Involvement of nucleotide excision repair in a recombination-independent and error-prone pathway of DNA interstrand cross-link repair.

DNA interstrand cross-links (ICLs) block the strand separation necessary for essential DNA functions such as transcription and replication and, hence, represent an important class of DNA lesion. Since both strands of the double helix are affected in cross-linked DNA, it is likely that conservative recombination using undamaged homologous regions as a donor may be required to repair ICLs in an error-free manner. However, in Escherichia coli and yeast, recombination-independent mechanisms of ICL repair have been identified in addition to recombinational repair pathways. To study the repair mechanisms of interstrand cross-links in mammalian cells, we developed an in vivo reactivation assay to examine the removal of interstrand cross-links in cultured cells. A site-specific psoralen cross-link was placed between the promoter and the coding region to inactivate the expression of green fluorescent protein or luciferase genes from reporter plasmids. By monitoring the reactivation of the reporter gene, we showed that a single defined psoralen cross-link was removed in repair-proficient cells in the absence of undamaged homologous sequences, suggesting the existence of an ICL repair pathway that is independent of homologous recombination. Mutant cell lines deficient in the nucleotide excision repair pathway were examined and found to be highly defective in the recombination-independent repair of ICLs, while mutants deficient in homologous recombination were found to be proficient. Mutation analysis of plasmids recovered from transfected cells showed frequent base substitutions at or near positions opposing a cross-linked thymidine residue. Based on these results, we suggest a distinct pathway for DNA interstrand cross-link repair involving nucleotide excision repair and a putative lesion bypass mechanism.

Role of the nucleotide excision repair gene ERCC1 in formation of recombination-dependent rearrangements in mammalian cells.

Spontaneous recombination between direct repeats at the adenine phosphoribosyltransferase (APRT) locus in ERCC1-deficient cells generates a high frequency of rearrangements that are dependent on the process of homologous recombination, suggesting that rearrangements are formed by misprocessing of recombination intermediates. Given the specificity of the structure-specific Ercc1/Xpf endonuclease, two potential recombination intermediates are substrates for misprocessing in ERCC1(-) cells: heteroduplex loops and heteroduplex intermediates with non-homologous 3' tails. To investigate the roles of each, we constructed repeats that would yield no heteroduplex loops during spontaneous recombination or that would yield two non-homologous 3' tails after treatment with the rare-cutting endonuclease I-SCE:I. Our results indicate that misprocessing of heteroduplex loops is not the major source of recombination-dependent rearrangements in ERCC1-deficient cells. Our results also suggest that the Ercc1/Xpf endonuclease is required for efficient removal of non-homologous 3' tails, like its Rad1/Rad10 counterpart in yeast. Thus, it is likely that misprocessing of non-homologous 3' tails is the primary source of recombination-dependent rearrangements in mammalian cells. We also find an unexpected effect of ERCC1 deficiency on I-SCE:I-stimulated rearrangements, which are not dependent on homologous recombination, suggesting that the ERCC1 gene product may play a role in generating the rearrangements that arise after I-SCE:I-induced double-strand breaks.

Proviral structure and differentiation antigen phenotype of spontaneous and chemically induced AKR lymphomas.

AKR mice develop spontaneous thymomas after 6 months of age due to a novel class of murine leukemia viruses that are generated by a series of genetic recombinations between endogenous proviral loci. AKR mice also are more susceptible to N-methyl-N-nitrosourea (MNU)-induced thymomas than are low-leukemia-incidence mouse strains. To determine whether virally and chemically induced lymphomagenesis proceeds by similar pathways in AKR mice, spontaneous and MNU-induced thymic lymphomas were analyzed for a DNA restriction linkage generated during spontaneous tumor development by recombination between envelope genes of endogenous murine leukemia proviral loci. DNA from spontaneous thymic lymphomas invariably contained a restriction fragment characteristic of recombinant murine leukemia virus etiology, while four of five MNU-induced thymic lymphomas did not show this restriction linkage. In addition, analysis of lymphocyte differentiation antigen profiles indicated that MNU-induced lymphomas represent a more immature stage of T-cell differentiation than the majority of spontaneous lymphomas. These data suggest that there are fundamental differences in the mechanisms of induction of virally and chemically induced thymic lymphomas in AKR mice.

