Testis peritubular myoid cells increase their motility and express matrix-metalloproteinase 9 (MMP-9) after interaction with embryonal carcinoma cells.

Today cancer research studies have highlighted the role of the cancer-stroma interaction in the regulation of invasive processes. However, very little is known about cell-to-cell relationships between germinal cancer cells and the somatic ones belong to their close environment, particularly at early invasion stages. Here, we have studied the potential role of the seminiferous peritubular myoid cells (PTCs), as potential part of the reactive stroma, like tumor myofibroblast, in the progression of embryonal carcinoma (EC). To this end, we show results on the in vitro interactions between F9 murine embryonal carcinoma cells (EC cells) and primary cultures of murine PTCs, using contact-dependent and contact-independent 2D co-cultures. In these circumstances, when EC cells interact with PTCs they change their migratory behavior and matrix-metalloproteinase 9 (MMP-9) was up-regulated in PTCs. Additionally, among a variety of cytokines implicated in tumor-stroma cross-talk, we have examined in more detail the influence of tumor necrosis factor alpha (TNF-α). In this regard, it was observed that this cytokine induced a MMP-9 secretion by PTCs in a pattern dependent on its concentration, whereas does not increase the migration capacity of cancer cells. All together, our results provide evidence for a role played by peritubular myoid cells and cancer-cell secreted TNF- α for a change in the tumor microenvironment during the early stages of EC progression.

Evidence for a role of matrix metalloproteinases and their inhibitors in primordial germ cell migration.

Understanding the mechanisms that enable migrating cells to reach their targets is of vital importance, as several pathologies, including cardiac defects and some tumours, are consequences of altered cell migration. With a view to evaluating if matrix metalloproteinases (MMPs) and their tissue inhibitors (TIMPs) play a role in the active migration of primordial germ cells (PGCs) from their place of origin in extra-embryonic sites towards their final destination in the developing gonads, we analysed the expression of mRNAs encoding nine MMPs and four TIMPs in migrating (E10.5) and post-migrating (E12.5) PGCs by means of quantitative polymerase chain reaction and the presence of MT1-MMP in the membrane of these cells. Our results show that PGCs express MMP-2, MMP-9, MMP-11, MT1-MMP, TIMP-1, TIMP-2 and TIMP-3 at both migrating and non-migrating stages. Comparing expression levels of MMP genes between E10.5 and E12.5 PGCs revealed higher expression in migrating PGCs of MT1- MMP (10.3-fold), MMP-2 (4.8-fold), MMP-11 (3.2-fold) and MMP-9 (2.1-fold). Similarly, the levels of TIMP gene expression were always higher in E12.5 genital ridge somatic cells: TIMP-3 (3.4-fold), TIMP-1 (2.4-fold) and TIMP-2 (1.8-fold). Moreover, the analysis at protein level showed the presence of MT1-MMP in the membrane of migrating PGCs whereas the expression of these metalloproteinase is not detected once the PGCs have reach the urogenital ridges and stop migrating. These results suggest that the change from the motile to non-motile phenotype that occurs during PGC maturation to gonocytes may be mediated in part by enhanced expression of MMPs in migrating PGCs together with higher expression of TIMPs in E12.5 genital ridges.

Peritubular myoid cell-derived factors and its potential role in the progression of testicular germ cell tumours.

The tumour surrounding stroma, known as reactive stroma, is a crucial factor to understand cancer cell growth and invasion. In the normal adult testis, the stroma contains extracellular matrix components, fibroblasts, infiltrating leucocytes, lymphocytes, macrophages and capillaries, as well as other specific cell populations, like Leydig cells and a thin myoepithelium surrounding the seminiferous tubules constituted by the peritubular cells. All these cells are an important source of proliferation and survival promoting signals, proteolytic enzymes, migratory cues and pro-angiogenic factors. Ascribable to this pro-invasive activity, the tumour reactive stroma cells, especially cancer-associated myofibroblasts, have emerged as a promising target for cancer therapy. This review is focused on the potential role of the peritubular myoid cells in the development of testicular germ cell tumours as the precursors of cancer-associated myofibroblast and on an experimental model for the study of testis germinal cancer stroma and on the differences between normal and tumour-associated stromal cells, including the molecular mechanisms that mediate the important cancer stroma crosstalk. Special attention will be paid to the cancer-associated myofibroblasts as possible therapeutic targets, because they are one of the main components of the reactive stroma and are known to secrete a variety of paracrine factors that stimulate tumour progression.

Vascularization of testicular germ cell tumours: evidence from experimental teratocarcinomas.

Testicular germ cell tumours (TGCTs) represent about 2% of male malignancies, being the most common cancer among adolescents and young adults. As in most neoplasias, TGCTs show a chaotic vascular architecture, altered blood supply and over-expression of pro-angiogenic factors, aspects closely related to tumour overgrowth and metastasis. Following this trend, our laboratory has analysed the effect of the hypoxic tumour microenvironment on cancer stem cells, particularly the expression of factors related to vascularization, such as matrix metalloproteinases, adhesion molecules, vascular endothelial growth factors (VEGF) and VEGF receptors. This review also summarizes our present knowledge on vascularization in the normal and neoplastic testis, the potential role of the factors involved in TGCT neovascularization and their importance as possible therapeutic targets.

Angiogenesis and vascular network of teratocarcinoma from embryonic stem cell transplant into seminiferous tubules.

BACKGROUND: Carcinoma in situ (CIS) of the testis is considered to be a precancerous germinal cell lesion, but the precise cellular and molecular mechanisms underlying transformation of CIS into invasive pluripotent cancer cells remain to be elucidated. Moreover, a satisfactory animal model for the experimental study of germinal tumours has not been developed to date. METHODS: We have developed a tumour model that involves the microinjection of green fluorescent protein-labelled embryonic stem (ES) cells (which are functionally equivalent to CIS cells) into syngenic mouse seminiferous tubules, a unique cell microenvironment in which germinal cells mature and CIS arise. To characterise the vascularisation of teratocarcinomas, which arise after cell transplant, we used immunohistochemistry, together with a qualitative and quantitative analysis of scanning electron microscopy images of corrosion casting samples. RESULTS: Embryonic stem cells transplanted into seminiferous tubules did not differentiate into germinal cells, but rather they behaved as invasive embryonal carcinoma (EC) stem cells. The vascular pattern of the experimental teratocarcinomas showed a highly disorganised architecture, and some of the neoplastic capillaries were derived, at least in part, from the original transplanted ES cells. CONCLUSION: The transplantation of pluripotent ES cells into seminiferous tubules efficiently recapitulates the early stages of development of teratocarcinomas. Consequently, this method constitutes a novel in vivo model to study the mechanisms of invasion and progression of experimental germinal tumours.