Monochromosomal rodent-human hybrids from microcell fusion of human lymphoblastoid cells containing an inserted dominant selectable marker

Construction of somatic cell hybrids

Somatic cell hybridization is the method of choice to separate a chromosome of interest from the full chromosome complement and obtain a permanent source of the chromosome. This unit begins with the choice of fusion techniques and selectable markers for hybrids containing a chromosome of interest. The first set of protocols outline the production of whole-cell hybrids by fusion of two cell lines: a monolayer (adherent) recipient and a donor that may be adherent or grown in suspension. The second set of protocols outline the production of micronuclei containing a limited number of chromosomes, and enucleation of the micronuclei to form microcells for fusion with recipient cells. Support protocols describe the preparation and use of cloning cylinders to isolate colonies in tissue culture, subcloning of whole-cell hybrid populations to isolate lines that have segregated additional chromosomes, purification of microcell preparations, and molecular and cytogenetic methods for characterizing.

Human monochromosome hybrid cell panel characterized by FISH in the JCRB/HSRRB

The human monochromosome hybrid cell panel in the Japanese Collection of Research Bioresources (JCRB) consists of 23 mouse cell clones, each containing a different human chromosome (the Y chromosome is not yet included). The panel is currently distributed by the Human Science Research Resources Bank (HSRRB) in Osaka. In order to determine the state of the human chromosomes and to supply the information to investigators, we characterized the cells by fluorescence in-situ hybridization (FISH) with corresponding human chromosome-specific painting probes, and, in part, by reverse FISH with the hybrid total DNA hybridized onto human metaphase spreads. Here, we report the frequency of intact human chromosomes maintained in each hybrid and the retained subregions of corresponding human chromosomes with relative frequencies estimated by fluorescent intensity. We used specific painted patterns to classify each hybrid into tentative types with their frequencies showing the nature of each hybrid and the state of rearrangements. This characterization will provide valuable information to investigators using the panel.

Cloning, genomic organization and expression of a putative human transmembrane protein related to the Caenorhabditis elegans M01F1.4 gene

A novel human transcript CG-2 (C9ORF5), was isolated from the familial dysautonomia candidate region on 9q31 using a combination of cDNA selection and exon trapping. CG-2 was detected as a relatively abundant 8kb transcript in all adult and fetal tissues with the exception of adult thymus. Genomic analysis of CG-2 identified 18 exons that span more than 110kb. The gene encodes a 911-amino-acid protein with a predicted molecular weight of 101kDa and a hypothetical pI of 9.03. Sequence analysis of CG-2 indicates that it is likely to encode a transmembrane protein. Here, we assess CG-2 as a candidate for familial dysautonomia.

DNA cytometry and chromosome 9 aberrations by fluorescence in situ hybridization of irrigation specimens from bladder cancer patients

OBJECTIVES

To determine the sensitivity and specificity of combining fluorescence in situ hybridization (FISH) measurement of chromosome 9 and DNA cytometry of bladder irrigation specimens in the detection of bladder cancer.

METHODS

Bladder irrigation specimens were obtained from 37 normal control patients and 317 bladder cancer patients during cystoscopic examinations. Bladder cancer patients were sampled in the absence of observable tumor (256 specimens) and concurrently with tumor (204 specimens). Chromosome 9 copy number was determined on a cellular basis by FISH, and cellular DNA content was determined by Feulgen DNA staining and image cytometry.

RESULTS

Sensitivity of chromosome 9 FISH was 42% for all tumors and was not correlated to transitional cell carcinoma tumor grade, while the sensitivity of DNA cytometry was 55% and improved with increasing grade from 38% for grade 1 to 90% for grade 3 tumors. The results of FISH and DNA cytometry were combined, resulting in specificity of 92% and sensitivity of 69% for grade 1, 76% for grade 2, and 97% for grade 3 tumors.

CONCLUSIONS

The lack of increase with grade in the percentage of positive specimens by FISH supports the hypothesis that chromosome 9 aberrations are critical events in bladder tumorigenesis for many patients. These data demonstrate the presence of cells in irrigation specimens with specific genomic lesions of chromosome 9 and DNA content. Combining FISH on chromosome 9 and DNA cytometry provides an increase in sensitivity to transitional cell carcinoma over either test alone.

Deletion mapping of chromosome region 9p21-p22 surrounding the CDKN2 locus in melanoma

The cyclin-dependent kinase-4 inhibitor gene CDKN2, localized at chromosome region 9p21, has been shown to be a familial melanoma gene, though we found that mutations of it are rare in uncultured sporadic melanomas. To determine Whether the region of allelic loss at 9p21 frequently observed in sporadic melanomas includes the CDKN2 locus, new polymorphic microsatellite probes were isolated from the genomic segments surrounding the CDKN2 gene and used for the study of loss of heterozygosity (LOH) in melanoma. The LOH study of matched uncultured tumor-constitutional DNA pairs from 66 metastatic cutaneous and 19 primary uveal melanomas showed that 63% and 32% of the respective tumors suffered allelic loss in the 9p21 region. Two regions of common losses which did not include the CDKN2 locus were observed: in a region of common loss near the D9S157 locus, telomeric to the CDKN2 locus, deletions were observed in 51% of informative cases; in the other region of common loss, near the D9S171 locus, centromeric to the CDKN2 locus, deletions were observed in 47% of informative cases. At the D9S974 locus, located within 20 kb of the CDKN2 gene, deletions were observed in 43% of informative cases. Homozygous deletions of the CDKN2 locus were observed in 8 cases of cutaneous melanoma and 2 cases of uveal melanoma; mutations in CDKN2 exon 2 were found in 2 of the 46 cases with allelic deletion in 9p21. Our results support the following conclusions: (i) somatic mutation of the CDKN2 gene is rare in sporadic melanomas with allelic loss at 9p21; (ii) homozygous loss is more frequent than mutation of the CDKN2 gene in sporadic melanomas; (iii) at 9p21-p23 genes other than CDKN2 may be involved in the development of sporadic melanomas.

