Melanoma loss-of-function mutants in Xiphophorus caused by Xmrk-oncogene deletion and gene disruption by a transposable element.

The overexpression of the Xmrk oncogene (ONC-Xmrk) in pigment cells of certain Xiphophorus hybrids has been found to be the primary change that results in the formation of malignant melanoma. Spontaneous mutant stocks have been isolated that have lost the ability to induce tumor formation when crossed with Xiphophorus helleri. Two of these loss-of-function mutants were analyzed for genetic defects in ONC-Xmrk's. In the lof-1 mutant a novel transposable element, TX-1, has jumped into ONC-Xmrk, leading to a disruption of the gene and a truncated protein product lacking the carboxyterminal domain of the receptor tyrosine kinase. TX-1 is obviously an active LTR-containing retrotransposon in Xiphophorus that was not found in other fish species outside the family Poeciliidae. Surprisingly, it does not encode any protein, suggesting the existence of a helper function for this retroelement. In the lof-2 mutant the entire ONC-Xmrk gene was found to be deleted. These data show that ONC-Xmrk is indeed the tumor-inducing gene of Xiphophorus and thus the critical constituent of the tumor (Tu) locus.     

Ligand-independent dimerization and activation of the oncogenic Xmrk receptor by two mutations in the extracellular domain

Overexpression of the oncogenic receptor tyrosine kinase ONC-Xmrk is the first step in the development of hereditary malignant melanoma in the fish Xiphophorus. However, overexpression of its proto-oncogene counterpart (INV-Xmrk) is not sufficient for the oncogenic function of the receptor. Compared with INV-Xmrk, the ONC-Xmrk receptor displays 14 amino acid changes, suggesting the presence of activating mutations. To identify such activating mutations, a series of chimeric and mutant receptors were studied. None of the mutations present in the intracellular domain was found to be involved in receptor activation. In the extracellular domain, we found two mutations responsible for activation of the receptor. One is the substitution of a conserved cysteine (C578S) involved in intramolecular disulfide bonding. The other is a glycine to arginine exchange (G359R) in subdomain III. Either mutation leads to constitutive dimer formation and thereby to activation of the ONC-Xmrk receptor. Besides, the presence of these mutations slows down the processing of the Xmrk receptor in the endoplasmic reticulum, which is apparent as an incomplete glycosylation.     

Construction and initial analysis of bacterial artificial chromosome (BAC) contigs from the sex-determining region of the platyfish Xiphophorus maculatus

Despite the major importance of sex determination in aquaculture, no master sex-determining gene has been identified so far in teleost fish. In the platyfish Xiphophorus maculatus, this master gene is flanked by two receptor tyrosine kinase genes, the Xmrk oncogene responsible for melanoma formation in some Xiphophorus interspecific hybrids, and its proto-oncogenic counterpart. Both Xmrk genes, which have already been characterised at the molecular level, delimit a region of about 1 Mb that contains other gene loci involved in sexual maturity, pigmentation and melanoma formation. We have constructed a genomic bacterial artificial chromosome (BAC) library of X. maculatus with a tenfold coverage of the haploid genome and walked on both X and Y sex chromosomes starting from both Xmrk genes. This led to the assembly of BAC contigs from the sex-determining region covering approximately 950 kb of the X and 750 kb of the Y chromosome. To our knowledge, these are the largest contigs reported so far for sex chromosomes in fish. Molecular analysis suggests that the sex-determining region of X. maculatus frequently undergoes retrotranspositions and other kinds of rearrangements. This genomic plasticity might be related to the high genetic variability observed in Xiphophorus for sex determination, sexual maturity, pigmentation and melanoma formation, which are encoded by gene loci located in the sex-determining region.     

Identification of a second egfr gene in Xiphophorus uncovers an expansion of the epidermal growth factor receptor family in fish

The epidermal growth factor receptor (EGFR) gives name to a family of receptors formed by four members in mammals (EGFR, ErbB2, ErbB3, and ErbB4). Members of this family can be activated to become potent oncogenes, and many human and animal tumors express qualitatively or quantitatively altered receptors from this group. We have isolated and characterized a second egfr gene in the melanoma model fish Xiphophorus. Both Xiphophorus egfra and egfrb duplicates are co-orthologs of the mammalian egfr gene. Database analysis showed that not only egfr but also erbB3 and erbB4 are present as duplicates in some fish species. They originated from ancient duplication events that might be consistent with the hypothesis of a fish-specific genome duplication. In Xiphophorus, the egfrb gene underwent a second duplication that generated the melanoma-inducing oncogene Xmrk. The study and comparison of some of the functional characteristics of both Xiphophorus EGF receptors, including expression profile, ligand-binding abilities, and intracellular signal transduction revealed that Xiphophorus Egfra not only shares common features with Egfrb and the human EGFR but also shows significant differences in its functional characteristics. The mechanism of maintenance of these duplicates remains to be clarified.     

