A dual-color FISH framework map for the characterization of the Sai1 tumor suppression region on rat chromosome 5.

The analysis of cell hybrids between malignant mouse hepatoma cells and normal rat fibroblasts has previously demonstrated the critical role of a deletion in rat chromosome 5 (RNO5) that was related to an anchorage independent phenotype. Those hybrids that were anchorage independent displayed loss of the entire RNO5 or an interstitial deletion in RNO5. These findings suggested that a putative tumor suppressor gene, Sai1 (suppression of anchorage independence 1), was located within the deleted region. To explore the molecular basis of the tumor suppressor activity of the Sai1 region, we analyzed the RNO5q23-q36 region with several genes and microsatellite markers that could be assigned to the region, as well as with new markers derived by representational difference analysis (RDA) or by microdissection. Dual-color FISH was used to construct a detailed physical map of the entire RNO5. These new data can be used to connect the physical and linkage maps in the rat, as well as to identify the details of the comparative map with other mammalian species including humans and mice. Using as FISH reagents genomic YAC, P1, or phage lambda clones corresponding to RNO5 markers, the order and unique positions of 18 markers could be established. The map provided a framework for the detailed characterization of the deletion found in anchorage independent hybrids. All markers within the bands RNO5q31.3-q35 were shown to be lost, including known cancer-related genes such as Ifna (5q32), Cdkn2a, -b (5q32), Jun (5q34), and Cdkn2c (5q35). However, the aberration in the deletion chromosome turned out to be more complex than originally thought in that we detected the presence of a paracentric inversion in addition to a deletion. The inversion led to the juxtaposition of the gene markers Tal2 (5q24.1) and Cd30lg (5q24.3). The framework map will provide the basis for the detailed physical YAC clone contig mapping of this region, and facilitate the identification and characterization of the Sai1 locus.

Analysis of mechanisms and frequency of CDKN2A/B gene loss during progression of RAS-transformed rat embryo fibroblast clones.

Rat embryo fibroblasts (REFs) are inefficiently transformed by RAS-oncogenes. Induction of p16INK4A expression by RAS has been suggested to contribute to this resistance. Glucocorticoid hormones, (DEX), enhance REF transformation by RAS and facilitates the isolation of transformed and immortal cell lines. We show that DEX induced cell proliferation is paralleled by a decrease in Cdkn2a gene transcripts, suggesting a mechanism for hormone promotion. The mechanisms of progression into hormone independent cell lines were examined. Twenty-two of 30 clones which reached a population size of approximately 10(6) cells could be established as cell lines. All lines studied showed homozygous deletions of the Cdkn2 loci (Cdkn2a and Cdkn2b) on RNO5. LOH was found for all RNO5 genetic markers examined in 7 of 19 cell lines, suggesting non-disjunction events. In the remaining 12 cell lines, both copies of Cdkn2 appeared to be lost by deletions/rearrangements, some of which could by demonstrated by karyotype analysis. We conclude that (i) clonal expansion of RAS-transfected REF by DEX is paralleled by down-regulation of Cdkn2a expression; (ii) homozygous deletion of Cdkn2 were estimated to occur at a frequency of 2 x 10(-8)/cell/generation or higher, and (iii) deletion/rearrangements and nondisjunction appear to be the main mechanisms leading to deletion of Cdkn2.

Codeletion of the JUN proto-oncogene and the CDKN2A tumor-suppressor gene in HRAS-transformed rat embryo fibroblast cell lines.

The cyclin kinase inhibitor p16, encoded by the CDKN2A gene, suppresses the transformation of mouse embryonic fibroblasts by oncogenic RAS. In contrast, the c-JUN transcription factor (a major component of AP-1) has been suggested to be required for RAS transformation of rodent fibroblasts. The CDKN2A gene and the JUN proto-oncogene have both been mapped to rat chromosome band 5q31-33. We here show that both copies of the CDKN2A gene are deleted in four of eight transformed cell lines derived from the transfection of rat embryo fibroblasts (REF) with HRASVAL12. In two cell lines, the homozygous deletions involved a larger area on 5q31-33, which included the JUN proto-oncogene. JUN-defective cells showed high AP-1 binding activity. Both AP-1 binding activity and stromelysin (transin) mRNA expression were found to be RAS-dependent in one of the JUN-defective cell lines. The finding of deletions of the CDKN2A gene in RAS-transformed REF cell lines is consistent with the concept that CDKN2A suppresses transformation by RAS. The occasional concomitant loss of the adjacent JUN proto-oncogene does not prevent establishment of transformed and tumorigenic cell lines.

Isolation of DNA markers for the rat Sai 1 gene for suppression of anchorage independence by using representational difference analysis.