Comparative structure and characterization of a CDKN2 gene in a Xiphophorus fish melanoma model.

We have cloned, sequenced, and characterized the RNA expression properties of a fish CDKN2 gene from Xiphophorus helleri and X. maculatus. This gene, termed CDKN2X, shows a high degree of amino acid sequence similarity to members of the mammalian CDKN2 gene family, which includes the tumor suppressor loci CDKN2A (P16) and CDKN2B (P15). Comparative sequence analysis suggests that fish CDKN2X is similarly related to all four mammalian gene family members, and may represent a descendant of an ancestral prototypic CDKN2 gene. CDKN2X was mapped to a region on autosomal Xiphophorus linkage group V (LG V) known to contain the DIFF gene that acts as a tumor suppressor of melanoma formation in X. helleri/X. maculatus backcross hybrids. Thus, CDKN2X may be a candidate for the tumor suppressor DIFF gene. Here we have sequenced CDKN2X in both Xiphophorus species and have characterized its expression in normal and melanotic tissues within control and backcross hybrid fish. A simultaneous expressional analysis of the Xmrk-2 tyrosine kinase receptor gene, which is strongly implicated in melanomagenesis in this system, was also performed. RT - PCR analyses revealed that both genes were highly expressed in melanomas. For CDKN2X, this result contrasts numerous findings in human tumors including human melanoma in which either CDKN2A (P16) deactivation or LOH was observed.

Loss of thymine dimers from mammalian cell DNA. The kinetics for antibody-binding sites are not the same as that for T4 endonuclease V sites.

Antiserum specific for thymine-containing dimers was used to assay DNA isolated from ultraviolet-irradiated cells following different repair periods. A 50% loss in antibody-binding sites was evident 1 h post-irradiation, and within 4 h 80% of the sites were removed. This result contrasts with data obtained with dimer-specific T4 endonuclease V and does not appear to be due to masking of the dimers by repair enzymes. T4 endonuclease V treatment of ultraviolet-irradiated DNA at 0 degree C resulted in conversion of the thymine dimers to apyrimidinic sites. This did not result in loss of antigenicity in either PM2 or CHO cell DNA. Likewise, treatment of ultraviolet-irradiated CHO cell DNA with T4 endonuclease at 37 degrees C did not change its antigenicity. These results suggest that aglycosylation of the dimers is not responsible for their inability to bind dimer-specific antibody 2-4 h post-irradiation. The possibility that T4 endonuclease V and the antiserum have different specificities for different dimers is discussed.

Identification and mapping of two divergent, unlinked major histocompatibility complex class II B genes in Xiphophorus fishes.

We have isolated two major histocompatibility complex (MHC) class II B genes from the inbred fish strain Xiphophorus maculatus Jp 163 A. We mapped one of these genes, designated here as DXB, to linkage group III, linked to a malic enzyme locus, also syntenic with human and mouse MHC. Comparison of genomic and cDNA clones shows the gene consists of six exons and five introns. The encoded beta1 domain has three amino acids deleted and a cytoplasmic tail nine amino acids longer than in other teleost class II beta chains, more similar to HLA-DRB, clawed frog Xela-F3, and nurse shark Gici-B. Key residues for disulfide bonds, glycosylation, and interaction with alpha chains are conserved. These same features are also present in a swordtail (Xiphophorus helleri) genomic DXB PCR clone. A second type of class II B clone was amplified by PCR from X. maculatus and found to be orthologous to class II genes identified in other fishes. This DAB-like gene is 63% identical to the X. maculatus DXB sequence in the conserved beta2-encoding exon and was mapped to new unassigned linkage group LG U24. The DXB gene, then, represents an unlinked duplicated locus not previously identified in teleosts.

