3 > g12-5 > g6-20-3'. Their individual sizes vary between 6.7 and 21.9 kb. Clones g6-20 and g12-5, both containing repetitive exon 45/46-like element, were found to be located within 59.1 kb downstream of g8-3 containing earlier identified polyadenylation site, i.e. 229.5 kb away from clone g14-5 (exons 10, 11). The possible implications of this structural complexity is discussed.     

A YAC, P1, and Cosmid Contig and 17 New Polymorphic Markers for the Werner Syndrome Region at 8p12–p21

A yeast artificial chromosome (YAC), P1, and cosmid clone contig was constructed for the Werner syndrome (WRN) region of chromosome 8p12–p21 and used to clone a candidate gene forWRN.This region also possibly contains a familial breast cancer locus. The contig was initiated by isolating YACs for the glutathione reductase (GSR) gene and extended in either direction by walking techniques. Sequence-tagged site (STS) markers were generated from subclones of 2GSRYACs and used to identify P1 and cosmid clones. Additional STSs were generated from P1 and cosmid clones and from potential expressed sequences identified by cDNA selection and exon amplification methods. The final contig was assembled by typing 17 YACs, 20 P1 clones, and 109 cosmids for 54 STS markers. TheWRNregion could be spanned by 2 nonchimeric YACs covering approximately 1.4 Mb. A P1/cosmid contig was established covering the core 700–800 kb of theWRNregion. Fifteen new short tandem repeat polymorphisms and 2 biallelic polymorphic markers were identified and included as STSs in the contig. Analysis of these markers in Werner syndrome subjects demonstrates that the candidate WRN gene is in a region of linkage disequilibrium.     

A cosmid clone for the 5HT1A receptor (HTR1A) reveals a TaqI RFLP that shows tight linkage to dna loci D5S6, D5S39, and D5S76.

A human neuroreceptor clone (G21), which was isolated by cross-hybridization with the human clone for the beta 2-adrenergic receptor, has recently been shown to encode the gene for the 5HT1A receptor (HTR1A) subtype. In situ hybridization to human metaphase chromosomes mapped the G21 sequence to chromosome 5 at bands 5q11.2-q13. The clone G21 recognizes a SacI RFLP with low heterozygosity (0.13). To increase the informativeness of the HTR1A locus we have isolated two new cosmid clones containing the receptor gene. No polymorphic microsatellites were present in the cosmids. However, one cosmid revealed a new TaqI RFLP that showed tight linkage to new highly polymorphic microsatellites for the loci D5S76, D5S39, and D5S6 in seven British and Icelandic reference pedigrees (maximum LOD of 13.2 with D5S76).     

SALL3, a new member of the human spalt-like gene family, maps to 18q23

spalt (sal) of Drosophila melanogaster is an important developmental regulator gene and encodes a zinc finger protein of unusual but characteristic structure. Two human sal-like genes have been isolated so far, SALL1 on chromosome 16q12.1 and SALL2 on chromosome 14q11.1-q12.1. Truncating mutations of SALL1 have been shown to cause Townes-Brocks syndrome and are thought to result in SALL1 haploinsufficiency. Sequence comparison of SALL1 to the related genes Msal in mouse and Xsal-1 in Xenopus laevis suggested that SALL1 was not the human orthologue of Msal and Xsal-1. By database searching and genomic cloning, we isolated an EST and a corresponding human cosmid clone, which contain coding sequence of a human gene highly similar to mouse Msal. This gene, named SALL3, was found to be expressed in different regions of human fetal brain and in different adult human tissues. The chromosomal localization of SALL3 at 18q23 suggests that haploinsufficiency of this gene might contribute to the phenotype of patients with 18q deletion syndrome.     

