Tissue specificity of oncogene action: endothelial cell tumours in polyoma middle T transgenic mice

Newborn mice inoculated with murine polyoma (Py) virus develop tumours in a wide range of tissues. To investigate viral oncogenesis we have generated transgenic mice carrying either the Py large T antigen (LT) gene or the Py middle T antigen (MT) gene linked to Py early regulatory sequences. Some Py LT mice develop pituitary tumours, while Py MT mice develop multifocal tumours of the vascular endothelium. These haemangiomas are lethal to the animals and can be passaged in vivo. Transgene RNAs and protein are present in both haemangiomas and the testes of these mice, and the Py middle T protein in both tissues is complexed to a cellular tyrosine kinase. The expression of complexed middle T protein in both tumorigenic endothelial cells and in unperturbed testes implies that endothelial cells may be particularly susceptible to the action of the middle T oncogene. The idea that oncogenes may exhibit a tissue specificity in their action is supported by other transgenic mouse models of oncogenesis and by studies of human tumours.     

Lentivirus-Mediated Oncogene Introduction into Mammary Cells In Vivo Induces Tumors

We recently reported the introduction of oncogene-expressing avian retroviruses into somatic mammary cells in mice susceptible to infection by transgenic expression of tva, encoding the receptor for subgroup A avian leukosis-sarcoma virus (ALSV). Because ALSV-based vectors poorly infect nondividing cells, they are inadequate for studying carcinogenesis initiated from nonproliferative cells (e.g., stem cells). Lentivirus pseudotyped with the envelope protein of ALSV infects nondividing TVA-producing cells in culture but has not previously been tested for introducing genes in vivo. Here, we demonstrate that these vectors infected mammary cells in vivo when injected into the mammary ductal lumen of mice expressing tva under the control of the keratin 19 promoter. Furthermore, intraductal injection of this lentiviral vector carrying the polyoma middle T antigen gene induced atypical ductal hyperplasia and ductal carcinoma in situ-like premalignant lesions in 30 days and palpable invasive tumors at a median latency of 3.3 months. Induced tumors were a mixed epithelial/myoepithelial histologic diagnosis, occasionally displayed squamous metaplasia, and were estrogen receptor-negative. This work demonstrates the first use of a lentiviral vector to introduce oncogenes for modeling cancer in mice, and this vector system may be especially suitable for introducing genetic alterations into quiescent cells in vivo.     

A variety of tumours induced by the middle T antigen of polyoma virus in a transgenic mouse family

A transgenic mouse family expressing the middle T antigen of polyoma virus under control of the immunoglobulin heavy chain (IgE) enhancer showed the frequent occurrence of carcinomas in various organs, predominantly in females. Most frequently affected were the salivary and thyroid glands, but mammary tumours, liver haemangiomas and adenocarcinomas of unknown origin were also observed. In all tumours, the middle T antigen was found to be complexed with cellular tyrosine kinases. These results extend the range of tumour types associated with in vivo expression of middle T and with the subsequent deregulation of pp60c-src and related tyrosine kinases.     

Stimulatory effects of neopterin on hematopoiesis in vitro are mediated by activation of stromal cell function

The pteridine neopterin (NP) was shown to be produced by monocytes and is known to be a useful marker of immunological activation, although, its biological activity is still unclear. Recently, we found that intravenous administration of NP increased the numbers of blood leukocytes, and granulocyte-macrophage progenitor cells (CFU-GM) in the bone marrow and spleens of mice. In order to elucidate the mechanism whereby NP stimulates hematopoiesis, the effects of NP on hematopoietic stem cell proliferation and differentiation in vitro were studied using a long-term bone marrow culture (LTMC) system with cloned stromal cell line, MS-5. Adding NP to the LTMC increased the numbers of cells in total, CFU-GM and colony-forming unit in spleen (CFU-S). NP also increased the number of CFU-GM in a soft agar culture system, but it did not enhance CFU-GM colony formation when target bone marrow cells were semi-purified (T, B and adherent cell-depleted bone marrow cells) and cultured in this system, suggesting that NP did not directly affect the proliferation of hematopoietic progenitors. Conditioned medium obtained from NP-treated stromal cells had much greater colony-stimulating activity than that obtained from untreated stromal cells. Furthermore, NP treatment stimulated the production of IL-6 and GM-CSF by stromal cells. All these findings suggest that NP stimulates hematopoietic cell proliferation and differentiation in vitro by activating stromal cell function.     