Cloning and comparative sequence analysis of TP53 in Xiphophorus fish hybrid melanoma models.

We have cloned and sequenced the p53-encoding cDNA of green swordtail (X. helleri) and southern platyfish (X. maculatus). These two fish species are often used to produce hybrids that develop melanomas after genetic crossing. Computer translation of derived cDNA sequences revealed that p53 polypeptides from these two species are virtually identical, exhibiting only two conservative amino acid substitutions. TP53 mRNA expression was detected in virtually all tissues tested. Comparison of these fish p53 polypeptide sequences with those of other vertebrates, including other fishes, amphibians, and mammals, revealed that conservation is especially high in several previously defined protein domains. In addition, sequencing of the 3' TP53 genomic region of X. maculatus reveals similarity to the human TP53 locus in overall organization. Knowledge of the Xiphophorus TP53 sequences will allow assessment of mutational alterations within tumors generated from numerous fish genetic crosses.

Immunoprecipitation of pyrimidine(6-4)pyrimidone photoproducts and cyclobutane pyrimidine dimers in uv-irradiated DNA.

Biological studies suggest that a significant proportion of the cytotoxicity observed in mammalian cells after uv irradiation may be due to damage other than cyclobutane dimers in DNA. Although pyrimidine-pyrimidone (6-4) photoproducts have been implicated as major contributors to cell lethality, their induction has been measured at considerably less than cyclobutane pyrimidine dimers when measured by chromatographic techniques. Because the yield of (6-4) photoproducts may be reduced by their lability to extreme heat and pH, we have advised an alternative, immunological quantification which does not require DNA hydrolysis. Affinity-purified rabbit antisera were used to precipitate low molecular weight 32P-labeled PM2 DNA irradiated with increasing fluences of uv light. DNA of known molecular weight was used to determine rates of induction for antibody-binding sites associated with (6-4) photoproducts and cyclobutane dimers. These rates were calculated to be 0.6 (6-4) photoproducts and 1.2 cyclobutane dimers/10(8) Da/J/m2. At low uv fluences (6-4) photoproducts were induced at one-half the rate of cyclobutane dimers, whereas at higher fluences (6-4) photoproducts predominated.

Assignment of the TP53 orthologue to a new linkage group (LG XIV) in fish of the genus Xiphophorus (Teleostei: Poeciliidae).

Using a p53 encoding cDNA fragment of rainbow trout (Oncorhynchus mykiss) as probe, a lambda clone from a platyfish (Xiphophorus maculatus) genomic library was isolated. DNA sequencing of the insert from this clone revealed that it contained the highly conserved domains IV and V of the p53 polypeptide. To map the Xiphophorus p53 gene, joint segregation analysis of the inheritance of a PstI-generated DNA restriction fragment length polymorphism (RFLP) and the inheritance of 36 polymorphic protein and DNA markers was performed in backcross hybrids of X. clemenciae x (X. clemenciae x X. milleri) and X. helleri x X. (helleri x X. maculatus Jp 163 B) using Oncorhynchus cDNA and Xiphophorus genomic p53 probes, respectively. The p53-hybridizing sequence (TP53) was linked to the ACO1 (cytosolic aconitase) locus in both crosses, and defines a new Xiphophorus linkage group, designated LG XIV. This is the first mapping assignment of a known human tumor suppressor gene in fish. Since ACO1 is not linked with melanoma severity in X. helleri x X. maculatus Jp 163 A backcross hybrids, these data indicate that homozygosity for the X. helleri TP53 genotype in backcross hybrids of the cross type is not associated with genetically regulated malignant melanoma formation in the Gordon-Kosswig hybrid melanoma model.

Assignment of an erbB-like DNA sequence to linkage group VI in fishes of the genus Xiphophorus (Poeciliidae).