Growth arrest and suppression of tumorigenicity of bladder-carcinoma cell lines induced by the P16/CDKN2 (p16INK4A, MTS1) gene and other loci on human chromosome 9

Wild-type P16/CDKN2 (p16INK4A, MTS1) cDNA, directed by the cytomegalovirus (CMV) immediate early promoter, was transfected into RT4 and RT112 bladder-carcinoma cell lines bearing a mutated endogenous P16/CDKN2 gene and lacking endogenous P16/CDKN2 respectively. In both cases, only transfected clones with rearranged exogenous P16/CDKN2 cDNA could be grown and propagated in cell culture. This result is reminiscent of transfection of wild-type p53 into cells with a deleted or mutated endogenous gene and suggests that P16/CDKN2, over-expressed under control of the strong CMV promoter, induces growth arrest in RT4 and RT112 cells. Transfer of human chromosome 9 to RT4 cells produced RT4/H9 hybrid clones retaining the P16/CDKN2 gene, since in RT4/H9 cell clones P16/CDKN2-gene expression is modulated by the physiological control of chromosomal regulatory sequence. All the RT4/H9 clones lost the entire chromosome 9, except clone 4 and clone 5, which maintained a deleted and an intact chromosome 9 respectively. Loss of several loci in 9p21, including P16/CDKN2, in tumors induced in nude mice by clone 4 and clone 5 suggests that P16/CDKN2 or other genes in 9p21 suppress tumorigenicity in bladder-carcinoma cells. Tumors induced by clone 4 and clone 5 show loss of markers in 9q. The regions 9q22.3, 9q32-33 and 9q34.2, which were maintained in the 2 clones and lost in their derived tumors, may contain tumor-suppressor genes relevant in bladder carcinoma. The results of this study suggest that the P16/CDKN2 gene controls growth of bladder-carcinoma cells when it is over-expressed, and may be involved in the development of bladder carcinoma, but other genes in 9p21 and 9q may participate in bladder-cancer progression.

The Bloom's syndrome gene product is homologous to RecQ helicases

The Bloom's syndrome (BS) gene, BLM, plays an important role in the maintenance of genomic stability in somatic cells. A candidate for BLM was identified by direct selection of a cDNA derived from a 250 kb segment of the genome to which BLM had been assigned by somatic crossover point mapping. In this novel mapping method, cells were used from persons with BS that had undergone intragenic recombination within BLM. cDNA analysis of the candidate gene identified a 4437 bp cDNA that encodes a 1417 amino acid peptide with homology to the RecQ helicases, a subfamily of DExH box-containing DNA and RNA helicases. The presence of chain-terminating mutations in the candidate gene in persons with BS proved that it was BLM.

Gene expression in response to retinoic acid in novel human chromosome 21 monochromosomal cell hybrids

To access a wide a variety of expressed sequence from human chromosome 21 we have placed this chromosome into undifferentiated P19 mouse embryonic carcinoma cells. Cell lines resulting from these experiments have a range of morphologies and a wide variety of karyotypes. We have studied the retinoic acid response of five cell lines, compared to P19 cells, by observing three markers of retinoic acid induced P19 differentiation--cell morphology, RAR alpha and Wnt1 transcription. We see an 'early' retinoic acid response effect, however this response breaks down by the time the 'late' gene. Wnt1 would be transcribed in P19 cells. A highly responsive cell line will be useful for cloning expressed sequences from human chromosome 21 which are produced by early genes in retinoic acid inducible pathways, such as those involved in neurogenesis.

Three new dinucleotide repeat polymorphisms on human chromosome 9: D9S970, D9S971, and D9S972

Three human chromosome 9-specific cosmid recombinants containing (CA)n microsatellites are described. Three microsatellite loci, D9S970, D9S971, and D9S972, were observed to have heterozygosities of 0.78, 0.84, and 0.82, respectively. Subchromosomal localizations were determined by R-banding and fluorescence in situ hybridization.

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.

Identification of the chromosome 12 translocation breakpoint region of a pleomorphic salivary gland adenoma with t(1;12)(p22;q15) as the sole cytogenetic abnormality

Cell line Ad-312/SV40, which was derived from a primary pleomorphic salivary gland adenoma with t(1;12)(p22;q15), was used in fluorescence in situ hybridization (FISH) analysis to characterize its translocation breakpoint region on chromosome 12. Results of previous studies have indicated that the chromosome 12 breakpoint in Ad-312/SV40 is located proximally to locus D12S8 and distally to the CHOP gene. We here describe two partially overlapping yeast artificial chromosome (YAC) clones, Y4854 (500 kbp) and Y9091 (460 kbp), which we isolated in the context of a chromosome walking project with D12S8 and CHOP as starting points. We present a composite long-range restriction map encompassing the inserts of these two YAC clones and show by FISH analysis that both YACs span the chromosome 12 breakpoint as present in Ad-312/SV40 cells. Subsequently, we have isolated cosmid clones corresponding to various sequence-tagged sites (STSs) mapping within the inserts of these YAC clones. These included cRM51, cRM69, cRM85, cRM90, cRM91, cRM110, and cRM111. In FISH studies, cosmid clones cRM85, cRM90, and cRM111 appeared to map distally to the chromosome 12 breakpoint, whereas cosmid clones cRM51, cRM69, cRM91, and cRM110 were found to map proximally to it. These results assign the chromosome 12 breakpoint in Ad-312/SV40 to a DNA region of less than 165 kbp. FISH evaluation of the chromosome 12 breakpoints in five other pleomorphic salivary gland adenoma cell lines indicated that these are located proximally to the one in Ad-312/SV40, at a distance of more than 0.9 Mbp from STS RM91. These results, while pinpointing a potentially critical region on chromosome 12, also provide evidence for the possible involvement of 12q13-q15 sequences located elsewhere.

