Eva Matouskova

Large expansion of morphologically heterogeneous mammary epithelial cells, including the luminal phenotype, from human breast tumours

Regular expansion of heterogeneous populations of epithelial cells, including the luminal phenotype, was achieved from small biopsies of human breast tumours and cutaneous metastases by optimized feeder layer technique based on irradiated NIH 3T3 cells. Forty-one out of 47 primary tumour specimens and all three cutaneous metastases grew successfully for two to 10 passages in vitro. The main phenotypes of cultured cells and their changes in subcultures were characterized using immunocytochemistry and phase contrast microscopy (in few cases also time-lapse recording). In the majority of cultured cell populations a fraction of cells positive for keratin 19 (K19+), typical for the luminal phenotype, was detected. This is the cell type from which breast carcinoma is supposed to arise. While in cultures derived from benign lesions only basic phenotypes of luminal and myoepithelial cells were found, in cultures derived from malignant tumours unusual phenotypes of epithelial cells, in their majority K19+, were detected. The growth properties of cells from six benign and seven malignant samples were analyzed in detail. In the analyzed cell populations the culture lifetime – related to the number of colony-forming cells – varied for cells from malignant tumours between 21 and 51 and from benign tumours between 22 and 40 cell generations. The total number of passages achieved was three to seven for malignant or four to nine for benign cultures. In spite of negative results of tumourigenicity testing in immunologically compromised Nu/nu mice the potential to culture apparently neoplastic cells was indicated by positive immunostaining for the p53 oncoprotein (seven of 23 tested malignant cases), the src oncoprotein (five of eight), and overexpression of the c-erbB-2 protein (five of 26). This was further confirmed by successful cultivation of malignant cells from cutaneous metastases. Two of the three metastasis-derived cultures were nearly homogeneously positive for K19 while the third was almost negative. The results proved the optimized feeder layer technique to be useful for regular yielding of large amounts of epithelial cells from small tumour biopsies and for supporting the majority of cell phenotypes present in the original tumour. Therefore, it appeared to be a promising tool for further analysis of interactions between luminal and myoepithelial cells in the development of human breast carcinoma and for the study of individual tumours.

Temporal in vitro expansion of the luminal lineage of human mammary epithelial cells achieved with the 3T3 feeder layer technique.

Human mammary epithelial cells from reduction mammoplasties were serially propagated in vitro from single cells and/or cell clusters using the NIH 3T3 cell feeder layer technique. In seven passages 46 cell population doublings, corrected for plating efficiency were achieved. The plating efficiency of epithelial cells in the primary culture was 0.2%. During subsequent passages it rose to 10–12% and decreased sharply towards the end of the culture life. In the third and fourth passages temporal prevalence of luminal cells was observed. The critical conditions for prevalence of the 1uminal phenotype were found to be the initial dissociation and optimum seeding density during subculturing. In primary cultures, after optimum dissociation of 0.15 cm3 mammary tissue with 0.05% collagenase A (Boehringher‐Mannheim) in Eagles MEM for 16 h at 37 °C, the yield on day 13 was 20 large colonies of 8–10 mm diameter. About 30% of the epithelial cells, which stained positively for the luminal cell marker cytokeratin 19, occupied colony centres. The remaining 70% were actin positive myoepithelial cells at the periphery. In subsequent passages, when using the optimum seeding density of 2×105 cells per 60 mm culture dish, the proportion of luminal cells gradually increased to 90% on day 35 in the fourth passage. A sudden rise in the proportion of rapidly growing myoepithelial cells to 65% was observed in the fifth passage. In the sixth and seventh passage small colonies were formed, most of which contained at least one keratin‐19‐positive (luminal) cell. Cells of human breast carcinomas are considered to be of luminal origin. Therefore, the described approach can be useful in studies of cell and molecular biology of mammary carcinomas.

Human Keratinocyte Growth and Differentiation on Acellular Porcine Dermal Matrix in relation to Wound Healing Potential

A number of implantable biomaterials derived from animal tissues are now used in modern surgery. Xe-Derma is a dry, sterile, acellular porcine dermis. It has a remarkable healing effect on burns and other wounds. Our hypothesis was that the natural biological structure of Xe-Derma plays an important role in keratinocyte proliferation and formation of epidermal architecture in vitro as well as in vivo. The bioactivity of Xe-Derma was studied by a cell culture assay. We analyzed growth and differentiation of human keratinocytes cultured in vitro on Xe-Derma, and we compared the results with formation of neoepidermis in the deep dermal wounds treated with Xe-Derma. Keratinocytes cultured on Xe-Derma submerged in the culture medium achieved confluence in 7–10 days. After lifting the cultures to the air-liquid interface, the keratinocytes were stratified and differentiated within one week, forming an epidermis with basal, spinous, granular, and stratum corneum layers. Immunohistochemical detection of high-molecular weight cytokeratins (HMW CKs), CD29, p63, and involucrin confirmed the similarity of organization and differentiation of the cultured epidermal cells to the normal epidermis. The results suggest that the firm natural structure of Xe-Derma stimulates proliferation and differentiation of human primary keratinocytes and by this way improves wound healing.

Prevention of burn wound conversion by allogeneic keratinocytes cultured on acellular xenodermis.

Deep dermal burns frequently tend to convert into full-thickness skin loss. We found that this wound deepening may be prevented by recombined human/pig skin (RHPS), consisting of human allogeneic keratinocytes cultured on acellular pig dermis. RHPS has skin-like consistency and therefore optimal adhesiveness to the wound. It can be easily removed from the dish and transferred to the recipient. The wound bed has to be prepared by tangential excision or deep dermabrasion to the level of capillary bleeding. RHPS has to be applied ‘upside-down’, with the epidermal layer facing the wound, to avoid the dermal matrix forming a barrier to the nutrients for the keratinocytes. In our practice, more than 70% of early excised or deeply dermabraded wounds grafted with RHPS healed in the course of one week after keratinocyte transplantation.

Three-dimensional organization of actin cytoskeleton and podosomal contact structures in neoplastic cells in vitro

In spontaneously metastasizing rat RPS sarcoma cells, a 3D structure of oblique F-actin cables was observed which was associated with active cell migration in vitro. This led us to further comparative investigations of several other neoplastic and normal cell populations in vitro for F-actin structures using confocal laser scanning microscopy (CLSM). Various forms of F-actin cytoskeleton were observed and the incidence of podosome-related contact structures appeared to be associated with malignancy, interpreted as metastatic capacity.