The inheritance of 23 protein polymorphisms was compared with the inheritance of a DNA restriction fragment length polymorphism (RFLP) of a strongly cross-hybridizing erbB-related sequence, epidermal growth factor receptor-like-1 (EGFRL1), in Xiphophorus clemenciae X X. milleri-derived backcross hybrids. Two polymorphic bands were noted in this cross with a v-erbB probe after PstI digestion: a 10-kilobase (kb) band in X. clemenciae and a 9-kb band in X. milleri. Joint segregation analysis of the RFLPs and protein polymorphisms indicate that this erbB-related sequence can be assigned to Xiphophorus linkage group VI, which also comprises genes coding for glutamine synthetase (GLNS), nucleoside phosphorylase-2 (NP2), and transferin (TF). We have designated this RFLP as alleles at a locus called EGFRL1 because of very strong cross-hybridization with the v-erbB probe, known to be homologous to the mammalian EGFR gene. This mapping assignment is the first autosomal linkage of an oncogene sequence reported in fish, which provide a large number of genetically controlled experimental tumor models.

The biology of the (6-4) photoproduct.

The (6-4) photoproduct is an important determinant of the lethal and mutagenic effects of UV irradiation of biological systems. The removal of this lesion appears to correlate closely with the early DNA repair responses of mammalian cells, including DNA incision events, repair synthesis and removal of replication blocks. The processing of (6-4) photoproducts and cyclobutane dimers appears to be enzymatically coupled in bacteria and most mammalian cell lines examined (i.e. a mutation affecting the repair of one lesion also often affects the other), although exceptions exist in which repair capacity may be evident for one photoproduct and not the other (e.g. UV61 and the XP revertant cell line). These differences in the processing of the two photoproducts in some cell lines of human and rodent origin suggest that in mammalian cells, different pathways for the repair of (6-4) photoproducts and cyclobutane dimers may be used. This observation is further supported by pleiotropic repair phenotypes such as those observed in CHO complementation class 2 mutants (e.g., UV5, UVL-1, UVL-13, and V-H1). Indirect data, from HCR of UV irradiated reported genes and the cytotoxic responses of UV61, suggest that the (6-4) photoproduct is cytotoxic in mammalian cells and may account for 20 to 30% of the cell killing after UV irradiation of rodent cells. Cytotoxicity of the (6-4) photoproduct may be important in the etiology of sunlight-induced carcinogenesis, affecting mutagenesis as well as tumorigenesis. The intricate photochemistry of the (6-4) photoproduct, its formation and photoisomerization, is in itself extremely interesting and may also be relevant to sunlight carcinogenesis. The data reviewed in this article support the notion that the (6-4) photoproduct and its Dewar photoisomer are important cytotoxic determinants of UV light. The idea that the (6-4) photoproduct is an important component in the spectrum of UV-induced cytotoxic damage may help clarify our understanding of why rodent cells survive the effects of UV irradiation as well as human cells, without apparent cyclobutane dimer repair in the bulk of their DNA. The preferential repair of cyclobutane dimers in essential genes has been proposed to account for this observation (Bohr et al., 1985, 1986; Mellon et al., 1986). The data reviewed here suggest that understanding the repair of a prominent type of noncyclobutane dimer damage, the (6-4) photoproduct, may also be important in resolving this paradox.

Inhibition of transient gene expression in Chinese hamster ovary cells by triplet-sensitized UV-B irradiation of transfected DNA.