Identification, molecular cloning, and characterization of the chromosome 12 breakpoint cluster region of uterine leiomyomas

Recent molecular cytogenetic analysis of uterine leiomyoma cell lines with chromosome 12 aberrations has indicated that their chromosome 12 breakpoints map between linkage locus D12S8 and the CHOP gene. Here, we report fluorescence in situ hybridization (FISH) and molecular cloning studies of the chromosome 12 breakpoints in a panel of seven such uterine leiomyoma cell lines; five with the frequently observed t(12;14)(q15;q24), one with t(12;15)(q15;q24), and one with ins(12;11)(q14;q21qter). Directional chromosome walking studies starting from D12S8 and the CHOP gene resulted in the isolation of a relatively large number of overlapping YAC clones, including Y5355 (465 kbp), Y7673 (360 kbp), and Y9899 (275 kbp). In total, the inserts of these three YAC clones span an 800 kbp long and presumably contiguous stretch of human genomic DNA. All chromosome 12 breakpoints of the uterine leiomyoma cell lines studied were found by FISH analysis to be mapping within a 445 kbp subfragment of this region and, furthermore, to be dispersed over a DNA region which is at least 150 kbp in size. The chromosome 12 breakpoint of t(12;14)(q15;q24) in uterine leiomyoma cell line LM-30.1/SV40 was tentatively mapped within the 60 kbp region between YAC clones Y9899 and Y5355. From this 60 kbp region and close to sequence-tagged site RM99, we isolated probe pRM118-A, which showed in Southern blot analysis that it detected a rearrangement in LM-30.1/SV40 DNA, and generated restriction maps of the normal and rearranged genomic DNA regions detected with this probe. Finally, we molecularly cloned part of one of those rearranged DNA fragments using a vectorette-PCR-based technique and demonstrated that it consisted of 12q13-q15 sequences fused to DNA sequences derived from 14q23-24 and most likely represented the translocation junction on der(14) in LM-30.1/SV40 cells. Our studies strongly suggest that we have identified and isolated the uterine leiomyoma cluster region of chromosome 12 breakpoints, which we designate ULCR12, and molecularly cloned and characterized the der(14) translocation junction in cells derived from a uterine leiomyoma carrying the frequently observed t(12;14)(q15;q24).

Isolation of genes from complex sources of mammalian genomic DNA using exon amplification

Modifications to exon amplification have been instituted that increase its speed, efficiency and reliability. Exons were isolated from target human or mouse genomic DNA sources ranging from 30 kilobases (kb) to 3 megabases (Mb) in complexity. The efficiency was dependent upon the amount of input DNA, and ranged from isolation of an exon for every 20 kb to an exon for every 80 kb of target genomic DNA. In these studies, several novel genes and a smaller number of genes isolated previously that reside on human chromosome 9 have been identified. These results indicate that exon amplification is presently adaptable to large scale isolation of exons from complex sources of genomic DNA.

Construction and characterization of a YAC library with a low frequency of chimeric clones from flow-sorted human chromosome 9

Human chromosome 9 DNA, flow-sorted from somatic cell hybrid PK-87-9, has been used to construct two complete digest YAC libraries. The combined representation of chromosome 9 in these libraries, estimated by hybridization of chromosome 9-specific sequences to YAC colony grids, is approximately 95%. The frequency of chimeric clones, analyzed by fluorescence in situ hybridization of chromosome 9 YACs to human metaphase chromosomes, was estimated to be approximately 4%. These libraries provide a resource for physical mapping and for moving from genetic markers to disease loci on chromosome 9.

The use of methylthioadenosine phosphorylase activity to select for human chromosome 9 in interspecies and intraspecies hybrid cells

Methylthioadenosine phosphorylase (MTAP) is an enzyme that functions in a salvage pathway for adenine synthesis. The locus that encodes MTAP activity has been mapped to human chromosome 9 (9q12-9pter) by analysis of mouse x human somatic cell hybrids. Cells that have MTAP activity will stop proliferating, and eventually die in the presence of azaserine, an inhibitor of de novo purine synthesis, but can be rescued by the addition of methylthioadenosine (MTA) to the culture medium. Some mouse and human tumor cells lack MTAP activity and can not grow in the presence of azaserine and MTA. We fused MTAP competent human fibroblast cells to MTAP deficient mouse L-cells and selected for somatic cell hybrids, containing MTAP activity, in medium containing azaserine and MTA. In a separate experiment, a CHO cell x human fibroblast somatic cell hybrid, containing a normal copy of human chromosome 9, was used to prepare microcells, which were fused to an MTAP-deficient human leukemic cell line, CCRF-CEM. Somatic cell and microcell hybrids were shown to retain human chromosome 9 by fluorescence in situ hybridization using probes that hybridize to the interferon-alpha and -beta 1 genes on human chromosome 9 (9p21), and the centromere of human chromosome 9. This is the first report of complementation for MTAP activity being used to select for somatic cell hybrids and microcell hybrids that retain a human chromosome 9.