Interaction of Xiphophorus and murine Fyn with focal adhesion kinase

The Src family kinase/Focal Adhesion Kinase (FAK) complex is a signaling platform playing a crucial role in transformation downstream of oncogenic growth factor receptors. In the case of melanoma in Xiphophorus fish, the oncogenic EGF receptor orthologue Xiphophorus melanoma receptor kinase (Xmrk) effects continuous activation of the Src family kinase Fyn, but not of the other family members Src or Yes. Here, Fyn is strongly involved in promoting many tumorigenic events. Although Fyn is expressed in most mammalian tissues, there are only few reports of its involvement in the development of solid tumors. To find out whether the prominent role of Xiphophorus Fyn is based on an altered binding to its important binding partner FAK when compared to its mammalian Fyn counterparts, we performed yeast-two-hybrid analyses. We compared Xiphophorus and murine Fyn with respect to their binding to full-length and truncated FAK constructs. We found that interaction with FAK occurs similarly for Xiphophorus and mouse Fyn. Both phosphorylated FAK residue Y397 and FAK proline-rich domain are involved in Fyn binding. We also found interaction of FAK and Fyn in human melanoma cell lines. These data suggest a possible, yet unrecognized role of Fyn in the tumorigenesis of human melanoma, too.     

Homology of Melanoma-Inducing Loci in the Genus Xiphophorus

Several species of the genus Xiphophorus are polymorphic for specific pigment patterns. Some of these give rise to malignant melanoma following the appropriate crossings. For one of these pattern loci from the playfish Xiphophorus maculatus the melanoma-inducing gene has been cloned and found to encode a novel receptor tyrosine kinase, designated Xmrk. Using molecular probes from this gene in Southern blot analyses on single fish DNA preparations from 600 specimens of different populations of various species of the genus Xiphophorus and their hybrids, either with or without melanoma-predisposing pattern, it was shown that all individuals contain the Xmrk gene as a proto-oncogene. It is located on the sex chromosome. All fish that carry a melanoma-predisposing locus which has been identified by Mendelian genetics contain an additional copy of Xmrk, closely linked to a specific melanophore pattern locus on the sex chromosome. The melanoma-inducing loci of the different species and populations are homologous. The additional copy of Xmrk obviously arose by a gene-duplication event, thereby acquiring the oncogenic potential. The homology of the melanoma-inducing loci points to a similar mechanism of tumor suppression in all feral fish populations of the different species of the genus Xiphophorus.     

RASSF6 exhibits promoter hypermethylation in metastatic melanoma and inhibits invasion in melanoma cells

Brain metastasis is a major contributor to cancer mortality, yet, the genetic changes underlying the development of this capacity remain poorly understood. RASSF proteins are a family of tumor suppressors that often suffer epigenetic inactivation during tumorigenesis. However, their epigenetic status in brain metastases has not been well characterized. We have examined the promoter methylation of the classical RASSF members (RASSF1A-RASSF6) in a panel of metastatic brain tumor samples. RASSF1A and RASSF2 have been shown to undergo promoter methylation at high frequency in primary lung and breast tumors and in brain metastases. Other members exhibited little or no methylation in these tumors. In examining melanoma metastases, however, we found that RASSF6 exhibits the highest frequency of inactivation in melanoma and in melanoma brain metastases. Most melanomas are driven by an activating mutation in B-Raf. Introduction of RASSF6 into a B-Raf^V600E-containing metastatic melanoma cell line inhibited its ability to invade through collagen and suppressed MAPK pathway activation and AKT. RASSF6 also appears to increase the association of mutant B-Raf and MST1, providing a potential mechanism by which RASSF6 is able to suppress MAPK activation. Thus, we have identified a novel potential role for RASSF6 in melanoma development. Promoter methylation leading to reduced expression of RASSF6 may play an important role in melanoma development and may contribute to brain metastases.     

