Evidence of a dominant transcriptional pathway which regulates an undifferentiated and complete metastatic phenotype.

The highly metastatic amelanotic C8161 human melanoma line was found to exhibit complete dominance of its undifferentiated and metastatic phenotype in multiple somatic cell hybridization studies designed to bypass the presence of potential tumor suppressor genes. In a three armed approach involving somatic cell fusions of C8161 with recipient lines of greater differentiation, different lineage, and different tumorigenicity status, the metastatic and undifferentiated phenotype of C8161 was promiscuously dominant. In somatic cell hybrids produced between the C8161 and a group of non-metastatic human melanoma lines which exhibited melanocyte differentiation markers including S100, HMB-45, NKI/C3, and melanin, the fusions were uniformly metastatic and undifferentiated. In somatic cell hybrids of C8161 and MCF-7 the fusions exhibited an estrogen independent and unresponsive, estrogen receptor (ER) negative, and highly metastatic phenotype. In fusions between C8161 and HMS-1, an immortalized 'benign' human myoepithelial line which produced an abundant extracellular matrix (ECM) and high levels of protease and angiogenic inhibitors including maspin, tissue inhibitor of metalloproteinase-1 (TIMP-1), alpha1-antitrypsin (alpha1-AT), protease nexin II (PN-II), thrombospondin-1 and soluble basic fibroblast growth factor (bFGF) receptors, the hybrids showed complete absence of matrix, absent maspin expression, markedly decreased protease inhibitor and angiogenic inhibitor production, high levels of proteases and angiogenic factors, and a highly metastatic phenotype. In our somatic cell fusions, the human-human hybrids represented true and complete fusions and not hybrid clones selected for by loss of dominant-acting growth suppressor genes. This finding was supported by detailed comparative genomic hybridization (CGH) studies, Q-banding karyotype analysis, and autofusions of representative clones. The purposeful creation of inherently unstable human-murine fusions between C8161 and B16-F1 where loss of putative suppressor loci would be expected, resulted in fusions exhibiting decreased growth and non-metastatic behavior with progressive chromosomal loss. Neither p53, nm23, DNA methyltransferase, activated ras, fibroblast growth factor-4 (FGF-4), or epidermal growth factor receptor (EGFR) mediated the acquisition of the metastatic or undifferentiated phenotype within the C8161-human fusions. These studies are the first studies ever to successfully transfer the complete metastatic phenotype by somatic cell fusion and support the presence of a new high level regulatory pathway(s) involving dominant trans-acting factors which act pleiotropically to regulate an undifferentiated and highly metastatic phenotype.

Ectopic G-CSF expression in human melanoma lines marks a trans-dominant pathway of tumor progression.

Using a human melanoma/Scid xenograft model with the C8161, M24-met, LD-1 and other human melanoma lines to investigate spontaneous metastasis, we made the observation of marked splenomegaly (up to five times normal weight and size) in only those xenografts exhibiting high degrees of spontaneous metastasis. Evaluation of this revealed the cause to be massive myelopoiesis due to ectopic granulocyte/ colony-stimulating factor (G-CSF) production by the melanoma cells. Because of these observations linking G-CSF expression with metastasis of human melanoma, we decided to investigate the mechanism of this ectopic production. No gross amplification or rearrangement of the G-CSF gene could be detected as the basis for the increased transcriptional activity in any of these lines. Human-human somatic cell hybridization studies carried out between the metastatic C8161 and several different nonmetastatic non-G-CSF-expressing lines revealed, in addition to metastatic dominance, 3- to 10-fold enhancement of G-CSF transcription and expression in the fusions compared with C8161 itself. The suggestion of a trans-dominant mechanism was further supported by transfection studies with a human G-CSF promoter-CAT-reporter construct, which revealed 3- to 5-fold increased reporter activity in only those melanoma lines and hybrids expressing G-CSF. Furthermore, no obvious autocrine or paracrine effects of this ectopic G-CSF expression on the melanoma lines' growth or metastasis were apparent, as all of the G-CSF-expressing lines lacked the G-CSF receptor and injections of purified recombinant G-CSF exerted no stimulatory effects on their tumorigenicity, latency, growth, or metastasis in Scid mice. Thus, we advance the hypothesis that G-CSF expression is serving as a marker of a more generalized trans-dominant pathway linked to tumor progression and metastasis. This hypothesis has direct relevance to many human cancers where ectopic hormone or growth factor production occurs with no obvious autocrine or paracrine benefit to the tumor.