Regional localization of th human EGF-like growth factor CRIPTO gene (TDGF-1) to chromosome 3p21

The CRIPTO gene encodes a novel human growth factor structurally related to epidermal growth factor. We localized the CRIPTO gene to chromosome 3p21 by fluorescence in situ hybridization with a cosmid clone containing 40 kb of the CRIPTO genomic region (TDGF-1). To suppress hybridization to CRIPTO-related sequences, present in multiple copies in the human genome, hybridization was carried out in the presence of unlabeled CRIPTO cDNA in excess over the probe. Our finding confirms the provisional mapping of the CRIPTO gene to chromosome 3, and assigns it precisely to a chromosomal region involved in several rearrangements occurring in malignancy.CRIPTO-specific sequences are present in multiple copies in the human genome (Dono et al. 1991). Two genomic CRIPTO-encoding sequences, TDGF-1 and TDGF-3, have been isolated and characterized. TDGF-1 corresponds to the structural gene encoding the protein expressed in teratocarcinoma cells (Ciccodicola et al. 1989). TDGF-3, possibly a functional pseudogene, corresponds to a complete copy of the TDGF-1 mRNA that contains seven base changes representing both silent and replacement substitutions in the coding region (Dono et al. 1991). By somatic cell hybrid analysis TDGF-1 has been assigned to chromosome 3, and TDGF-3 to the Xq21–22 region (Dono et al. 1991).     

Localization of the mcf.2 transforming sequence to the X chromosome.

A transforming sequence was identified using co-transfection of DNA from the human mammary carcinoma cell line MCF-7 and of a G418 resistance gene into NIH 3T3 cells, followed by tumor formation in athymic mice. This sequence, named mcf.2, was molecularly cloned. A transforming activity resides in a cosmid clone of 42 kb. mcf.2 did not cross-hybridize with the known oncogenes tested. In situ hybridization localized it on the X chromosome, probably at q27. This localization was confirmed by hybridization to a panel of human--rodent cell line DNAs.     

Identification and initial utilization of a portion of the smaller plasmid of Anabaena variabilis ATCC 29413 capable of replication in Anabaena sp. strain M-131

Summary Anabaena variabilis ATCC 29413 contains two cryptic plasmids. Clones of the smaller (41 kb) plasmid, designated pRDS1, in cosmid vectors were used to construct a physical map. A clone bank of pRDS1 constructed by ligating fragments from aXhoII digest of a pRDS1 cosmid clone into a mobilizable plasmid was used to locate an origin of replication of pRDS1. Because we were unable to cureA. variabilis of pRDS1, the clone bank was transferred by conjugation to another strain ofAnabaena sp., strain M-131. A 5.3 kb fragment of pRDS1 contained all of the sequences necessary for replication inAnabaena sp. strain M-131 as judged by the ability to rescue the hybrid vector from exconjugants in unchanged form after many generations. Hybrid plasmids derived from pRDS1, one bearing genes for luciferase, were also transferred by conjugation toA. variabilis, where they appeared to recombine with pRDS1.     

The HLA-AW24 gene: Sequence,surroundings and comparison with the HLA-A2 and HLA-A3 genes

A cosmid clone containing two class I sequences was found to cause expression of the HLA-AW24 protein after transfection into mouse L cells. The restriction map of this cosmid shows extensive homology over 26 kb with the map of the HLA-A3 region obtained from cosmids of the same library, constructed with DNA from an HLA-A3/HLA-AW24 heterozygote, but diverges over the remaining 14 kb. The HLA-AW24 gene was subcloned from this cosmid and its nucleotide sequence was determined. Amino acid and, more strikingly, nucleotide sequence comparisons with other HLA alleles indicate that the A locus alleles are more closely related to each other than to alleles from other HLA loci. A very skewed distribution of silent substitutions is apparent, and the occurrence of clustered multiple substitutions hints at gene-conversion-like events.     

Delimitation of the fertility restorer locus Rfk1 to a 43-kb contig in Kosena radish (Raphanus sativus L.)

We are pursuing a positional cloning strategy to isolate the fertility restoration gene Rfk1 from radish. Random polymorphic DNA-sequence-tagged site (RAPD-STS) markers tightly linked to the gene in radish were isolated, and a RAPD map surrounding the Rfk1 locus was constructed. We surveyed 948 F2 plants with adjacent RAPD-STS markers to isolate recombinants for bulk segregant analysis. This analysis was effective in isolating tightly linked amplification fragment length polymorphism (AFLP) markers surrounding the gene of interest. Ten tightly linked AFLP markers were obtained and used to construct a high-resolution map of the region. The closest AFLP-STS markers flanking Rfk1 were 0.1 cM and 0.2 cM away. Using the four adjacent AFLP markers, we screened lambda and cosmid libraries. The lambda and cosmid clones were aligned by examination of end sequences and restriction fragment length polymorphism (RFLP) patterns for each clone, and by hybridization to the DNA isolated from recombinants. Finally, we constructed a 198-kb contig encompassing the Rfk1 gene and comprising 20 lambda and two cosmid clones. By analysis of the breakpoints in recombinants with the rfk1/rfk1 or Rfk1/- genotype, the Rfk1 locus could be assigned to a 43-kb region comprising four lambda clones and one cosmid clone. This pinpoint localization in the radish genome has made it possible for us to identify the gene by sequence analysis and genetic transformation of cytoplasmic male-sterile Brassica napus plants.     