Extracellular protease mRNAs are predominantly expressed in the stromal areas of microdissected mouse breast carcinomas

Solid tumors synthesize a number of extracellular matrix-degrading proteases that are important for tumor progression. Based on qualitative in situ hybridization studies in human cancer tissue, a range of components involved in proteolysis appear to be expressed by stromal cells rather than cancer cells. We have now used laser capture microdissection and real-time PCR to quantify the mRNA expression of components of matrix-degrading proteolytic systems in cancer and stromal areas of mouse mammary tumors genetically induced by the polyoma virus middle T (PyMT) antigen. We examined the mRNA levels of urokinase plasminogen activator, plasminogen activator inhibitor 1 and the matrix metalloproteases MMP-2, -3, -11, -13 and -14, and found that all these seven genes are predominantly expressed by stromal cells. Our results were qualitatively supported by in situ hybridization analysis of the expression of mRNAs for MMP-2, -3 and -13 in the PyMT tumors. Statistical analyses indicated that the quantitative expression patterns observed in cancer and stromal cells isolated from individual tumors from different PyMT mice are quite reproducible. The methodology described in this study provides excellent tools to study the possible interactions between cancer and stromal cells during the development of breast cancer, and the results suggest that stromal cells are involved in carcinogenesis and tumor progression, which may have important implications for the biology and therapy of cancer.     

Unique lymphoid cell subset target to infection and proliferation induced in vitro by a murine leukemia virus.

The mechanisms by which non-oncogene bearing, slowly transforming T-cell-tropic retroviruses induce leukemia is not well understood. Viruses such as the murine radiation leukemia virus (RadLV) induce oncogenic transformation of T-cells in the thymus only in vivo and after a long latency. The capacity of RadLV to induce proliferation of lymphoid cells in vitro has been analysed here as a first attempt at mapping oncogenic transformation. Autonomously replicating cell lines have been isolated following exposure of splenic lymphocytes to two different isolates of RadLV, following in vitro culture in the presence of T-cell growth factors. Cells of similar precursor lymphoid morphology and phenotype have been isolated and cloned from cultures established from different animals. These cell lines all grow independently of exogenous growth factors in vitro, but are not tumorigenic in mice. Exposure to RadLV under the culture conditions provided has allowed integration of a new retroviral genome into each cell line, but no active replication of virus has been detected in any of the cell lines analysed. A common cell type resembling a lymphoid precursor has been induced to proliferate. These cell lines express cell surface markers attesting to their bone marrow origin, such as CD44 (Pgp-1), Gr-1, B220 and NK1.1, but they do not show the characteristics of T cells which have undergone differentiation within the thymus. They do not express the Thy-1 marker, nor show rearrangement involving any of the T-cell receptor (TCR) alpha, beta gamma or sigma genes. These cells bind several antibodies specific for the CD3-epsilon and TCR-alpha beta structures, and there appears to be aberrant expression of TCR proteins in cells bearing fully rearranged TCR genes. Precursor lymphoid cells and not mature T-cells in spleen, appear to be appropriate targets for RadLV-induced proliferation/immortalisation in vitro. Oncogenic transformation induced by RadLV in vivo may occur within precursor lymphoid cells and must be a complex process dependent on both the differentiation events which occur within the thymus, as well as the thymic environment of stromal cells.     

Polyoma virus middle tumor antigen stimulates membrane-associated protein kinase C at lower levels than required for phosphatidylinositol kinase activation and neoplastic transformation.