The human myoepithelial cell is a natural tumor suppressor.

Myoepithelial cells, which surround ducts and acini of glandular organs, form a natural border separating proliferating epithelial cells from basement membrane and underlying stroma. Myoepithelial cells in situ and in vitro constitutively express high amounts of proteinase inhibitors that include tissue inhibitor of metalloproteinase 1, protease nexin-II, alpha-1 antitrypsin, and maspin. Human myoepithelial xenografts (HMS-X, HMS-3X, and HMS-4X), which our laboratory has established, accumulate an abundant extracellular matrix containing sequestered proteinase inhibitors. Humatrix, a gel that we have derived from HMS-X, inhibits tumor cell invasion (down to 25% +/- 10% of Matrigel control; P < 0.01), and our recently established human myoepithelial cell lines, HMS-1, HMS-3, and HMS-4, inhibit tumor cell invasion in cellular invasion (down to 42% +/- 7% of control; P < 0.05) and in conditioned media assays (down to 30% +/- 8% of control; P < 0.01). The anti-invasive effects of HMS-1, HMS-3, and HMS-4 can be enhanced by phorbol 12-myristate 13-acetate (down to 2% +/- 1% of control) by a maspin-dependent mechanism and abolished by dexamethasone (up to 95% +/- 5% of control) by a maspin-independent mechanism (P < 0.01). HMS-X, HMS-3X, HMS-4X, and Humatrix inhibit tumor invasion and metastasis in severe combined immunodeficient mice (P < 0.001). The cumulative data suggest that myoepithelial cells are natural paracrine suppressors of invasion and metastasis and may specifically inhibit the progression of precancerous disease states to invasive cancer in vivo.

Establishment and characterization of a novel human myoepithelial cell line and matrix-producing xenograft from a parotid basal cell adenocarcinoma.

Myoepithelial cells exert important paracrine effects on epithelial morphogenesis and mitogenesis through direct cell-cell interactions and through synthesis of a basement membrane extracellular matrix. To study these effects further, this study established the first immortalized human myoepithelial cell line, HMS-1, and transplantable xenograft, HMS-X, from the rare parotid basal cell adenocarcinoma. The cell line exhibited a fully differentiated myoepithelial phenotype and the xenograft exhibited the rare property of accumulating an abundant extracellular matrix composed of both basement membrane and nonbasement membrane components with the latter predominating. With HMS-1 as a feeder layer, dramatic and specific induction of epithelial morphogenesis (spheroid formation) occurred with selected normal epithelial and primary carcinoma target cells. HMS-1 and HMS-X provide distinct advantages over the conventional murine matrices in existence. They will be invaluable in future studies of human tumor-myoepithelial and matrix interactions important for tumor cell growth, invasion, and metastasis.

Human breast cancer progression can be regulated by dominant trans-acting factors in somatic cell hybridization studies.

Human breast cancer is often characterized by a progression to an ER (estrogen receptor)-negative, estrogen-independent, antiestrogen-resistant, EGFR (epidermal growth factor receptor)-positive, and highly metastatic phenotype. The molecular and biochemical mechanisms behind this progression are not well defined. Most studies of breast cancer have focused on one or another aspect or this progression but have not found a common pathway. By constructing stable and complete human-human somatic cell fusions between a highly metastatic, undifferentiated, ER-negative line of melanoma lineage and the estrogen-dependent, ER-positive MCF-7 line, this study produced hybrids that were ER negative, highly expressive of EGFR, estrogen independent, estrogen unresponsive, fully tumorigenic, and highly metastatic. ER negativity was on the basis of complete suppression of ER transcription as evidenced by Northern blot analysis and nuclear run-on assay, not on the basis of gene rearrangement. EGFR positivity was not due to gene amplification or rearrangement but rather to increased EGFR transcription. Mechanisms, including ras activation, fibroblast growth factor 4 expression, and human DNA methyltransferase activation causing ER promoter methylation, which are respectively known to induce estrogen-independent growth, induce spontaneous metastasis, and decrease ER levels in breast carcinoma experimentally, were not mechanisms operating in the hybrids. This model demonstrates that many of the common denominators of human breast carcinoma progression can be regulated by dominant trans-acting factors.

The primary tumor is the primary source of metastasis in a human melanoma/SCID model. Implications for the direct autocrine and paracrine epigenetic regulation of the metastasis process.