Localization of the retinoid X receptor alpha gene (RXRA) to chromosome 9q34

The retinoid X receptor alpha is one of a number of retinoic acid receptors which are members of the steroid/thyroid hormone superfamily. Localization of RXRA was achieved using the polymerase chain reaction on a panel of somatic cell hybrids. A cosmid clone was isolated using the RXRA PCR product, and this was used to further localize the gene by fluorescence in situ hybridization to chromosome 9q34 distal to the dopamine beta hydroxylase gene (DBH). This mapping position was confirmed by PCR on a panel of translocation hybrids.

Molecular cloning of the human alpha 2(IX) collagen cDNA and assignment of the human COL9A2 gene to chromosome 1

Type IX collagen, a heterotrimer of alpha 1(IX), alpha 2(IX) and alpha 3(IX) chains, is a cartilage-specific fibril-associated collagen. In the process of characterizing genomic clones for the mouse alpha 2(IX) collagen gene four pairs of oligonucleotide primers designed for amplification of murine exon sequences were also utilized to construct cDNA clones for human alpha 2(IX) collagen spanning > 90% of the coding region. The amino acid and nucleotide sequence identities between human and chick are 78% and 71%, respectively. Localization of the COL9A2 gene to human chromosome 1 was subsequently performed using a panel of DNAs from human/rodent somatic cell hybrids.

Cloning of a human galactokinase gene (GK2) on chromosome 15 by complementation in yeast

A human cDNA encoding a galactokinase (EC 2.7.1.6) was isolated by complementation of a galactokinase-deficient (gal1-) strain of Saccharomyces cerevisiae. This cDNA encodes a predicted protein of 458 amino acids with 29% identity to galactokinase of Saccharomyces carlsbergensis. Previous studies have mapped a human galactokinase gene (GK1) to chromosome 17q23-25, closely linked to thymidine kinase. The galactokinase gene that we have isolated (GK2) is located on chromosome 15. The relationship between the disease locus for galactokinase deficiency galactosemia, which is responsible for cataracts in newborns and possibly presenile cataracts in adults, and the two galactokinase loci is unknown.

Direct formation of microcells from mitotic cells for use in chromosome transfer

Microcells, cytoplasmic fragments that contain micronuclei composed of one or a few chromosomes, can be generated directly from mitotic cells. Cytochalasin B, which causes nuclear extrusion in interphase cells, has a similar effect on the chromosomes of colcemid-blocked mitotic cells. The forces generated during centrifugation in a Percoll gradient are sufficient to separate the extruded microcells from the parent cell. The chromosomes contained in an extruded microcell form micronuclei during the process, and in all respects are comparable to microcells generated from micronucleated cells except that they are uniformly in the G1 phase of the cell replication cycle. The procedure is probably applicable to all mammalian cells that grow in culture and can be employed to make microcells for the transfer of both intact and fragmented chromosomes.

Homozygous deletions within human chromosome band 9p21 in melanoma

Genetic studies have implicated the early involvement of a gene on chromosome arm 9p in the development of cutaneous melanoma. We have performed loss-of-heterozygosity studies to confirm these original findings and identify the most frequently rearranged or deleted region of 9p. Eight markers were analyzed, including (from 9pter to proximal 9q) D9S33, the beta-interferon (IFNB1) locus, the alpha-interferon (IFNA) gene cluster, D9S126, D9S3, D9S19, the glycoprotein 4 beta-galactosyltransferase (GGTB2) gene, and the argininosuccinate synthetase pseudogene 3 (ASSP3). Two or more of these loci were found to be hemizygously reduced in 12 of 14 (86%) informative metastatic melanoma tumor and cell line DNAs, and homozygous deletions of the marker D9S126 were observed in 2 of 20 (10%) melanoma cell lines. These findings have resulted in the identification of a small critical region of 2-3 megabases on 9p21 in which a putative melanoma tumor-suppressor gene appears likely to reside. Several 9p candidate genes, including IFNB1, the IFNA gene cluster, GGTB2, and the tyrosinase-related protein (TYRP) locus, have all been eliminated as potential targets because they are located outside of the homozygously deleted regions.

Preferential chromosome loss in human papilloma virus DNA-immortalized mammary epithelial cells

Human papilloma virus (HPV) DNA-immortalized human mammary epithelial cells may provide a model system for studying the molecular basis of immortalization and its role in breast neoplasia. Cytogenetic analyses were performed on clones derived from HPV 16- and HPV 18-immortalized human mammary epithelial cells. The majority of the clones contained near-diploid karyotypes. The single most frequent whole-chromosome loss was that of chromosome 19. Regions that showed preference for deletion and/or translocation included 2pter, 11qter, and 15pter. Evidence of chromosome 19 loss was confirmed by polymerase chain reaction (PCR)-generated, chromosome 19-specific, dinucleotide microsatellite repeat polymorphism analysis.