RASSF6 exhibits promoter hypermethylation in metastatic melanoma and inhibits invasion in melanoma cells

Brain metastasis is a major contributor to cancer mortality, yet, the genetic changes underlying the development of this capacity remain poorly understood. RASSF proteins are a family of tumor suppressors that often suffer epigenetic inactivation during tumorigenesis. However, their epigenetic status in brain metastases has not been well characterized. We have examined the promoter methylation of the classical RASSF members (RASSF1A-RASSF6) in a panel of metastatic brain tumor samples. RASSF1A and RASSF2 have been shown to undergo promoter methylation at high frequency in primary lung and breast tumors and in brain metastases. Other members exhibited little or no methylation in these tumors. In examining melanoma metastases, however, we found that RASSF6 exhibits the highest frequency of inactivation in melanoma and in melanoma brain metastases. Most melanomas are driven by an activating mutation in B-Raf. Introduction of RASSF6 into a B-Raf^V600E-containing metastatic melanoma cell line inhibited its ability to invade through collagen and suppressed MAPK pathway activation and AKT. RASSF6 also appears to increase the association of mutant B-Raf and MST1, providing a potential mechanism by which RASSF6 is able to suppress MAPK activation. Thus, we have identified a novel potential role for RASSF6 in melanoma development. Promoter methylation leading to reduced expression of RASSF6 may play an important role in melanoma development and may contribute to brain metastases.     

Epigenetic events in malignant melanoma

Irreversible changes in the DNA sequence, including chromosomal deletions or amplification, activating or inactivating mutations in genes, have been implicated in the development and progression of melanoma. However, increasing attention is being turned towards the participation of 'epigenetic' events in melanoma progression that do not affect DNA sequence, but which nevertheless may lead to stable inherited changes in gene expression. Epigenetic events including histone modifications and DNA methylation play a key role in normal development and are crucial to establishing the correct program of gene expression. In contrast, mistargeting of such epigenetic modifications can lead to aberrant patterns of gene expression and loss of anti-cancer checkpoints. Thus, to date at least 50 genes have been reported to be dysregulated in melanoma by aberrant DNA methylation and accumulating evidence also suggests that mistargetting of histone modifications and altered chromatin remodeling activities will play a key role in melanoma. This review gives an overview of the many different types of epigenetic modifications and their involvement in cancer and especially in melanoma development and progression.     

Xiphophorus interspecies hybrids as genetic models of induced neoplasia

Fishes of the genus Xiphophorus (platyfishes and swordtails) are small, internally fertilizing, livebearing, and derived from freshwater habitats in Mexico, Guatemala, Belize, and Honduras. Scientists have used these fishes in cancer research studies for more than 70 yr. The genus is presently composed of 22 species that are quite divergent in their external morphology. Most cancer studies using Xiphophorus use hybrids, which can be easily produced by artificial insemination. Phenotypic traits, such as macromelanophore pigment patterns, are often drastically altered as a result of lack of gene regulation within hybrid fishes. These fish can develop large exophytic melanomas as a result of upregulated expression of these pigment patterns. Because backcross hybrid fish are susceptible to the development of melanoma and other neoplasms, they can be subjected to potentially deleterious chemical and physical agents. It is thus possible to use gene mapping and cloning methodologies to identify and characterize oncogenes and tumor suppressors implicated in spontaneous or induced neoplasia. This article reviews the history of cancer research using Xiphophorus and recent developments regarding DNA repair capabilities, mapping, and cloning of candidate genes involved in neoplastic phenotypes. The particular genetic complexity of melanoma in these fishes is analyzed and reviewed.     

DNA repair in hybrid fish of the genus Xiphophorus

The genus Xiphophorus is an important vertebrate model for investigating the etiology and genetics of both spontaneous and induced cancers. Xiphophorus are comprised of 23 species most of which can be crossed to produce fertile interspecies hybrid progeny. The Xiphophorus gene map is well developed and allows genetic associations to be studied among cohorts of progeny derived from backcrossing interspecies hybrid animals to one of the parental strains. In interspecies cross-progeny from select Xiphophorus backcrosses, ionizing radiation, ultraviolet light (UVB), and exposure to methylnitrosourea (MNU) have all been shown to induce tumors. Induced tumor types represented in various models include melanoma, fibrosarcoma, schwannoma, retinoblastoma, etc. The well-established backcross hybrid genetics make Xiphophorus fish an excellent system to study the contribution of DNA repair capability to induced tumorigenesis. DNA repair pathways represent multigenic traits that must be tightly regulated to insure genome fidelity. Herein we review initial DNA repair studies that assess repair capacities among different Xiphophorus species and interspecies hybrids. Assessment of both base excision repair (BER) and nucleotide excision repair (NER) have yielded consistent results indicating reduced DNA repair function in hybrid fish tissues. These data provide molecular support for potential reduced fitness in hybrid fish under conditions of environmental stress and may present a plausible explanation for absence of interspecies hybridization in sympatric environments. In addition, they support the role of direct DNA damage and its repair in the initiation of tumors in Xiphophorus hybrids.     