The biological effectiveness of thymine-thymine cyclobutane dimers specifically induced by photosensitized ultraviolet-B irradiation was analyzed by host-cell reactivation of triplet-sensitized, UV-B irradiated plasmid pRSV beta gal DNA transfected into normal and repair-deficient Chinese hamster ovary cells. For comparison, pRSV beta gal DNA was also UV-C irradiated and transfected into the same cell lines. Ultraviolet endonuclease-sensitive site induction was determined after UV-C irradiation or acetophenone-sensitized UV-B irradiation of plasmid pRSV beta gal DNA. These data were used to calculate the number of cyclobutane pyrimidine dimers required to inactivate expression of the lacZ reporter gene in each irradiation condition. Transfection with UV-C-irradiated plasmid DNA resulted in a significantly greater reduction of reporter gene expression than did transfection with acetophenone-sensitized UV-B-irradiated pRSV beta gal DNA at equivalent induction of enzyme-sensitive sites. Since only a fraction of the inhibition could be accounted for by noncyclobutane dimer photoproducts, these results suggest that cytosine-containing pyrimidine cyclobutane dimers may be more effective than thymine-thymine dimers in inhibiting transient gene expression as measured in such host-cell reactivation experiments in mammalian cells.

Nonmammalian models for sunlight carcinogenesis: genetic analysis of melanoma formation in Xiphophorus hybrid fish.

Genetic hybrids of Xiphophorus fishes have been used for decades to study heritable melanoma formation. In these models, overexpression of pigmentation patterns from melanin-producing pigment cells can lead to genetically regulated melanoma formation in backcross hybrids. In the best studied of these models, the Gordon-Kosswig hybrid melanoma, tumors form spontaneously in all individuals of a subset of backcross hybrids between the platyfish Xiphophorus maculatus Jp 163 A and the swordtail species Xiphophorus helleri. Backcross hybrids susceptible to melanoma formation inherit a sex-linked oncogene, Xmrk, associated with the spotted dorsal (Sd) pigment pattern and have lost both copies of an autosomal gene, DIFF, from the X. maculatus parent. Spontaneous melanoma formation conforms to simple, two-gene Mendelian inheritance in which DIFF behaves as a recessive tumor suppressor gene. Recently, Xiphophorus hybrids in which melanomas can be induced by UV and near-UV visible light exposure have been described. We report here results of genetic linkage analysis of one of these Xiphophorus light-inducible hybrid melanoma models, in backcross hybrids between the two platyfish species X. maculatus Jp 163 B and Xiphophorus couchianus. Our linkage results provide the first estimate of recombination between the tumor suppressor locus, DIFF, and glycerate-2-dehydrogenase (GLYDH) in Xiphophorus linkage group V. Also, they demonstrate that DIFF regulates hyperplasia of spotted side (Sp) pigment cells in this hybrid model, analogous to its regulation of hyperplasia of Sd pigment cells in the "classical" Gordon-Kosswig hybrid. Joint segregation analyses of melanoma-bearing fish indicate that segregation of DIFF is genetically linked to melanoma induction by 405 nm light in this model but that induction of melanomas by UV wavelengths apparently does not depend on segregation of the DIFF locus.

Photoreactivation of cyclobutane dimers and (6-4) photoproducts in the epidermis of the marsupial, Monodelphis domestica.

Radioimmunoassays were used to investigate the repair of cyclobutane pyrimidine dimers and pyrimidine (6-4)pyrimidone photoproducts ((6-4] photoproducts) in the epidermis of the South American opossum, Monodelphis domestica. In the absence of photoreactivating light, both types of photodamage were excised with similar kinetics, 50% of the damage remaining 8 h after UV irradiation in vivo. Exposure of UV-irradiated skin to photoreactivating light resulted in removal of most of the cyclobutane dimers and an enhanced rate of (6-4) photoproduct repair. Photoenhanced excision repair of non-dimer damage increases the range of biologically effective lesions removed by in vivo photoreactivation.

Nucleotide excision repair proteins and their importance for radiation-enhanced transfection.