Genetic and physical map of the interferon region on chromosome 9p

A region of chromosome 9, surrounding the interferon-beta (IFNB1) locus and the interferon-alpha (IFNA) gene cluster on 9p13-p22, has been shown to be frequently deleted or rearranged in a number of human cancers, including leukemia, glioma, non-small-cell lung carcinoma, and melanoma. To assist in better defining the precise region(s) of 9p implicated in each of these malignancies, a combined genetic and physical map of this region was generated using the available 9p markers IFNB1, IFNA, D9S3, and D9S19, along with a newly described locus, D9S126. The relative order and distances between these loci were determined by multipoint linkage analysis of CEPH (Centre d'Etude du Polymorphisme Humain) pedigree DNAs, pulsed-field gel electrophoresis, and fluorescence in situ hybridization. All three mapping approaches gave concordant results and, in the case of multipoint linkage analysis, the following gene order was supported for these and other closely linked chromosome 9 markers present in the CEPH database: pter-D9S33-IFNB1/IFNA-D9S126-D9S3-D9S19 -D9S9/D9S15-ASSP3-qter. This map serves to extend preexisting chromosome 9 maps (which focus primarily on 9q) and also reassigns D9S3 and D9S19 to more proximal locations on 9p.

Reassessment of a chromosome 12q+ marker by fluorescent in situ hybridization (FISH)

We present a case previously described by Jenkins et al. (1983) as atypical Down syndrome (DS). The initial diagnosis was first made on the basis of phenotypic and cytogenetic data. This analysis was supported by studies of superoxide dismutase (SOD1) activity that maps to band 21q22.1. Results from phenotypic, chromosome banding and SOD1 studies suggested a karyotype of 46,XX,-12,+t(12pter to 12qter::21q21 to 21q22.?2). Using fluorescent in situ hybridization (FISH) for chromosome painting with DNA libraries derived from sorted human chromosomes to stain selectively the chromosomes No. 21 and No. 12, we demonstrate that the marker chromosome 12q+ has no chromosome 21 content but it is derived from chromosome 12.

Human chromosome 12 is required for optimal interactions between Tat and TAR of human immunodeficiency virus type 1 in rodent cells

Levels of trans activation of the human immunodeficiency virus type 1 long terminal repeat (HIV-1 LTR) by the virally encoded transactivator Tat show marked species-specific differences. For example, levels of transactivation observed in Chinese hamster ovary (CHO) rodent cells are 10-fold lower than those in human cells or in CHO cells that contain the human chromosome 12. Thus, the human chromosome 12 codes for a protein or proteins that are required for optimal Tat activity. Here, the function of these cellular proteins was analyzed by using a number of modified HIV-1 LTRs and Tats. Neither DNA-binding proteins that bind to the HIV-1 LTR nor proteins that interact with the activation domain of Tat could be implicated in this defect. However, since species-specific differences were no longer observed with hybrid proteins that contain the activation domain of Tat fused to heterologous RNA-binding proteins, optimal interactions between Tat and the trans-acting responsive RNA (TAR) must depend on this factor(s).

Genomic organization, sequence analysis, and chromosomal localization of the human carboxyl ester lipase (CEL) gene and a CEL-like (CELL) gene

The gene encoding human carboxyl ester lipase (CEL), including 1628 bp of the 5'-flanking region, has been isolated and characterized from two overlapping lambda phage clones. The gene spans 9832 bp and contains 11 exons interrupted by 10 introns. The exons range in size from 88 to 204 bp, except for the last exon, which is 841 bp. A major and a minor transcription initiation site were determined 13 and 7 bp, respectively, upstream of the initiator methionine. The nucleotide sequence is identical with that of the previously reported cDNA, except for the third nucleotide in the 5'-untranslated sequence, a C, which in the cDNA is a T. A TAAATA sequence is present 26 nt upstream from the major CAP site, and within the 5'-flanking region there are several putative transcription factor binding sites. Seven Alu repetitive sequence elements are present in the region analyzed. The organization of the human CEL gene is similar to that of the recently reported rat pancreatic cholesterol esterase gene. The CEL gene was assigned to chromosome 9q34-qter, which confirms the recently reported results of Tayler et al. (1991, Genomics 10: 425-431). A previously unknown gene with a striking homology to the human CEL gene, here called the CEL-like gene (CELL), has also been isolated and characterized, including 1724 bp of the 5'-flanking region. The CELL gene, which most likely is a psuedogene, spans 4846 bp, and due to the absence of a 4.8-kb segment, the CEL gene exons 2-7 are not present in the CELL gene. Despite these differences, the CELL gene is transcribed. We have also assigned the CELL gene to a separate locus at chromosome 9q34-qter.

Radiation-reduced hybrids for the myotonic dystrophy locus

The myotonic dystrophy (DM) gene maps to the long arm of human chromosome 19 and is flanked by markers ERCC1 and D19S51. Also mapping to this region is the polio virus receptor gene (PVS). To produce more markers for this interval, we have constructed radiation-reduced hybrids by selecting for the retention of ERCC1 and for the loss of PVS. One of the cell lines produced has been characterized extensively and contains about 2 Mb of human DNA derived exclusively from chromosome 19, and includes ERCC1 and D19S51. Phage libraries constructed from DNA of this cell line have been screened and several new markers identified, including two for which cDNAs have been isolated. These represent candidate genes for DM. The new markers have also been used to extend the long-range restriction map of this region.

Banding profiles of LTR of human endogenous retrovirus HERV-A in 24 chromosomes in somatic cell hybrids

The human genome carries multiple copies of sequences related to endogenous retroviral genomes. We investigated the distribution of one of these sequences, HERV-A, in 24 human chromosomes by Southern analyses using DNAs from flow-sorted chromosomes or rodent cells carrying a single human chromosome. The results showed that HERV-A is distributed among all human chromosomes and that each chromosome has a specific Southern blot profile. The chromosome-specific pattern did not show significant polymorphism, except in a few cases, when the same chromosome obtained from different individuals was compared. These chromosome-specific Southern hybridization profiles may be useful for chromosome karyotyping. This would allow the integrity of human chromosomes in human-rodent somatic cell hybrids to be monitored without using conventional cytogenetic methods.