Although previous autopsy and experimental studies had indicated that metastases can metastasize, the question of whether metastases from metastases increasingly contribute to the overall metastatic burden is crucial to the basic question of whether the metastatic process is more directly regulated by genetic or by epigenetic mechanisms. The highly metastatic human C8161 melanoma was transfected with either pSV2neo or pSV2hygro and clones of neo-C8161 and hyg-C8161 were injected intravenously and subcutaneously in SCID mice. In combination experiments, both the timing and size of inoculum of tumor cells were titrated to ensure that the hematogenously injected cells disseminated almost exclusively to the lungs and that the overall pulmonary burden was equal to the primary tumor. In s.c. injection experiments, no spontaneous metastases ever developed when the primary tumor was extirpated before it had grown to more then 0.5 cm in diameter. When the primary tumor approached 1 cm in diameter, widely-disseminated metastases developed within lungs, liver subcutaneous sites and other internal viscera. In the combination-injection experiments, while large numbers of both hematogenously and spontaneously metastatic clones were recovered from the lungs, a vast excess of only the latter clones was recovered from extrapulmonary sites. Both hematogenously and spontaneously metastatic pulmonary clones recovered showed similar levels of Matrigel invasion and collagenases by substrate gel electrophoresis, but significantly decreased levels when compared to the cell line. Primary tumor clones, in contrast, demonstrated increased invasion and increased collagenases. Our findings argue for the importance of paracrine (orthotopic) and autocrine (size) epigenetic mechanisms in the regulation of metastasis.

Characterizations of the extracellular matrix and proteinase inhibitor content of human myoepithelial tumors.

Myoepithelial tumors are intriguing low-grade neoplasms that exhibit the property of accumulating an abundant extracellular matrix. Because accumulation of an extracellular matrix represents an important exception to the rule of matrix degradation otherwise exhibited by the vast majority of human epithelial neoplasms, this study investigated the composition of this matrix to gain insight into the biological behavior of this class of neoplasms. Several different human myoepithelial tumors and their derived cell lines and xenografts were thus examined by ultrastructural, immunohistochemical, molecular, and biochemical methods. Results indicated that although the extracellular matrix of these tumors contains some basement membrane components such as laminin, nidogen, and heparan sulfate proteoglycan (8%), it is also largely cartilagenous in nature, containing large amounts of chondroitin sulfate proteoglycan (78%). In addition to extracellular matrix structural proteins, myoepithelial cells secreted relatively large amounts of proteinase inhibitors including maspin, protease nexin II, alpha1-antitrypsin, a 31-kd serine proteinase inhibitor, and TIMP-1. Immunolocalization and extraction studies further demonstrated that protease nexin II and alpha1-antitrypsin especially accumulated within the myoepithelial extracellular matrix. In addition, protease nexin II likely underwent extracellular in vivo processing to a 95-kd product retaining full proteinase inhibitor activity. These specific biochemical observations unite the classes of myoepithelial tumors, confer an anti-invasive property to their extracellular matrix, and likely contribute to their low-grade biological behavior.

A novel strategy for the investigation of clonality in precancerous disease states and early stages of tumor progression.

A novel strategy for clonality determination from only 100 cells using the polymerase chain reaction in amplifying a 511 bp region located within the first intron of the human hypoxanthine phosphoribosyl transferase (HPRT) gene has been devised. The strategy rests on several observations: that this region in females contains two HpaII/MspI sites whose methylation remains both obligate with X chromosome inactivation and independent of tumor progression; and that this region contains single base allelic polymorphisms in 5-10% of females which can be detected by denaturing gradient gel electrophoresis (DGGE) on the PCR product. In polymorphic individuals, multiple bands (homo- and heteroduplexes) indicate multiclonality, single bands indicate monoclonality, and their comparative migrations indicate clonal identity/non-identity.

Analysis of genomic DNA from Chlamydia trachomatis for Dam and Dcm methylation.

Chlamydia trachomatis is a Gram-negative eubacterium with a dimorphic developmental cycle and obligate intracellular growth in the eucaryotic host. The Dam transmethylase of Escherichia coli methylates at the N6 position of adenine in the sequence 5'-GATC-3' and the Dcm transmethylase adds methyl groups to the C5 position of the internal cytosines in the sequences 5'-CCWGG-3'. In contrast to E. coli, C. trachomatis DNA appears to have unmethylated Dam sites and only low level Dcm methylation.