The effect of parity, tumor latency and transplantation on the activation ofint loci in mmtv-induced, transplanted C3H mammary pre-neoplasias and their tumors

Mouse Mammary Tumor Virus (MMTV) and MMTV-like Viruses: An In-depth Look at a Controversial Issue

Since its discovery as a milk factor, mouse mammary tumor virus (MMTV) has been shown to cause mammary carcinoma and lymphoma in mice. MMTV infection depends upon a viral superantigen (sag)-induced immune response and exploits the immune system to establish infection in mammary epithelial cells when they actively divide. Simultaneously, it avoids immune responses, causing tumors through insertional mutagenesis and clonal expansion. Early studies identified antigens and sequences belonging to a virus homologous to MMTV in human samples. Several pieces of evidence fulfill a criterion for a possible causal role for the MMTV-like virus in human breast cancer (BC), though the controversy about whether this virus was linked to BC has raged for over 40 years in the literature. In this review, the most important issues related to MMTV, from its discovery to the present days, are retraced to fully explore such a controversial issue. Furthermore, the hypothesis of an MMTV-like virus raised the question of a potential zoonotic mouse–man transmission. Several studies investigate the role of an MMTV-like virus in companion animals, suggesting their possible role as mediators. Finally, the possibility of an MMTV-like virus as a cause of human BC opens a new era for prevention and therapy.

Lessons Learned from Mouse Mammary Tumor Virus in Animal Models

Mouse mammary tumor virus (MMTV), which was discovered as a milk-transmitted, infectious, cancer-inducing agent in the 1930s, has been used as an animal model for the study of retroviral infection and transmission, antiviral immune responses, and breast cancer and lymphoma biology. The main target cells for MMTV infection in vivo are cells of the immune system and mammary epithelial cells. Although the host mounts an immune response to the virus, MMTV has evolved multiple means of evading this response. MMTV causes mammary tumors when the provirus integrates into the mammary epithelial and lymphoid cell genome during viral replication and thereby activates cellular oncogene expression. Thus, tumor induction is a by-product of the infection cycle. A number of important oncogenes have been discovered by carrying out MMTV integration site analysis, some of which may play a role in human breast cancer.

Genes affected by mouse mammary tumor virus (MMTV) proviral insertions in mouse mammary tumors are deregulated or mutated in primary human mammary tumors

The accumulation of mutations is a contributing factor in the initiation of premalignant mammary lesions and their progression to malignancy and metastasis. We have used a mouse model in which the carcinogen is the mouse mammary tumor virus (MMTV) which induces clonal premalignant mammary lesions and malignant mammary tumors by insertional mutagenesis. Identification of the genes and signaling pathways affected in MMTV-induced mouse mammary lesions provides a rationale for determining whether genetic alteration of the human orthologues of these genes/pathways may contribute to human breast carcinogenesis. A high-throughput platform for inverse PCR to identify MMTV-host junction fragments and their nucleotide sequences in a large panel of MMTV-induced lesions was developed. Validation of the genes affected by MMTV-insertion was carried out by microarray analysis. Common integration site (CIS) means that the gene was altered by an MMTV proviral insertion in at least two independent lesions arising in different hosts. Three of the new genes identified as CIS for MMTV were assayed for their capability to confer on HC11 mouse mammary epithelial cells the ability for invasion, anchorage independent growth and tumor development in nude mice. Analysis of MMTV induced mammary premalignant hyperplastic outgrowth (HOG) lines and mammary tumors led to the identification of CIS restricted to 35 loci. Within these loci members of the Wnt, Fgf and Rspo gene families plus two linked genes (Npm3 and Ddn) were frequently activated in tumors induced by MMTV. A second group of 15 CIS occur at a low frequency (2-5 observations) in mammary HOGs or tumors. In this latter group the expression of either Phf19 or Sdc2 was shown to increase HC11 cells invasion capability. Foxl1 expression conferred on HC11 cells the capability for anchorage-independent colony formation in soft agar and tumor development in nude mice. The published transcriptome and nucleotide sequence analysis of gene expression in primary human breast tumors was interrogated. Twenty of the human orthologues of MMTV CIS associated genes are deregulated and/or mutated in human breast tumors.

Hippo signaling pathway and organ size control

Initially discovered in Drosophila, the Hippo (Hpo) pathway has been recognized as a conserved signaling pathway that controls organ size during development by restricting cell growth and proliferation and by promoting apoptosis. In addition, abnormal activities of several Hpo pathway components have been implicated in human cancer. Here, we review the current understanding of the molecular and cellular basis of Hpo signaling in development and tumorigenesis, and discuss how the Hpo pathway integrates spatial and temporal signals to control tissue growth and organ size.