Generation and characterization of a human chromosome 9 cosmid library

A cosmid library has been constructed from the hamster-human hybrid cell line PK-87-9, which contains chromosome 9 as its sole known human component. Ten thousand colonies were produced, of which approximately 200, or 2%, contain human material. Fifty of these 200 were regionally mapped by an Alu-primed PCR product hybridization procedure. These cosmids were localized to all regions of chromosome 9, but were especially concentrated in the distal portion of 9q. The map location derived by the Alu-primed PCR product hybridization procedure was compared to the map location derived by fluorescent in situ hybridization. Assignment of chromosomal location by the two methods was correspondent in all but a few cases. The presumptive presence of HTF islands was investigated for 130 cosmids by digestion with the restriction enzyme NotI. Twenty percent of cosmids contained at least one NotI site. A number of simple sequence repeat polymorphisms identified from the cosmid set were characterized and will provide a link between the genetic and physical maps for this chromosome.

Construction and characterization of radiation hybrids for chromosome 9, and their use in mapping cosmid probes on the chromosome

Radiation hybrids were produced from a monochromosomal microcell hybrid (PK87-9) which contains only human chromosome 9 with an inserted marker on 9p. Doses of radiation ranging from 1000 to 8000 rads were used to produce a series of hybrids with different size fragments of human chromosome 9. The inserted dominant selectable marker was used to select for hybrids that preferentially maintain fragments of 9p. A panel of 53 radiation hybrids were characterized for 17 chromosome 9 markers. In addition, 17 hybrids were analyzed by fluorescent in situ hybridization (FISH). Hybrids were produced with breaks on both 9p and 9q, many of which appear to contain a single fragment of human chromosome 9. These hybrid cell lines were used to regionally localize 31 cosmids isolated from a chromosome 9 cosmid library. Six cosmids were mapped to intervals on 9p, six cosmids mapped to the centromeric region of the chromosome, and 19 mapped to 9q.

Molecular cloning, characterization, and genomic localization of a human potassium channel gene

Potassium (K+) channels are critical for a variety of cell functions, including modulation of action potentials, determination of resting membrane potential, and development of memory and learning. In addition to their role in regulating myocyte excitability, cardiac K+ channels control heart rate and coronary vascular tone and are implicated in the development of arrhythmias. We report here the cloning and sequencing of a k+ channel gene, KCNA1, derived from a human cardiac cDNA library and the chromosomal localization of the corresponding genomic clone. Oligonucleotides based on a delayed rectifier K+ channel gene were used in PCR reactions with human genomic DNA to amplify the S4-S6 regions of several different K+ channel genes. These sequences were used to isolate clones from a human cardiac cDNA library. We sequenced one of these clones, HCK1. HCK1 contains putative S2-S6 domains and shares approximately 70% sequence homology with previously isolated Shaker homologues. HCK1 was used to screen human cosmid libraries and a genomic clone was isolated. By sequencing the genomic clones, a putative S1 domain and translation initiation sequences were identified. Genomic mapping using human-rodent somatic cell panels and in situ hybridization with human metaphase chromosomes have localized KCNA1 to the distal short arm of human chromosome 12. This work is an important step in the study of human cardiac K+ channel structure and function and will be of use in the study of human inherited disease.

Chromosomal assignment of 46 brain cDNAs

Expressed sequence tags (ESTs) have been obtained from several hundred brain cDNAs as an initial effort to characterize expressed brain genes. These ESTs will become tools for human genome mapping and they will also provide candidate causative genes for inherited disorders affecting the central nervous system. We have developed a procedure for the rapid chromosomal assignment of these ESTs: cDNA sequences are first analyzed by a computer program to determine regions likely not to be interrupted by introns in the genomic DNA. A pair of oligonucleotide primers is then designed to amplify this region by the polymerase chain reaction using DNA template from human-rodent somatic cell hybrid chromosomal panels. The chromosomal assignment of the cDNA is determined by studying the segregation of the amplified products in these panels. In this paper we describe the mapping of 46 brain ESTs, as well as observations on the amplification of rodent sequences.

Construction of a GT polymorphism map of human 9q

To construct a framework map of human chromosome 9 consisting of highly informative markers, we identified 36 cosmid clones from chromosome 9 that contained long GT repeat sequences. The cosmids were found to cluster on the long arm of the chromosome, particularly in the q32-34 region. Thirteen highly informative polymorphisms from 9q were identified, with median observed heterozygosity 0.75 and median calculated heterozygosity based upon allele frequencies of 0.75. These new GT repeat polymorphisms (D9S56, D9S58-67), as well as anchor GT polymorphisms for D9S15 (MCT112, 9q13), and ABL and ASS (both 9q34.1) were utilized to construct a linkage map of human 9q by the typing of the Venezuelan Reference Pedigree. Care was taken to avoid errors, including analysis of the data with CHROMLOOK and verification of all double crossover events detected within a 30 cM interval by repetition of the marker analysis. The map was generated using the MAPMAKER program. All positions in the resulting map are favored by odds of greater than 10(4):1. The map has a sex-averaged length of 90 cM (Kosambi function) with a single maximum intermarker recombination fraction of 26%. All other intermarker recombination fractions are less than 15%. As D9S15 is known to be closely linked to markers on proximal 9p, and ASS/ABL are in band 34.1, this set of GT polymorphisms spans the length of 9q and provides a useful panel for linkage analysis of disease genes to this region. The marker order was confirmed by in situ hybridization of the cosmid clones to metaphase spreads of normal human chromosomes, which indicated an excess of recombination in the telomeric region in comparison to centromeric 9q, in agreement with previous chiasmata distribution observations. Two spontaneous new mutations for these GT repeat markers were identified, giving an overall observed spontaneous mutation rate of 0.00045 per locus per gamete. Direct observation of new mutations has not been previously reported for dinucleotide polymorphisms, but the observed rate is consistent with frequencies observed for other VNTR polymorphisms.