Twelve independent rat F111 cell lines expressing the polyoma virus middle tumor antigen (mT) under control of the dexamethasone-regulatable MMTV-LTR promoter were assayed for levels of membrane-associated protein kinase C (PKC) activity. Low background levels of mT antigen expression (approximately 2%), although insufficient for transformation, triggered a dramatic increase in PKC activity. Under the same conditions, levels of the mT-associated phosphatidylinositol kinase activity were low, indicating that this kinase might be a factor limiting transformation in this cell system.     

Vascular tumors induced by polyoma virus in pregnant rats.

Female R rats mated with an R male and inoculated in utero with polyoma virus after "fetectomy" developed tumors. These tumors originated in the uterus and were of fetal origin (visceral yolk sac). Histologically, they were hemangiomas or hemangiosarcomas. The latter were transplantable and grew in tissue culture. Infectious polyoma virus could not be isolated from the tumor cells kept as transplantable lines or cultured in vitro. However, the tumor cells were positive for the polyoma-specific surface antigen, polyoma tumor-specific transplantation antigen(s), and polyoma nuclear T antigen.     

Systemic retinoic acid treatment induces sodium/iodide symporter expression and radioiodide uptake in mouse breast cancer models

Lactating breast tissue and some breast cancers express the sodium/iodide symporter (NIS) and concentrate iodide. We recently demonstrated that all-trans retinoic acid (tRA) induces both NIS gene expression and iodide accumulation in vitro in well-differentiated human breast cancer cells (MCF-7). In the present study, we investigated the in vivo efficacy and specificity of tRA-stimulated iodide accumulation in mouse breast cancer models. Immunodeficient mice with MCF-7 xenograft tumors were treated with systemic tRA for 5 days. Iodide accumulation in the xenograft tumors was markedly increased, approximately 15-fold greater than levels without treatment, and the effects were tRA dose dependent. Iodide accumulation in other organs was not significantly influenced by tRA treatment. Significant induction of NIS mRNA and protein in the xenograft tumors was observed after tRA treatment. Iodide accumulation and NIS mRNA expression were also selectively induced in breast cancer tissues in transgenic mice expressing the oncogene, polyoma virus middle T antigen. These data demonstrate selective induction of functional NIS in breast cancer by tRA. Treatment with short-term systemic retinoic acid, followed by radioiodide administration, is a potential tool in the diagnosis and treatment of some differentiated breast cancer.     

Direct and indirect contribution of bone marrow‐derived cells to cancer

Stromal‐epithelial interactions may control the growth and initiation of cancers. Here, we not only test the hypothesis that bone marrow‐derived cells may effect development of cancers arising from other tissue cells by forming tumor stroma but also that sarcomas may arise by transformation of stem cells from the bone marrow and epithelial cancers may arise by transdifferentiation of bone marrow stem cells to epithelial cancers. Lethally irradiated female FVB/N mice were restored with bone marrow (BM) transplants from a male transgenic mouse carrying the polyoma middle T‐oncoprotein under the control of the mouse mammary tumor virus promoter (MMTV‐PyMT) and followed for development of lesions. All of 8 lethally irradiated female FVB/N recipient mice, restored with BM transplants from a male MMTV‐PyMT transgenic mouse, developed Y‐chromosome negative (Y−) cancers of various organs surrounded by Y+ stroma. One of the female FVB/N recipient mice also developed fibrosarcoma and 1, a diploid breast adenocarcinoma containing Y chromosomes. In contrast, only 1 of 12 control female mice restored with normal male BM developed a tumor (lymphoma) during the same time period. These results indicate not only that the transgenic BM‐derived stromal cells may indirectly contribute to development of tumors in recipient mice but also that sarcomas may arise by transformation of BM stem cells and that breast cancers arise by transdifferentiation of BM stem cells, presumably by mesenchymal‐epithelial transition.     