PURPOSE: Irradiated cells transfect more efficiently than unirradiated cells because of a radiation-induced increase in plasmid integration. However, the molecular mechanism is unclear. Because of recent observations that nucleotide excision repair (NER) proteins can be involved in certain types of recombination in yeast, it was hypothesized that NER proteins might play a role in this radiation-enhanced integration. MATERIALS AND METHODS: Hamster and human cells with inactivating mutations in NER genes were irradiated at doses from 0 to 6 Gy and then immediately transfected with a linearized selectable marker plasmid. Transfection-enhancement ratios (TERs) were calculated as the ratio of the number of drug-resistant colonies in unirradiated cells to the number of transfectants in irradiated cells, corrected for cytotoxicity from radiation. RESULTS: Transfection into unirradiated rodent cells was unaffected by NER mutation status. Transfection into unirradiated human cells, however, was increased by NER mutation. The TERs were 5 and 100 for CHO and primary human fibroblasts, respectively, after exposure of the cells to 6 Gy. Mutations in ERCC1, XPA, XPB, XPC, XPF, XPG and CSB dramatically reduced TER. Mutations in ERCC1, XPC, XPF, XPG and CSB suppressed transfection so that the TER was significantly below 1. CONCLUSIONS: The mechanism of radiation-enhanced plasmid integration was distinct from that of plasmid integration in unirradiated cells, and NER gene products were critical for enhanced integration to occur.

Transformation depending on intermolecular homologous recombination is stimulated by UV damage in transfected DNA.

DNA-mediated gene transfer (DMGT) was performed in DNA repair-proficient and UV-hypersensitive, repair-deficient Chinese hamster ovary (CHO) cell lines using the UV-irradiated thymidine kinase gene from herpes simplex virus (HSV-TK). Transformation frequencies in repair-deficient CHO cell lines declined relative to repair-proficient cells with increasing UV damage in transfected DNA; approximately 3-fold higher UV fluence was required to inactivate 50% of irradiated HSV-TK plasmid molecules in repair-proficient cells. In cotransfection experiments performed with pairs of HSV-TK plasmids containing linker insertion mutations in TK coding sequences, moderate UV damage in plasmid DNA enhanced the yield of TK+ transformants resulting from homologous recombination between HSV-TK sequences up to 4-fold. These results suggest that UV damage in DNA can stimulate transformation of mammalian cells dependent on intermolecular DNA homology.

Intermediate (6-4) photoproduct repair in Chinese hamster V79 mutant V-H1 correlates with intermediate levels of DNA incision and repair replication.

A DNA-repair mutant isolated from Chinese hamster V79 cells, V-H1, has been characterized as having only slightly reduced unscheduled DNA synthesis (UDS) and intermediate levels of DNA incision and repair replication after UV exposure. This observation was unexpected, since V-H1 has been shown by genetic complementation analysis to belong to the UV5 complementation class (i.e., class 2), exhibiting equivalent UV hypersensitivity and hypermutability as UV5 cells, which are defective in incision, UDS and repair replication. We have examined the repair of cyclobutane dimers and (6-4) photoproducts in V-H1 and V79 cells and shown that V-H1 cells are deficient in cyclobutane dimer repair, but exhibit intermediate (6-4) photoproduct repair, unlike UV5 cells which are completely deficient in (6-4) photoproduct repair. Our results confirm observations made in other UV-hypersensitive Chinese hamster cell mutants in CHO complementation class 2, and suggest that the gene affected in these mutants (ERCC2) may be involved in at least two distinct repair pathways in hamster cells.

UV mutagenesis, cytotoxicity and split-dose recovery in a human-CHO cell hybrid having intermediate (6-4) photoproduct repair.