Positive selectable markers for use with mammalian cells in culture

As more complicated gene expression studies are necessary, the need for multiple positive selection schemes becomes critical. Numerous selectable markers have been described over the last 25 years. A hallmark of the most generally useful markers is easy selection in a wide number of cell types. This paper briefly reviews the spectrum of available selectable markers and describes some of the applications that have been found for these genes, particularly with respect to retrovirus-mediated gene transfer.

Chromosomal assignment of the human immunophilin FKBP-12 gene

FKBP-12 is the major T cell binding protein for the immunosuppressive drugs FK506 and rapamycin. It is a member of the immunophilin family of proteins which are believed to play a role in immunoregulation and basic cellular processes involving protein folding and trafficking. The chromosomal assignment of the human FKBP-12 gene was determined by using the polymerase chain reaction to amplify an intron-containing region of the gene in purified DNA isolated from 42 human-rodent somatic cell hybrids. The results of this analysis indicated that the FKBP-12 gene resides on human chromosome 20.

An efficient technique for obtaining sequences flanking inserted retroviruses

Genomic mapping studies frequently employ retrovirus-mediated transfer of dominant selectable markers to specific target chromosomes. DNA probes containing sequences adjacent to inserted proviruses are valuable mapping tools in such studies. We have implemented a strategy for amplification of chromosomal sequences flanking the 5' LTR of MoMuLV-based vectors. Probes derived from these amplification products successfully differentiated murine versus human proviral localization in retrovirus-infected mouse-human chromosome 17q hybrid cells.

Mapping the human CAS2 gene, the homologue of the mouse brown (b) locus, to human chromosome 9p22-pter

Melanin biosynthesis is a multistep process with the first step being the conversion of L-tyrosine to L-Dopa catalyzed by the enzyme tyrosinase. The enzymes which catalyze the other steps of melanogenesis are not known. One murine pigmentation gene, the brown (b) locus, when mutated, leads to a brown or hypopigmented coat. The b-locus protein has been shown to display catalase activity. The human b-locus, therefore, is designated as CAS2. We used the mouse b-locus cDNA to isolate the human homologue, which in turn, was used to map the CAS2 locus to a human chromosome. The potential CAS2 protein codes for 527 amino acids containing a putative signal sequence and transmembrane domain. The CAS2 protein has primary and probably secondary structures similar to human tyrosinase. The CAS2 was mapped to human Chromosome 9 by somatic cell hybridization and, more specifically, to 9p22-pter by in situ hybridization. The assignment of CAS2 on the human Chromosome 9 extends this region of known homology on mouse Chromosome 4.

Organization and chromosomal localization of the human platelet-derived endothelial cell growth factor gene

Human platelet-derived endothelial cell growth factor (hPD-ECGF) is a novel angiogenic factor which stimulates endothelial cell growth in vitro and promotes angiogenesis in vivo. We report here the cloning and sequencing of the gene for hPD-ECGF and its flanking regions. This gene is composed of 10 exons dispersed over a 4.3-kb region. Its promoter lacks a TATA box and a CCAAT box, structures characteristic of eukaryotic promoters. Instead, six copies of potential Sp1-binding sites (GGGCGG or CCGCCC) were clustered just upstream of the transcription start sites. Southern blot analysis using genomic DNAs from several vertebrates suggested that the gene for PD-ECGF is conserved phylogenetically among vertebrates. The gene for hPD-ECGF was localized to chromosome 22 by analysis of a panel of human-rodent somatic cell hybrid lines.

Organization and chromosomal localization of the human platelet-derived endothelial cell growth factor gene

Human platelet-derived endothelial cell growth factor (hPD-ECGF) is a novel angiogenic factor which stimulates endothelial cell growth in vitro and promotes angiogenesis in vivo. We report here the cloning and sequencing of the gene for hPD-ECGF and its flanking regions. This gene is composed of 10 exons dispersed over a 4.3-kb region. Its promoter lacks a TATA box and a CCAAT box, structures characteristic of eukaryotic promoters. Instead, six copies of potential Sp1-binding sites (GGGCGG or CCGCCC) were clustered just upstream of the transcription start sites. Southern blot analysis using genomic DNAs from several vertebrates suggested that the gene for PD-ECGF is conserved phylogenetically among vertebrates. The gene for hPD-ECGF was localized to chromosome 22 by analysis of a panel of human-rodent somatic cell hybrid lines.