Analysis of an esterase linked to a locus involved in the regulation of the melanoma oncogene and isolation of polymorphic marker sequences inXiphophorus

Melanoma formation in Xiphophorus hybrids is mediated by a growth factor receptor tyrosine kinase oncogene encoded by the Tu locus. In the wild-type parental fish no tumors occur due to the activity of a locus that regulates the activity of the melanoma oncogene. Molecular identification of this regulatory locus (R) requires a precise physical map of the chromosomal region. Therefore we studied esterase isozymes in Xiphophorus, two of which have been previously reported to be linked to locus R. We confirm that ES1 is a distant marker for R (approx. 30cM), and contrary to earlier studies, we show that this isozyme is present in all species of the genus and at similar activity levels in all organs tested. ES4, which has also been reported to be linked to R, was found to be a misclassification of liver ES1. In an attempt to identify markers that bridge the large distance between ES1 and R, we have generated DNA probes which are highly polymorphic. They will be useful in finding landmarks on a physical map of the R-containing chromosomal region.     

Etiology of MNU-induced melanomas in Xiphophorus hybrids

Genetic hybrids of the genus Xiphophorus have historically been useful models for study of the genetic aspects of tumor formation. In the most studied Xiphophorus tumor model, two-gene loci, XMRK and DIFF, are implicated as critical both to UV-induced and spontaneous melanoma formation in BC(1) hybrids of crosses between X. maculatus and X. helleri, with X. helleri as the recurrent backcross parent. In addition to UV, the direct-acting carcinogen N-methyl-N-nitrosourea (MNU) has been used to induce tumors in Xiphophorus BC(1) hybrids from several cross types. In the present study, we address the hypothesis that excess melanomas in MNU-treated BC(1) hybrids may have been generated by direct mutation of CDKN2AB, a candidate gene for DIFF. MNU treatment of F(1) and BC(1) hybrid fish significantly increased tumor incidence at 6 months; however, no association was found between MNU-induced tumor formation and zygosity of the candidate tumor tumor-suppressor CDKN2AB in BC(1) hybrids, consistent with previously reported results. Sequence analysis of the X. maculatus CDKN2AB locus of heterozygous individuals (both BC(1) and F(1) hybrids) did not reveal any mutations caused by MNU, suggesting that the mechanism of MNU-induced melanoma formation in this Xiphophorus model does not involve direct mutation of CDKN2AB but may result from mutation of other critical genes.     

Pharmacological properties of angiotensin II receptors in cultured rabbit gingival fibroblasts

Certain interspecific hybrids of the fish Xiphophorus spontaneously develop melanoma induced by the derepression of the Xmrk oncogene. Xmrk is a recent duplicate of an orthologue of the mammalian epidermal growth factor receptor gene Egfr. In addition to a specific overexpression in melanoma, amino-acid substitutions in the extracellular domain leading to ligand-independent dimerisation and constitutive autophosphorylation are responsible for the tumorigenic potential of Xmrk. The Xmrk receptor induces several signal transduction pathways mediating cell proliferation and resistance to apoptosis and initiating dedifferentiation. Moreover, Xmrk upregulates the expression of the secreted protein osteopontin, inducing an autocrine loop possibly allowing invasion and survival in the dermis as a first step in malignancy. Hence, Xmrk is able to induce pathways essential for a transformed phenotype. Some of these events are equivalent to those found downstream of the mammalian Egfr, but others have clearly evolved differently or are specific for pigment cells. Xmrk is potentially hazardous, nonessential and located in a very unstable genomic region. Nevertheless, Xmrk has been maintained under purifying selection in divergent Xiphophorus species. Hence, Xmrk has probably a beneficial function under certain conditions. The analysis of this function is a major challenge for future research in the Xiphophorus model.     

MC1R CpG island regulates MC1R expression and is methylated in a subset of melanoma tumours

Melanocortin 1 receptor (MC1R) is a G protein‐coupled receptor expressed in melanocytes where it plays an important role in skin pigmentation and in the UV response, and has implications in melanoma development. Here we show that methylation of a CpG island (CGI) within the MC1R gene can control expression of MC1R in melanoma. This CGI overlaps with a potential enhancer region, and is unmethylated in normal melanocytes but highly methylated in other skin cells, suggesting a melanocyte specific function. Analysis showed that MC1R was the only gene significantly differentially expressed by methylation of this region. Within several data sets, this region is methylated in a subset of melanoma tumours (55%–74% of tumours) and results in reduced MC1R expression and significantly longer overall survival.     