We have applied the representational difference analysis (RDA) to isolate genetic markers for a deletion on the rat chromosome RNO5q22-33. This deletion occurred in anchorage independent sublines of a normal rat fibroblast x mouse hepatoma cell hybrid (BS181) (Islam 1989). Normal rat tissue DNA provided the "tester" and the BS181 hybrid DNA the "driver" in the RDA hybridization/selection reactions. Out of twelve RDA derived DNA sequences that were analyzed in detail using a rat X mouse cell hybrid panel for chromosome mapping, nine (75%) were found to represent RNO5 deletions, whereas the other three were new RFLPs mapping to other chromosomes. In two cases, the RDA sequences were also analyzed by fluorescence in situ hybridization (FISH) and found to give distinct signals in the RNOq22-33 region. This result emphasizes teh significance of the previous cytogenetic analysis of this hybrid, which indicated the presence of a gene for the suppression of anchorage independence, Sai 1, in this deletion region. The RDA derived sequences isolated by this work will provide a valuable source of new genetic markers for the further detailed analysis of the Sai 1 deletion region.

Physical map of small cell lung cancer deletion region on short arm of human chromosome 3 (3p13-22) based on radiation fusion hybrid analysis.

Deletion of DNA sequences from various regions of the short arm of human chromosome 3 (3p13-14, 3p21, and 3p25) has been observed during the development of a variety of solid tumors, including lung and renal cell carcinomas. In this study we have used a set of radiation fusion hybrids to generate a physical map of chromosome 3p to orient the search for putative tumor suppressor genes. Eighty-six human-hamster radiation fusion hybrids were screened on Southern blots for the retention of 55 human chromosome 3p DNA markers. The high marker density enabled us to identify a set of successively overlapping chromosome fragments in the 3p13-22 area guided by eight markers with previously known order. Twenty-four map intervals were suggested using breakpoints determined by partial fragment overlaps. The final order between the markers derived is consistent with previous information about localizations for 26 of the markers to three larger cytogenetic intervals.

Identification of human chromosome region 3p14.2-21.3-specific YAC clones using Alu-PCR products from a radiation hybrid.

Deletion of DNA sequences from at least three different regions on the short arm of human chromosome 3 (3p13-14, 3p21 and 3p25) are frequently observed during the development of many solid tumors, including lung cancers and renal cell carcinomas. In order to physically characterize the 3p21 region, we previously identified a radiation fusion hybrid that contained about 20 megabases of DNA from chromosome region 3p14.2-p21.3. In this study total Alu-PCR products from this hybrid were used as a probe to isolate 86 yeast artificial chromosomes (YAC) clones from a 620-kb average insert YAC library (ICRF). Sixty-nine Alu-PCR markers, generated from the YACs, and seven PCR primers were used to screen for overlaps between individual clones. Seven contigs were identified encompassing 32 YAC clones. Based on previous information about localization of the PCR primers, the three largest contigs could be assigned to smaller subregions between 3p14.2 and 3p21.3. By this work a large proportion of the 3p14.2-21.3 region is covered with large-insert YAC clones.

Radiation hybrids for the proximal long arm of the X chromosome and their use in the derivation of an ordered set of cosmid markers from a defined subregion in proximal Xq13.1.

We have defined a radiation hybrid panel for Xq11-q22 characterized with 20 DNA markers and shown how the panel can be used in conjunction with Alu-PCR and a gridded X-specific cosmid library to isolate cosmids from a preselected subregion. We used Alu-PCR products derived from two radiation hybrids, IHB2-B30 and IHB1-A12, sharing a segment in proximal Xq13.1, containing DXS453 to CCG1, as the only human component in common. Used as probes, these Alu-PCR products identified 39 cosmids on the gridded X-cosmid libraries that were positive for both probes. The target specificity of the derived cosmids was very high, 11 of 13 cosmids tested mapped to the region of fragment overlap in the hybrids, as was determined by two translocation breakpoints bordering most of the target interval. Accounting for a redundancy of four in the libraries, the isolated 39 cosmids should correspond to about 10 independent loci derived from the region of fragment overlap defined by these radiation hybrids. In addition, a subset of five radiation hybrids having breakpoints in the target region could be used to further subdivide the 11 cosmids into an ordered set of five submapping intervals of Xq13.1.

The isolation of evolutionarily conserved Eag I end-clones from mouse chromosome 17 using cloned DNA.