Characterization of somatic cell hybrids by bivariate flow karyotyping and fluorescence in situ hybridization

We report on the use of flow karyotyping and fluorescence in situ hybridization (FISH) to characterize the human chromosomes in somatic cell hybrids. The identity, DNA content, and relative frequency of human chromosomes are derived from flow karyotypes, i.e., measurements of Hoechst and chromomycin fluorescence intensities of chromosomes by dual beam flow cytometry. Chromosome integrity is assessed by comparing the peak position of a human chromosome in the flow karyotypes of a hybrid cell line and its human donor. When human donor cells are unavailable, the peak position of a human chromosome in a hybrid line is compared to the range of peak positions among normal individuals. The relative frequency of human chromosomes in subclones or hybrids grown in culture is monitored using the volumes of peaks in flow karyotypes. FISH with biotinylated human genomic DNA or chromosome-specific repeat sequence as probe is used in conjunction with flow karyotyping to confirm the number of human chromosomes in hybrids. Some small rearrangements are detected by flow karyotyping and not by FISH. On the other hand, translocations between human and rodent chromosomes are detected by FISH and not always by flow karyotyping. Flow karyotyping and FISH were used to characterize over 100 hybrid lines donated by other laboratories. A hybrid set useful for the construction of chromosome-enriched gene libraries is presented. In this set, each of the 24 human chromosome types is present and intact, as judged by these techniques, in a line containing little or no other human material.

Stem cell factor (SCF), a novel hematopoietic growth factor and ligand for c-kit tyrosine kinase receptor, maps on human chromosome 12 between 12q14.3 and 12qter

Recently a novel hematopoietic growth factor, stem cell factor (SCF), was cloned and demonstrated to be the ligand for the c-kit tyrosine kinase receptor. In the mouse, SCF is encoded by Sl (steel), a gene critical to the development of several distinct cell lineages during embryonic life and which has important effects on hematopoiesis in the adult animal. The Sl/SCF locus maps to the distal region of mouse chromosome 10, in the vicinity of genes that have been mapped to human chromosome 12. Here we report the use of somatic cell hybrid lines to localize SCF to the long arm of human chromosome 12, between 12q14.3 and 12qter. In addition to localizing the Sl homolog in man, these data provide further evidence for the conservation of synteny between the long arm of human chromosome 12 and the distal end of mouse chromosome 10.

"PCR-karyotype" of human chromosomes in somatic cell hybrids

Amplification of human DNA sequences in 16 monochromosomal somatic cell hybrids containing different human chromosomes were performed by the polymerase chain reaction (PCR) using primer directed at human-specific regions of Alu or L1, the two major classes of interspersed repetitive sequences (IRS-PCR). A chromosome-specific pattern of amplification products was observed on agarose gels run with ethidium bromide, producing a "PCR-karyotype." This simple gel analysis provides a rapid method for identifying and monitoring the human chromosomal content of monochromosomal somatic cell hybrids without conventional cytogenetic analysis. Hybrids containing multiple human chromosome produce complex gel patterns, but identification of chromosome content can be achieved by hybridization of PCR products against a reference panel of monochromosomal or highly reduced hybrids representing each human chromosome. This dot-blot method also enables identification of human marker chromosomes or translocated pieces in hybrids that are not identifiable by cytogenetic methods. These IRS-PCR methods should greatly reduce the need for more laborious cytogenetic, isozyme, and Southern blot characterizations of human-rodent cell hybrids.

Human chromosome 12 encodes a species-specific factor which increases human immunodeficiency virus type 1 tat-mediated trans activation in rodent cells

The human immunodeficiency virus type 1 (HIV-1) tat protein functions at a much lower level in rodent cells than in human cells. This species-specific difference in trans activation appears to be due to the lack of a functional homolog of a human cofactor for tat in rodent cells. Using HIV-1 long terminal repeat-driven human growth hormone as a reporter plasmid, we found that the tat-mediated trans activation functions at a level 5- to 20-fold lower in rodent cells than in human cells. Stable rodent-human hybrid cells containing only human chromosome 12 support a dramatically higher degree of trans activation. Thus, human chromosome 12 encodes a species-specific HIV-1 tat cofactor which, at least partially, restores high levels of tat-mediated trans activation. Chromosome 6 also appears to provide an additional factor which enhances HIV-1 tat-mediated trans activation in murine cells.

Monochromosomal mouse microcell hybrids containing inserted selectable neo genes

Normal mouse fibroblasts at early passage levels were used as a starting material to construct mouse-hamster microcell hybrids (MCH). The neor gene, carried on the pSV2neo and pZIP-NeoSV(X)1 plasmids, was introduced into the mouse fibroblasts by gene transfection and retroviral infection, respectively, prior to microcell hybridization into the E36 Chinese hamster cell line. In total about 180 MCH clones were isolated and their amount of mouse DNA was estimated by dot-blot analysis. About 50% of the transfection based hybrids (T-hybrids) showed signals indicating one mouse chromosome, less than 10% more than one mouse chromosome, and the remaining clones contained only subchromosomal amounts of mouse DNA. In the infection-based hybrid series (I-hybrids) more than 95% showed only subchromosomal mouse DNA content. Chromosomal integration analysis verified the presence of neor insertions in all 42 hybrid clones analyzed. C-banding analysis verified 14 of 15 hybrids scored as monochromosomals on dot blots. Chromosome fragmentation in T-type MCH was found to be (1) nonrandom, preferentially occurring in MCH derived from certain transfectants, (2) late in clonal establishment, and (3) essentially not related to prolonged cultivation in vitro. Once established, most T-type MCH clones including mono- and subchromosomal hybrids were essentially stable during prolonged cultivation. In contrast MCH initially containing several mouse chromosomes tend to lose the nonselectable ones during prolonged cultivation. In total we estimate the number of independent monochromosomal MCH derived in this study to more than 30.