Multi-step genetic regulation of oncogene expression in fish hereditary melanoma

Melanoma occurring spontaneously in Xiphophorus fish hybrids is a model system in which involvement of cellular oncogenes and multi-step regulation of their expression have been identified by classical genetics. The macromelanophore gene in platyfish (Xiphophorus maculatus) is a sex-linked codominant gene which determines the black spot patterns of macromelanophores in the skin. The macromelanophore locus includes a cellular oncogene which potentially induces neoplasms of the pigment cells. Expression of the oncogene is regulated by a multi-step genetic process and brings about a characteristic phenotype associated with pigment cell differentiation at each step. The multi-step genetic regulation of oncogene expression can be recognized by interspecific hybridization of the platyfish with swordtails (Xiphophorus helleri) which have not developed the macromelanophore gene. When platyfish are hybridized with swordtails, the F1 offspring carrying this gene develop a preneoplastic state. When the F1 offspring are back-crossed to swordtails, the backcross offspring develop a heritable form of melanoma with a characteristic inheritance pattern. This heritable form of melanoma occurs at an early age and has a well differentiated character. Thus, the first and second steps of oncogene expression bring about a preneoplastic state in the F1 offspring and a heritable form of melanoma in the backcross offspring, respectively. These steps may be due to progressive substitution of platyfish chromosomes with swordtail chromosomes in germ line cells, resulting in a progressive reduction of the dosage of regulatory genes in the platyfish genome. The third step of oncogene expression brings about a sporadic form of melanoma in the hybrid offspring bearing the preneoplastic state and heritable form of melanoma spontaneously or through induction by carcinogens. This form of melanoma has a poorly differentiated character. The incidence of this form is considerably enhanced by aging in adult life, thus exhibiting age-specific incidence. It is likely that this step is due to mutational events in regulatory genes, which occur in somatic cells following chromosome substitution in germ line cells by hybridization. The albino gene enhances the malignancy of the two forms of melanoma and the incidence of the sporadic form of melanoma, possibly by suppressing the differentiation of transformed pigment cells. These facts and speculations are summarized in Fig. 6. The molecular identification of oncogenes in this melanoma system and their transfer into the swordtail eggs may provide a useful means for studying oncogene expression during development, growth, and aging of animals.     

PI3-Kinase Is Involved in Mitogenic Signaling by the Oncogenic Receptor Tyrosine Kinase Xiphophorus Melanoma Receptor Kinase in Fish Melanoma

Overexpression of the mutationally activated receptor tyrosine kinase Xiphophorus melanoma receptor kinase (Xmrk) initiates formation of hereditary malignant melanoma in the fish Xiphophorus. In melanoma as well as in a melanoma-derived cell line (PSM) this receptor is highly activated resulting in constitutive Xmrk-mediated mitogenic signaling. In order to analyze mitogenic signaling triggered by Xmrk a possible involvement of phosphatidylinositol 3 (PI3)-kinase in Xmrk signal transduction was examined. Constitutive binding of the p85 adapter subunit of PI3-kinase to the Xmrk receptor was detected in PSM melanoma cells. Further analyses in BHK cells expressing a Xmrk chimera (HER-mrk) showed that p85 association with the intracellular part of Xmrk was dependent on autophosphorylation of the receptor. In vitro binding studies revealed that the interaction is mediated mainly through the N-terminal SH2 domain of p85 which directly binds to a sequence motif around phosphorylated Tyr-983 in the Xmrk carboxy-terminus. In accordance with recruitment of p85 by Xmrk in PSM cells, the PI3-kinase downstream target Akt was found to be highly phosphorylated on Ser-473, indicating efficient PI3-kinase signaling in melanoma cells. PI3-kinase activation was also detected in Xiphophorus melanoma. Moreover, malignant melanomas exhibited an increased level of PI3-kinase activity which was about three times higher than that in benign pigmented lesions. Inhibition of PI3-kinase activity in PSM melanoma cells by both Wortmannin and LY294002 blocked entry into S-phase. Together these data demonstrate that PI3-kinase is a substrate of the oncogenic Xmrk receptor and plays a significant role in mitogenic signaling of melanoma cells and the formation of malignant melanoma in Xiphophorus.