Role of stromal fibroblasts in cancer: Promoting or impeding?

The basement membrane, immune cells, capillaries, fibroblasts and extracellular matrix (ECM) constitute the tumour stroma, commonly referred to as the 'reactive stroma'. The fibroblasts from the initial stages of a tumour, as the main constituents of the reactive stroma, present a different phenotype from the normal fibroblasts and play a crucial role in tumour progression. This review presents the differences between normal and tumour stromal fibroblasts and analyzes the molecular mechanisms (which involve growth factors, ECM components, matrix metalloproteinases, integrins and cell adhesion molecules) in the complex interactions between stromal fibroblasts and tumour cells. To date, several examples of heterotypic interactions between tumour stromal fibroblasts and tumour cells have supported the hypothesis that the tumour stroma promotes the growth of the tumour mass, as well as invasion and metastasis. However, it remains possible that the stroma acts essentially as a local modulator to impede tumorigenesis at an early stage and that the desmoplastic response is a host defence reaction designed to confine the developing tumour. The latter hypothesis has largely been neglected. The review aims to give a broader view on the role of stromal fibroblasts in tumour growth, invasion and metastasis. Copyright © 2009 S. Karger AG

Sub-toxic cisplatin concentrations induce extensive chromosomal, nuclear and nucleolar abnormalities associated with high malignancy before acquired resistance develops: Implications for clinical caution.

AimThis study investigates the impact of sub-toxic cisplatin levels on nuclear and nucleolar abnormalities and chromosome instability in HeLa cells since our current knowledge of cisplatin effects on these parameters is based on studies with high concentrations of cisplatin.Materials and methodsHeLa cells were exposed to gradually increasing sub-toxic doses of cisplatin (0.01 to 0.2 μg/ml). Cells treated with 0.1 and 0.2 μg/ml, termed HeLaC0.1 and HeLaC0.2, were not cisplatin-resistant, only exhibiting a slightly reduced viability, and were termed "cisplatin-sensitized cells." Giemsa and silver staining were used to detect nuclear and nucleolar abnormalities and chromosomal alterations.ResultsNotable abnormalities were observed in HeLaC0.1 and HeLaC0.2 cells after treatment with sub-toxic concentrations of cisplatin: nuclei showed abnormal shapes, blebs, micronuclei, fragmentation, pulverization, and multinucleation; nucleoli exhibited irregular shapes and increased numbers; anaphase cells showed more nucleolar organizing regions. Abnormal chromosome segregation, heightened aneuploidy (81-140 chromosomes), polyploidy, double minutes, dicentrics, chromatid exchanges, chromatid separations, pulverization, and chromosome markers were prominently noted. These abnormalities were intensified in cells pre-sensitized to 0.02 or 0.08 μg/ml cisplatin for seven days, then exposed to 0.03 or 0.1 μg/ml cisplatin for 24 hours, and finally cultured in cisplatin-free medium for 24 hours before chromosome analysis.ConclusionHeLa cells subjected to increasing concentrations of sub-toxic cisplatin exhibited large-scale, multiple-type abnormalities in nuclei, nucleoli, chromosomes, and chromosomal numbers, indicating genetic/chromosomal instability associated with high malignancy, before the development of cisplatin resistance. These results suggest that low doses of cisplatin administration in the clinical setting may promote malignancy and caution should be used with this type of treatment