Chromosomal instability at a mutational hotspot in polyoma middle T-antigen affects its ability to activate the ARF-p53 tumor suppressor pathway

We have isolated spontaneous mutants of polyoma virus middle T-antigen (PyMT) that do not activate the ARF-p53 pathway based on their inability to block REF52 cell division. The REF52 cells containing these mutants have a flat untransformed morphological phenotype and do not express the ARF protein. The PyMT mutations in the different cell isolates so far analysed occur at a mutational hotspot in the PyMT sequence between nucleotides 1241 and 1249, which contains nine consecutive cytosines. In one set of mutants a single cytosine was deleted, while in another mutant set an additional cytosine was inserted. Both these mutations result in frameshifts, generating altered PyMT proteins containing amino-acid sequences derived from each of the two other alternative reading frames of the polyoma virus early region. Both types of mutations result in the loss of the C-terminal PyMT region containing the membrane-binding hydrophobic region and result is mislocalization of the PyMT mutant proteins. Revertant wild-type PyMT (containing nine cytosines) was easily detected in transformants generated after infection of REF52 cells expressing high amounts of dominant negative p53 with retroviruses containing either mutation. We demonstrate that wild-type PyMT revertants are derived from mutations in the hotspot sequence of the integrated mutant PyMT sequences.     

Stepwise progression of B cell malignancy occurred in a bone marrow stromal cell-dependent pre-B cell clone

The murine long-term bone marrow culture system which can support the almost infinite growth of normal B lineage cells was used to establish the experimental model for spontaneous B cell leukemogenesis. At the early phase of the culture, B cell differentiation with diversification of immunoglobulin genes was induced. However, the culture was finally captured by a single B cell clone which had the fastest growth rate. The B cell clone was strictly dependent on stromal cells for in vitro growth and did not generate leukemia when injected into syngenic mice. After up to a year of maintenance of the clone, the leukemic cells developed spontaneously. The leukemic cell line isolated in vivo retained the stromal cell-dependency, and further in vitro selection process was required to establish the stromal cell-independent leukemic cell line. These leukemic cell lines highly expressed c-myc and Ha-ras genes regardless of stromal cell-dependency. We detected no chromosomal aberrations accompanied with the process of leukemic transformation. Our results suggest that spontaneous neoplastic transformation of B cells in long-term bone marrow culture occurs in a stepwise manner.     

The bone marrow stromal microenvironment influences myeloma therapeutic response in vitro.

The bone marrow microenvironment supports growth and differentiation of normal hematopoietic cells and can contribute to malignant growth. Since myeloma cells localize and accumulate in bone marrow, it is important to understand the influence of the bone marrow microenvironment not only on the growth of the malignant cells, but also on the therapeutic response of myeloma cells. Growth factors such as interleukin-6 (IL-6) produced by bone marrow stromal cells can protect myeloma cells from glucocorticoid-induced apoptosis. We examined the effect of myeloma cells-bone marrow stromal cells interaction in vitro on several therapeutic treatments. An interleukin-6-dependent myeloma cell line ANBL6 was used and treated with dexamethasone, doxorubicin, and melphalan in the presence of bone marrow stromal cells. Stromal cells were able to protect ANBL6 from dexamethasone, but significantly enhanced the effect of doxorubicin and melphalan. IL-6-induced bcl-XL and cyclin D2 expression in ANBL6 cells, but dexamethasone was able to suppress both bcl-XL and cyclin D2 expression in ANBL6. Doxorubicin and melphalan were able to suppress bcl-XL expression only in the presence of IL-6. We also looked at the effect of activating mutations of N-ras in myeloma cells interacting with stromal cells on therapeutic responses. Surprisingly, ANBL6 N-ras shows significant resistance to all drugs used. Notably, the presence of stromal cells did not alter ANBL6 Nras cells' drug resistance. These results suggest both the bone marrow microenvironment and genetic alterations of myeloma cells can independently impact on therapeutic responses.     