Chromosomal Localization of the Human Urothelial “Tetraspan” Gene, UPK1B, to 3q13.3–q21 and Detection of aTaqI Polymorphism

The TI1/UPK1b gene codes for a protein of the “tetraspan” family and is expressed as a differentiation product of the mammalian urothelium. A partial genomic clone of the human homologue of the TI1/UPK1b gene was isolated and used as probe to localize the human gene to chromosome 3q13.3–q21 byin situhybridization. Using the same probe, aTaqI restriction fragment length polymorphism, with 29% heterozygosity, was identified by Southern analysis.     

The human gene for neurotrophic tyrosine kinase receptor type 2 (NTRK2) is located on chromosome 9 but is not the familial dysautonomia gene

The neurotrophic tyrosine kinase receptor type 2 (NTRK2) gene is a member of the trk family of tyrosine protein kinases, which encode receptors for the nerve growth factor-related proteins known as neurotrophins. The neurotrophins and their receptors have long been considered candidate genes for familial dysautonomia (FD), a hereditary sensory neuropathy resulting from the congenital loss of both sensory and autonomic neurons. The DYS gene has recently been mapped to human chromosome 9q31–q33, and therefore we set out to determine the chromosomal localization of the candidate gene NTRK2. A mouse trkB probe was hybridized to both somatic cell hybrids containing human chromosome 9 and a human chromosome 9 flow-sorted cosmid library. The human homologue of trkB, NTRK2, was assigned to chromosome 9. To localize the NTRK2 gene further, a dinucleotide repeat polymorphism was identified within a cosmid that contains NTRK2 exon sequences. This marker was genotyped in the CEPH reference pedigrees and places the NTRK2 gene near D9S1 on the proximal long arm of human chromosome 9. The NTRK2 gene is located approximately 22 cm proximal to DYS and shows several recombinants in disease families. Therefore, the NTRK2 gene can now be excluded as a candidate gene for familial dysautonomia.     

The anonymous polymorphic DNA clone D1S1, previously mapped to human chromosome 1p36 by in situ hybridization, is from chromosome 3 and is duplicated on chromosome 1.

D1S1, a human anonymous DNA clone originally called lambda Ch4A-H3 or lambda H3, was mapped by two other laboratories to human chromosome 1p36 by in situ hybridization but its localization was not confirmed using a different mapping method. We used a panel of human-hamster somatic cell hybrids to show that there are copies of D1S1 on both chromosomes 1 and 3. The D1S1 clone itself is from chromosome 3, and part of it is duplicated at least twice on chromosome 1. A high frequency HindIII polymorphism detected by D1S1, believed to be at chromosome 1p36 on the basis of the in situ hybridization data, maps instead to chromosome 3. This finding demonstrates the importance of using two mapping methods to verify the localization of a gene or DNA segment, particularly a polymorphic one which itself may be used in mapping studies. It also raises the question of why in situ hybridization detected a duplicated portion of a clone but not the chromosomal origin of the clone itself.     