To isolate DNA markers from mouse chromosome 17, a genomic phage library was constructed from the mouse-hamster CMGT cell hybrid RcE-B52. This hybrid contains a chromosomal fragment from the distal end/flanking region of the t complex on mouse chromosome 17. Recombinants of mouse origin were identified by using a panel of mouse-specific repetitive sequences as a probe. A total of 1,500 mouse phage recombinants were isolated. These were found to represent 250-300 individual recombinants, comprising about 4 Mbp of cloned mouse DNA. The pooled mouse recombinant phages were used to construct an Eag I end-library. This was achieved by the specific insertion of a marker plasmid in Eag I recognition sites when present in the mouse inserts of the recombinant phages. The Eag I end-fragments were subsequently subcloned using a simple procedure taking advantage of the inserted plasmid. A total of 56 individual Eag I end-fragments were identified. These were found to contain recognition sites for rare cutting enzymes at high frequency. A large proportion (73%) were found to be evolutionarily conserved in human DNA. Furthermore, a significant fraction of these fragments, two of six tested, appears to detect specific cDNAs in a 8.5-day mouse embryo cDNA library.

Different pathways for chromosomal integration of transfected circular pSVneo plasmids in normal and established rodent cells.

The chromosomal integration of transfected circular plasmid pSV2neo molecules was investigated in normal and established mammalian fibroblasts, including two secondary cultures of normal mouse fibroblast lines, one established mouse-hamster hybrid cell line, R44, and the human fibrosarcoma line, HT1080. The physical organization of the integrated molecules was studied by restriction analysis. The results showed that whereas the normal fibroblasts predominantly integrated one head-to-tail partial dimeric molecule, the established cells predominantly integrated distinctly different molecular forms including deleted monomeres (HT1080) and various complex concatemeric molecules (R44), and frequently at more than one chromosomal site (R44). We also constructed a head-to-tail dimeric version of the plasmid, which in the case of the normal fibroblasts again integrated as a partial dimeric molecule in at least 50% of these cells. This result excluded the possibility that the normal mouse transfectants were selected for the integration of two functional neo genes. Thus, it is concluded that the distinctly different molecular forms integrated in normal and established cells demonstrate the operation of different integration pathways, the possible nature of which is discussed.

Radiation fusion hybrids for human chromosomes 3 and X generated at various irradiation doses.

We have used a gamma-irradiation (2.5-25 krads) cell fusion procedure to generate human-hamster somatic cell hybrids (IHB, irradiated human fragments in B14-150 cells), retaining small fragments derived from human chromosomes 3 and X. By using Alu-element mediated PCR amplification and dot-blot hybridization with human alphoid or total human DNA as probes, 86 positive hybrids were identified and selected for further analysis. Nonisotopic fluorescence in situ hybridization (FISH) with human DNA in a set of eight hybrids demonstrated the presence of from one to eight human fragments per cell independent of irradiation dose. In contrast, a significant dose-dependent variation of fragment sizes was shown in the analysis of the 86 hybrids with markers previously mapped to 3p (seven markers) and to Xq (21 markers). Using the Xq27-28 region as a model, 40% of the hybrids generated at 5 krads or less were found to have retained fragments in the range of 3-30 Mb, 10% retained the whole chromosome arm, and the remaining 50% retained fragments of less than 2-3 Mb. The proportion of fragments of 3 Mb or larger decreased rapidly at higher irradiation doses and was very low (less than 6%) in hybrids generated at 25 krads. Upon further characterization, the 86 hybrids analyzed here will provide a mapping panel for the entire chromosomes 3 and X with an estimated resolution in the range of 1-2 Mb on average, a size range amenable to PFGE and YAC contig mapping.

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.

Construction of microcell hybrid panel containing different neo gene insertions in mouse chromosome 17 used for chromosome-mediated gene transfer.

A panel of four microcell hybrids representing different sites of insertion of the exogenous neo gene into mouse chromosome 17 has been constructed. These constructions were based on a cotransfer of mouse chromosome 17 and neomycin resistance generated in a stepwise procedure involving (1) random insertion of the neo gene into a primary cell hybrid containing mouse chromosome 17 in a hamster cell background, (2) microcell-mediated chromosome transfer (MMCT) to segregate mouse and hamster chromosomes, and (3) identification of the mouse chromosome containing cells using a novel cell dotting procedure for mass screening at the cell colony level by molecular hybridization. Using this panel of four microcell hybrids for chromosome mediated gene transfer (CMGT), we obtained one transformant containing a chromosome fragment derived from the t-complex region located on mouse chromosome 17. It is concluded that the specific chromosome based procedure used here to generate CMGT transfectants may provide a general means to produce large numbers of transfectants containing megabase fragments covering, in principle, all regions of a given chromosome.

Molecular clones of the mouse t complex derived from microdissected metaphase chromosomes.