Premalignant and malignant mammary lesions induced by MMTV and chemical carcinogens

This article reviews the types of mammary premalignant and malignant lesions induced in the mouse mammary gland after exposure to MMTV and chemical carcinogens. There are different morphological types of hyperplastic lesions in the mouse mammary gland. These lesions are designated as alveolar hyperplasia (HAN), ductal hyperplasia (DH), and cystic lesions; both non-keratinized and keratinized. The HAN and DH have been demonstrated to be precursors to invasive lesions. The HAN as a group tend to be ovarian-hormone independent for growth and transformation, mammary fat pad site-dependent for growth, possess unlimited replication potential (i.e., immortal), are at increased risk for progression to cancer, and are genetically stable. Serial transplantation demonstrates that any given stage of hyperplasia can progress to the next stage, sometimes rapidly and sometimes slowly. Multiple growth factor pathways are deregulated early in the development of HAN depending on etiology of the HAN. One general conclusion that emerges from such studies of HAN induced by different etiologies is that the early stages of premalignancy are a result of defects in cell cycle regulation with subsequent alterations playing a role in the acquisition of invasive phenotype. The predominant lesion induced by chemical carcinogens is the ductal hyperplasia (DH). Although DH show many of the essential biological alterations seen in HAN, they also exhibit a higher frequency of hormone-dependence and genetic instability, thus the DH appearing in chemical carcinogen treated mice and in transgenic mice mimic the histological, biological and genetic properties seen in human premalignant lesions more faithfully than do the HAN. The mammary tumors that arise from both general classes of premalignant lesions are very heterogeneous and exhibit different potentials for metastasis. The cell and molecular biology of metastasis represents an understudied area, in part because of the absence of suitable models to study the metastatic process. Newer transgenic mouse models provide a renewed opportunity to engage in the study of the mechanisms and processes underlying mammary metastasis.

Number of pregnancies and ovariectomy modify mammary carcinoma development in transgenic HER-2/neu female mice

We studied effect of pregnancy and ovariectomy on the development of mammary tumors in homozygous female HER-2/neutransgenic mice. The mean life span of uniparous mice was decreased by 16% in comparison to the control (P<0.05) and of mice which have two pregnancies decreased by 11% (P<0.05). Ovariectomy at the age of 2 months was followed by 32.7% increase in mean life span of mice. The incidence or multiplicity of mammary adenocarcinomas did not change in uniparous mice, whereas the size of the tumors and metastatic potential were decreased as compared to the virgins. When mice have two full-time pregnancies, there was an increase in multiplicity of mammary carcinomas and significant (2.1-fold) decrease in the survival time of tumor-bearing mice. Ovariectomy significantly decreased the total incidence of mammary carcinomas, the number of tumors per tumor-bearing animal, and inhibited metastasizing into lungs. Our results indicate that pregnancy accelerated the development of mammary adenocarcinomas in transgenic HER-2/neu mice whereas ovariectomy inhibits their development.

The preneoplastic phenotype in murine mammary tumorigenesis

Preneoplastic lesions in murine mammary tumorigenesis have been extensively investigated over the past 50 years. The two general types of lesion that have malignant potential are the alveolar hyperplasias represented by the classical hyperplastic alveolar nodule and the ductal hyperplasias. The former type of lesion is induced by viral, chemical and hormonal agents; the latter by chemical agents and specific genetic alterations. Individual animal models have been utilized to elucidate the basic biological properties of the lesions and some of the basic molecular alterations. The biological phenotype of the two types of lesions include immortalization and epithelial hyperplasia. The ductal hyperplasias are distinguished from the alveolar hyperplasias by their pattern of epithelial hyperplasia and their extent of aneuploidy. The molecular alterations underlying epithelial hyperplasia are numerous and dependent on the particular animal model. An important issue for future studies is how faithfully any of these models mimic human premalignant progression. A minimal set of criteria is proposed that includes morphological progression, hormone dependence and genetic instability. It is likely that hyperplasias from a specific mouse model will represent a subset of the lesions found in human disease. Analogous hyperplasias from several defined genetic models, adequately characterized at the biological and molecular levels, would provide appropriate models for testing chemopreventive agents.