The DY sub-region of the sheep MHC contains an A/B gene pair

The major histocompatibility complex (MHC) class II region of ruminants appears to have a structure broadly similar to that of the human class II or HLA-D region. Restriction fragment length polymorphism (RFLP) studies of class II genes in cattle (Andersson et al. 1988; Anderson and Rask 1988; Sigurdardottir et al. 1988, 1991 b), and in sheep (Scott et al. 1987), have provided an estimate of the number and type of class II genes in these species. The subsequent cloning and sequencing of sheep and cattle class II genes (Muggli-Cockett and Stone 1989; Groenen et al. 1990; van der Poel et al. 1990; Andersson et al. 1991; Scott et al. 1991 a, b; Ballingall et al. 1992; Sigurdardottir et al. 1991 a, 1992), have demonstrated that they are highly homologous to their human counterparts. Of more interest, therefore, are loci within the ruminant MHC which differ from the HLA class II region.Three distinguishing features of the ruminant class II region described to date are, firstly, the apparent absence of a DP-like isotype, secondly, the variability in the number of DQ genes between haplotypes (Andersson and Rask 1988), and thirdly, the presence of class II genes presumed to be unique to the ruminant (Andersson et al. 1988). The presence of two such genes, designated DYA and DYB, was deduced from RFLP studies of cattle DNA. These genes were shown to segregate together with the DOB gene in one region separated by a recombination distance of 17 cM from the region which contains the DQA, DQB, DRB, DRA, and C4 loci (Andersson et al. 1988). Subsequently, Bota-DYA was cloned from a phage library and sequenced (van der Poel et al. 1990; Acc. Nos. m30119 and m30118). The sequence of part of a similar gene in the goat, obtained by PCR by using primers derived from the cattle sequence, has recently been reported (Mann et al. 1993; Acc. No. m94325). However, there has been no report of the cloning of a B gene partner for the DYA gene. A novel cattle class II B gene designated Bota-DIB was cloned from a phage library and sequenced by Stone and Muggli-Cockett (1990). This was shown to be a single copy gene of limited polymorphism, which on the basis of RFLP analysis was probably not Bota-DYB but did appear to be distinct from other known cattle class II genes. The species distribution of this B gene was shown to be restricted to Cervidae, Giraffidae, and Bovidae (Stone and Muggli-Cockett 1993). However, it is not known whether any of these novel genes are functional.Expressed human class II genes usually occur as A/B gene pairs situated close to each other on the chromosome. This is also the case with Bota-DQ genes (Groenen et al. 1990) and Ovar-DQ genes (Deverson et al. 1991; Wright and Ballingall 1994). We used the techniques of cosmid cloning and DNA-mediated gene transfection to determine whether there is a sheep equivalent of the Bota-DYA gene, whether there is a DYB gene partner, and whether there is a protein product.A cosmid library was constructed from DNA prepared from a Finnish Landrace ram. The library was screened with Ovar-DQA, Ovar-DQB, HLA-DQA, and HLA-DQB gene probes at low stringency. A cosmid clone, 365, was obtained which hybridized weakly to both the Ovar gene probes. Restriction maps of the clone were produced for the enzymes Eco R1, Bam HI, Hin dIII, Sac I and Sma I. When the maps were compared to those published for the phage clones containing the Bota-DYA (van der Poel et al. 1990) and the Bota-DIB gene (Stone and Muggli-Cockett 1990), there was an imperfect match (Figure 1 shows the Eco RI maps). However, the sequence data for the A and B genes in cosmid 365 are more convincing. The sequences of exons 2 and 3 of the A gene in cosmid 365 and the Bota-DYA gene, together with the partial sequence from the third exon of the Cahi-DYA gene are shown in Figure 2 A. The predicted amino acid translations of these genes together with those of other published sheep MHC class II A genes are shown in Figure 2 B. The A gene in cosmid 365 had all the salient features of an MHC class II A gene. It showed a high sequence similarity to the cattle and caprine DYA genes and much less so to the Ovar-DRA gene (Ballingall et al. 1992; Acc. No z11600) and the Ovar-DQA1 and DQA2 (Scott et al. 1991 a; Acc. Nos. m33304 and m33305), as detailed in Table 1. The cosmid A gene showed low sequence similarity to the sheep DNA (formerly DZA) gene (unpublished observations). The A gene described here is clearly the sheep homologue of the Bota-DYA gene.The sequences of the second, third, and fourth exons of the B gene in cosmid 365 are shown in Figure 3 A together with those of the Bota-DIB gene (Stone and Muggli-Cockett 1990). Unfortunately, the presence of a Bam HI site in exon 2 of the sheep gene caused a truncation at this point, during the cloning procedure and so a part of exon 2, the whole of exon 1, and all the upstream regulatory elements were missing. The predicted amino acid translations of exons 2, 3, and 4 are shown together with those of an Ovar-DQB (Scott et al. 1991 a; Acc. No. m33323) and an expressed Ovar-DRB gene (Ballingall et al. 1992; Acc. No. z11522) in Figure 3 B.