Mesenchymal stem cells as therapeutic tools and gene carriers in liver fibrosis and hepatocellular carcinoma.

Mesenchymal stem (stromal) cells (MSCs) are a source of circulating progenitors that are able to generate cells of all mesenchymal lineages and to cover cellular demands of injured tissues. The extent of their transdifferentiation plasticity remains controversial. Cells with MSC properties have been obtained from diverse tissues after purification and expansion in vitro. These cellular populations are heterogeneous and under certain conditions show pluripotent-like properties. MSCs present immunosuppressive and anti-inflammatory features and high migratory capacity toward inflamed or remodeling tissues. In this study we review available data regarding factors and signaling axes involved in the chemoattraction and engraftment of MSCs to an injured tissue or to a tissue undergoing active remodeling. Moreover, experimental evidence in support of uses of MSCs as vehicles of therapeutic genes is discussed. Because of its regenerative capacity and its particular immune properties, the liver is a good model to analyze the potential of MSC-based therapies. Finally, the potential application of MSCs and genetically modified MSCs in liver fibrosis and hepatocellular carcinoma (HCC) is proposed in view of available evidence.

VEGF/VPF overexpression in skin of transgenic mice induces angiogenesis, vascular hyperpermeability and accelerated tumor development.

Upregulation of keratinocyte-derived VEGF-A expression has recently been established in non-neoplastic processes of skin such as wound healing, blistering diseases and psoriasis, as well as in skin neoplasia. To further characterize the effects of VEGF-A in skin in vivo, we have developed transgenic mice expressing the mouse VEGF120 under the control of a 2.4 kb 5' fragment of keratin K6 gene regulatory sequences that confers transgene inducibility upon hyperproliferative stimuli. As expected from the inducible nature of the transgene, two of the three founder mice obtained (V27 and V208), showed no apparent phenotype. However, one founder (V2), mosaic for transgene integration, developed scattered red spots throughout the skin at birth. The transgenic offspring derived from this founder developed a striking phenotype characterized by swelling and erythema, resulting in early postnatal lethality. Histological examination of the skin of these transgenics demonstrated highly increased vascularization and edema leading to disruption of skin architecture. Expression of the transgene was silent in adult animals of lines derived from founders V27 and V208. Phorbol ester-induced hyperplasia resulted in transgene induction and increased cutaneous vascularization in adult transgenic mice of these lines. Skin carcinogenesis experiments performed on hemizygous crosses of V208 mice with activated H-ras-carrying transgenic mice (TG.AC) resulted in accelerated papilloma development and increased tumor burden. Previous results from our laboratory showed that VEGF upregulation is a major angiogenic stimulus in mouse epidermal carcinogenesis. By overexpressing VEGF in the skin of transgenic mice we now move a step further toward showing that VEGF-mediated angiogenesis is a rate-limiting step in the genesis of premalignant lesions, such as mouse skin papilloma. Our transgenic mice constitute an interesting model system for in vivo study of the cutaneous angiogenic process and its relevance in tumorigenesis and other skin diseases.

Increased expression of mutated Ha-ras during premalignant progression in SENCAR mouse skin.

The ras proto-oncogene family products are membrane-associated, guanine nucleotide-binding proteins that serve as a molecular switch for signal transduction pathways in a diverse array of organisms. In the mouse skin two-stage carcinogenesis model, a specific point mutation in Ha-ras codon 61 is responsible for the initiation event. Here we investigated whether Ha-ras protein and mRNA expression change during premalignant progression. Also, we assessed the Ha-ras mutated allele after these changes. To those ends, we analysed the Ha-ras expression profiles in normal and hyperplastic skin, papillomas, and squamous cell carcinomas by western blotting, reverse transcription-polymerase chain reaction, and in situ hybridization. Increased levels of Ha-ras expression were observed at specific times during promotion. These changes were followed by an increase in the level of expression of the Ha-ras mutated allele. These results suggest that increased expression of Ha-ras mutated alleles may have an important role during premalignant progression.

Angiogenesis is an early event in the development of chemically induced skin tumors.

In this study we have analyzed the vascular response induced in the two-stage carcinogenesis model in SENCAR mice. The role of angiogenesis has not been explored in this model, which is the paradigm of multistage carcinogenesis and a model for neoplastic lesions derived from exophytic premalignant lesions (e.g. colon carcinoma, bladder papilloma). We investigated if angiogenesis is involved in the formation of papillomas and in the progression from papilloma to carcinoma. To this end we analyzed the vasculature of normal and hyperplastic skin, focal epidermal hyperplasias that are precursors of papillomas, papillomas at different stages and squamous cell carcinomas. We also analyzed the vascularization of papillomas induced in two strains of mice that differ in their susceptibility to malignant progression. We show here that angiogenesis is turned on in the earliest stages of papilloma formation. In late stages, regardless of state of progression, the predominant response is an increase in the size of blood vessels. Thus, in the SENCAR mouse model, representative of exophytic tumors, the angiogenesis switch is a very early event, probably mechanistically related to the development of the primarily exophytic lesions. Therefore, the density of blood vessels cannot be used as a predictor of malignant progression in this model.