Somatic cell hybrids constructed between UV-hypersensitive Chinese hamster ovary cell line UV20 and human lymphocytes were used to examine the influence of a human DNA repair gene, ERCC1, on UV photoproduct repair, mutability at several drug-resistance loci, UV cytotoxicity and UV split-dose recovery. In hybrid cell line 20HL21-4, which contains human chromosome 19, UV-induced mutagenesis at the APRT, HPRT and Na+/K+-ATPase loci was comparable to that in repair-proficient CHO AA8 cells, whereas cell line 20HL21-7, a reduced human-CHO hybrid not containing human chromosome 19, exhibited a hypermutable phenotype at all 3 loci indistinguishable from that of UV20 cells. The response of 20HL21-4 cells to UV cytotoxicity reflected substantial but incomplete restoration of wild-type UV cytotoxic response, whereas responses of UV20 and 20HL21-7 cell lines to UV cytotoxicity were essentially the same, reflecting several-fold UV hypersensitivity. Repair of UV-induced (5-6) cyclobutane dimers and (6-4) photoproducts was examined by radioimmunoassay; (6-4) photoproduct repair was deficient in UV20 and 20HL21-7 cell lines, and intermediate in 20HL21-4 cells relative to wild-type CHO AA8 cells. UV split-dose recovery in 20HL21-4 cells was also intermediate relative to AA8 cells. These results show that the human ERCC1 gene on chromosome 19 is responsible for substantial restoration of UV survival and mutation responses in repair-deficient UV20 cells, but only partially restores (6-4) UV photoproduct repair and UV split-dose recovery.

Aquaria fish models of human disease: reports and recommendations from the working groups.

On September 21-24, 2000, the National Cancer Institute, Southwest Texas State University, and the Roy and Joan Mitte Foundation sponsored an international conference entitled "Aquaria Fish Models of Human Disease" at Southwest Texas State University (SWT), San Marcos, Texas, USA. Over 100 scientists, representing various fish model systems, participated in four roundtable working groups. We considered the first step in promoting the exciting research with fish models was to unify the efforts within this scientific community towards accomplishing specific goals. With this objective in mind, the following four working groups were convened: (1) fish cancer models: sustenance and enhancement; (2) fish genomics and transgenics: resources and technology; (3) fish pathology: standards for tumor pathology classification; and, (4) resources underpinning aquaria fish research. Each working group was charged with preparing a report of their discussions with recommendations on how researchers and funding agencies might best direct and strengthen research support to ensure a healthy future for such work. Included are the final reports from these working groups, together with a brief summary of the discussions held during the sessions and the consensus recommendations from each group.

Genetic analysis of susceptibility to spontaneous and UV-induced carcinogenesis in Xiphophorus hybrid fish.

Xiphophorus interspecies hybrids provide genetically controlled models of tumor formation. Spontaneous melanomas form in first-generation backcross (BC(1)) hybrids produced from backcrossing F(1) hybrids derived from the platyfish X. maculatus Jp 163 A and the swordtail X. helleri to the X. helleri parental strain (the Gordon-Kosswig hybrid cross). Nodular melanomas originate in the dorsal fin from cells constituting the spotted dorsal (Sd) pigment pattern. A parallel genetic cross, with X. maculatus Jp 163 B, exhibits the spotted side (Sp) pigment pattern instead of Sd, and produces BC(1) hybrids exhibiting a much lower frequency of spontaneous melanoma formation. These hybrids are susceptible to melanoma development if irradiated with UV light as fry. Other hybrids involving these two strains of X. maculatus and different swordtail and platyfish backcross parents also have been investigated as potential tumor models, and show differing susceptibilities to UV-induced and spontaneous melanomas. Genotyping of individual BC(1) hybrids from several Xiphophorus crosses has implicated a locus, CDKN2X (a Xiphophorus homologue of the mammalian CDKN2 gene family, residing on Xiphophorus linkage group V), in enhancing pigmentation and the susceptibility to spontaneous and UV-induced melanoma formation in BC(1) hybrids from some crosses, but not others. Homozygosity for X. helleri and X. couchianus CDKN2X alleles in BC(1) hybrids can predispose individuals to melanoma, but this susceptibility is modified in other crosses depending both on the contributing sex-linked pigment pattern locus from X. maculatus (Sd or Sp), and the genetic constitution of the backcross parent. Xiphophorus BC(1) hybrids constitute unique genetic models offering the potential to analyze the contributions of specific genes to spontaneous and induced tumor formation in different, but comparable genetic backgrounds.