MMTV-induced mammary tumorigenesis: gene discovery, progression to malignancy and cellular pathways

The study of the mouse mammary tumor virus (MMTV) has provided important insights into the mechanisms of gene transcription regulation by steroid hormones, the mode of action of heritable super antigens and the progressive nature of neoplastic transformation in the mammary gland. Here we describe the current situation with respect to the latter aspect of MMTV biology and the prospects for further advance in our understanding of breast cancer in humans that may be expected from a continued study of MMTV-induced mammary neoplasia. MMTV is a heritable somatic mutagen whose target range is limited. Commonly, the tumorigenic capacity of MMTV is restricted to mammary gland, whereas infection is found in a variety of cell types. In order to replicate, proviral DNA must be inserted into the cell DNA and cell division is required to fix the mutation. Yet only in the mammary epithelium does this lead to neoplastic transformation. This suggests a unique relationship between MMTV and mammary epithelium. In evaluating this relationship, we and others have discovered genes and potential gene pathways that are pertinent in mammary differentiation and neoplasia. In addition, the clonal nature of these progressive events from normal to malignant phenotype has become increasingly clear. The weight of these observations compel us to conclude that mammary neoplasms arise from multipotent mammary epithelial cells through a process of acquired mutations that are reflected in the increasingly malignant nature of the population of progeny produced by these damaged stem cells.

MMTV-induced mutations in mouse mammary tumors: their potential relevance to human breast cancer

In mouse mammary tumor virus (MMTV) infected mice, three identifiable stages of mammary tumorigenesis can be biologically defined: preneoplastic hyperplastic nodules, malignant tumor, and distant metastatic lesions (primarily in the lung). MMTV is a biological carcinogen which induces somatic mutations as consequence of its integration into the host cellular genome. Each stage of mammary tumorigenesis appears to result from the clonal outgrowth of cells containing additional integrated proviral MMTV genomes. This phenomenon has provided the basis for an approach to identify genes which, when affected, may contribute to progression through the different stages of mammary tumorigenesis. Eight different genes (Wnt1, Wnt3, Wnt10b, Fgf3, Fgf4, Fgf8, Int3, and Int6) have been shown to be genetically altered in multiple mammary tumors as a consequence of MMTV integration. Although the significance of the human homologs of these genes as targets for somatic mutation during human breast carcinogenesis is only now being explored, it is clear that this work has led to a new appreciation of the complexity of the genetic circuitry that is involved in the control of normal mammary gland growth and development. It seems likely that some of the mutations induced by MMTV, and the signaling pathways in which these target genes take part, will be relevant to the progression from preneoplastic lesions to distant metastasis in human breast cancer.

Effect of virus infection on levels of transcripts for cellular genes

Malignant rabbit fibroma virus (MV) induces tumors composed of proliferating cells, principally fibroblasts, and vasculature. These tumors are associated with large amounts of collagen and other connective tissue proteins. We studied the effect of MV infection on levels of mRNA for alpha 1 chains of collagens type I, III and V in RK-13 fibroblasts and alpha 2 chain of collagen type I. MV infection induces expression of specific collagen genes at particular time points after infection in vitro. Expression of these collagen genes is clearly different in MV-infected cells compared to uninfected cells. Transcript levels for a cellular transcription factor that regulates expression of alpha 1 chain type I collagen, cbf-a, were increased in MV-infected cells prior to the increase in type I collagen mRNA. The virus infection also specifically induced increased levels of mRNA for the cellular transcription factors c-fos and SP1. MV infection is therefore associated with increased levels of specific cellular mRNAs, and is correspondingly associated with increased mRNA for transcription factors that may regulate transcription of these genes. The ability of malignant fibroma virus to influence expression of cellular genes may be exerted through the cells' own transcription regulatory apparatus.

Mouse mammary-tumor virus activates Fgf-3/Int-2 less frequently in tumors from virgin than from parous mice

Tumorigenesis by mouse mammary-tumor virus (MMTV) involves proviral disruption and transcriptional activation of a number of cellular oncogenes, generically termed Int. The frequencies with which different Int genes are activated in different mouse strains can be quite variable, and previous surveys have suggested that insertions at Int-2/Fgf-3 occur primarily in strains that develop pregnancy-dependent mammary tumors. To address this issue, we have determined the relative contributions of 5 known Int genes (Wnt-1, Wnt-3, Fgf-3, Fgf-4 and Int-3) in mammary tumors from virgin BR6 and multiparous BR6, BALB/cfBR6 and RIII mice. Whereas Fgf-3 was implicated in 66%, 80% and 92% of the tumors from the respective parous animals, only 20% of the tumors from virgin mice expressed Fgf-3. This reduced involvement of Fgf-3 was compensated by proviral insertions in Fgf-4, Int-3 and Wnt-3, but the frequency of Wnt-1 activation was relatively constant. These data strengthen the link between Fgf-3 and a pregnancy-dependent phenotype and suggest that, in the strains analyzed, the frequency of Int-gene activation was influenced more by the hormonal status than by the genetic background.