Fragments of the proximal half of mouse chromosome 17 including the t-complex region were microdissected from metaphase spreads. DNA was isolated from a pool of such fragments, and was cloned on microscale. Individual clones were used to probe genomic digests of DNA from a pair of Chinese hamster cell lines with or without mouse chromosome 17, and livers of congenic inbred lines of mice carrying wild-type and/or t-haplotype forms of chromosome 17. The data obtained indicate that 95% of the low copy number microclone inserts recognize DNA sequences present on mouse chromosome 17. It has been possible to use one-third of these clones to identify restriction-fragment-length polymorphisms between wild-type and t-haplotype DNA on a congenic background. These results demonstrate that these clones have been derived from the t-complex or regions closely linked to it. Clones of this type should provide starting points for a molecular analysis of this region of the mouse genome.

Evidence for a relationship between longevity of mammalian species and life spans of normal fibroblasts in vitro and erythrocytes in vivo.

The replicative life spans of mammalian fibroblasts in vitro were studied in a number of cell cultures representing eight species. Emphasis was placed on determining the population doubling level at which phase III (a period of decrease in the rate of proliferation) and chromosomal alterations occur. All the cell cultures studied went through a growth crisis, a period of apparent growth cessation lasting for at least 2 weeks. In most cultures, the crisis represented the end of their replicative capacities, but in some cultures cell proliferation was resumed after the crisis. A predominantly diploid chromosome constitution (more than 75%) was demonstrated prior to the growth crisis. In cultures in which cell proliferation was resumed after the crisis, a nondiploid constitution prevailed in all cases except the rat (with 90% or more diploid cells all the time). The growth crisis occurred at population doubling levels that were characteristic for the species and was shown to be related to the species' maximal life span by a strict power law, being proportional to the square root of the maximal life span. Based on data in the literature, the same relationship was also valid for the lifespans of circulating mammalian erythrocytes in vivo. These results may indicate the prevalence of a common functional basis regulating the life span of fibroblasts and erythrocytes and thus operating in replicative as well as postmitotic cells in vitro and in vivo.

Ageing and the fusion sensitivity potential of human cells in culture: relation to tissue origin, donor age, and in vitro culture level and condition.

Cell fusion was induced by inactivated Sendai virus in different human diploid cell lines. These were derived from the kidney, lung or skin originating from embryos or adult donors and representing predominantly epithelioid cells (kidney) and fibroblastic cells (lung and skin). The fusion sensitivity (FS) potentials of these cell lines were determined and related to various aspects of cell ageing. In case of the fibroblastic lines, an inverse relation was demonstrated both to the culture age in vitro and to the donor age. The FS potential of embryonal fibroblasts decreased some 40-50% during the in vitro cultivation. In comparison to exponentially growing fibroblasts, the FS potentials were higher in cells in the stationary phase of growth. This was shown to correlate well with the fact that the life-span in calendar time also increased in cultures predominantly grown in the stationary phase. In the case of the kidney cells, the FS potentials were some 50% higher than those of fibroblasts. Since the cellular manifestation of the FS potential most likely primarily resides in the cell membrane-cytoskeleton structure, the results emphasize the importance of this system in relation to ageing.

Quantitative cell fusion: the fusion sensitivity (FS) potential.

The dose response of Sendai virus-induced cell fusion was studied in 10 mammalian cell lines, comprising 5 continuous and 5 diploid cell lines originating from 5 species. The extent of fusion was calculated using a parameter directly proportional to the number of fusion events (t-parameter). At lower levels of fusion the dose response was found to be based on the same simple kinetic rules in all cell lines and was defined by the formula: t = FS . FAU/(I + FS . FAU), where FS (fusion sensitivity) is a cell-specific constant of the fusion rate and FAU (fusion activity units) is the virus dose. The FS potential of a cell line was determined as the linear regression coefficient of the fusion index (t/(I - t)) on the virus dose. At higher levels of fusion, when the fusion extent reached cell-line-specific maximal levels, the dose response was not as uniform. In general, and particularly in the cases of the diploid cell lines, these maximal levels were directly proportional to the FS potentials. Thus, it was concluded that the FS potential is the basic quantitative feature, which expresses the cellular fusion efficiency. The fact that FS varied extensively between cell lines, but at the same time apparently followed certain patterns (being higher in continuous compared to diploid cell lines and being related to the species of origin of the cells), emphasizes it biological significance as well as its possible usefulness in studies of the efficiency of various molecular interactions in the cell membrane/cytoskeleton system.

Quantitative cell fusion: derivation and application of theoretical models.

Cell fusion experiments were made on ten cell lines representing seven mammalian species, using inactivated Sendai virus. The extent of fusion was determined microscopically and tabulated as frequencies of cell with different numbers of nuclei. Expected distributions were derived theoretically under certain assumptions concerning the fusion process. A random model was assumed according to which the tendency to fuse depends only on the cell size, expressed as the number of nuclei present in the cell. Three distributions were derived, which were referred to as the simple, additive, and multiplicative models. The additive model pertained to fusions made in cell suspensions and the multiplicative one mainly to fusions in fibroblast monolayers.