HOXB4 confers a constant rate of in vitro proliferation to transduced bone marrow cells

HOXB4 overexpression mediates increased self-renewal of haematopoietic stem cells (HSCs) ex vivo. Since HOXB4-expanded HSCs retain normal differentiation potential and there is no leukaemia development from transduced HSCs, HOXB4 represents a promising tool for human HSC therapy. However, the increased proliferation capacity of HOXB4 overexpressing fibroblasts resulting from upregulation of JunB, Fra-1 and cyclin D1 protein levels may indicate a potential risk associated with the HOXB4 overexpression approach. This prompted us to investigate the proliferation rate, differentiation and expression of cell cycle regulators directly in bone marrow cultures overexpressing HOXB4. Here we show that in comparison to neo-transduced control bone marrow cultures, HOXB4-overexpressing cultures had a more homogenous morphology and increased numbers of haematopoietic progenitor cells capable to generate primitive colonies in vitro. In contrast, neo-transduced bone marrow cells in long-term cultures showed hallmarks of myeloid differentiation and a reduced secondary colony forming activity. We further show that multilineage repopulating activity in vivo, which was present only in HOXB4 long-term cultures, declined over time. HOXB4 overexpression in vitro did not result in an increase but in a stabilization of the proliferation rate (1.4-1.8 cell divisions per day), while the proliferation rate of control neo-transduced bone marrow cultures gradually declined. Correspondingly, increased HOXB4 expression was paralleled by decreased expression levels of cyclins, CDKs and AP-1 family members. These results suggest that the growth rate of HOXB4- compared to neo-transduced bone marrow cells remains constant in long-term cultures along with a suppression of myeloid differentiation. In contrast to HOXB4 overexpression in fibroblasts, bone marrow cells engineered to overexpress HOXB4 do not upregulate AP-1 complex members or cyclins indicating that HOXB4 acts in a cell type-specific way.     

In vitro growth of human multiple myeloma: implications for biology and therapy.

In vitro data allow presentation of a plausible scenario for the in vivo growth, progression, and dissemination of human multiple myeloma (MM) that involves the interactions between the monoclonal B-cell clone and the bone marrow (BM) microenvironment. A large series of adhesion and extracellular matrix molecules allow trapping of circulating plasma cell precursors within the BM, and a battery of locally released cytokines promote their growth and final differentiation. Malignant B cells establish close contacts with BM stromal cells and release a host of cytokines that recruit and activate BM stromal cells and also T lymphocytes to produce other cytokines. All these cytokines might conceivably act in concert in a self-perpetuating mechanism of mutual help between malignant plasma cells and BM stromal cells to favor the progressive expansion of the malignant clone through a sort of an "avalanche effect." Also, most cytokines produced by malignant B cells, stromal cells, and activated T lymphocytes, including IL-1 beta, TNF-beta, M-CSF, IL-3, and IL-6, have osteoclast-activating properties, thus explaining why the expansion of the B-cell clone is matched by the activation and numeric increase of osteoclasts.     

Rodent fibroblast tumours expressing human myc and ras genes: growth, metastasis and endogenous oncogene expression

The effects of expression of human c-myc and both mutated (T24) and normal forms of human Ha-ras-1 were studied in an aneuploid rat fibroblast line (208F). Mutated T24 Ha-ras was also studied in a near-diploid cell derived from early passage Chinese hamster lung fibroblasts (CHL). In contrast to the parental fibroblasts, cells expressing any of the human oncogenes engendered rapidly growing tumours in immune-suppressed animals. Blood- and lymph-borne metastases were observed from both ras- and myc-expressing cells. In general ras-expressing cells were more aggressive than those expressing myc. In the 208F background, expression of c-myc was associated with an incidence of mitosis similar to that in tumours expressing T24 Ha-ras, but incidence of single cell death by apoptosis was higher. Quantitatively, expression of human oncogene mRNA was constant during growth in vivo, and similar to that sometimes observed in human neoplasms. Of 9 endogenous proto-oncogenes, 7 showed no change in expression from the parental fibroblasts, but c-abl and c-fos were strongly expressed in all cells expressing human ras or myc. Thus these tumorigenic cells, although transfected with single human oncogenes, all expressed oncogenes with both nuclear- and membrane-associated products.