Genetic instability and divergence of clonal populations in colon cancer cells in vitro.

The accumulation of multiple chromosomal abnormalities is a characteristic of the majority of colorectal cancers and has been attributed to an underlying chromosomal instability. Genetic instability is considered to have a key role in the generation of genetic and phenotypic heterogeneity in cancer cells. To shed light on the dynamics of chromosomal instability in colon cancer cells, we have analyzed genetic divergence in clonal and subclonal derivates of chromosomally unstable (SW480) and stable (HCT116, LoVo) cell lines. Conventional G-banding karyotyping and arbitrarily primed PCR (AP-PCR) fingerprinting were used to calculate genetic distances among clones and parental cells, and to trace tree-type phylogenies among individual cells and clonal cell populations. SW480 cells showed enhanced karyotypic heterogeneity in clones as compared with parental cells. Moreover, genetic clonal divergence was also increased after two consecutive episodes of single-cell cloning, demonstrating that the homogeneity induced by the bottleneck of cloning is disrupted by genetic instability during clonal expansion and, as a consequence, heterogeneity is restored. These results demonstrate genetic drift in clonal populations originated from isolated cells. The generated cell heterogeneity coupled with selection provides the grounds for the reported feasibility of pre-neoplastic and neoplastic cells to generate new phenotypic variants with increased evolutionary potential.

p21(WAF1/CIP1) acts as a brake in osteoblast differentiation.

Continuous fibroblast growth factor signaling inhibits the differentiation of primary osteoblasts and osteoblastic cell lines. We studied the expression of several cell cycle regulatory molecules in response to fibroblast growth factor, and found that fibroblast growth factor strongly upregulates the expression of p21(WAF1/CIP1), a CDK inhibitor that has also been implicated in the regulation of apoptosis and cell differentiation. To test the hypothesis that p21 mediated the fibroblast growth factor effects on osteoblasts, we studied the differentiation of primary osteoblasts and osteoblastic cell lines derived from p21 null mice in the presence or absence of fibroblast growth factor. While the results obtained indicate that p21 is not the major mediator of the inhibition of osteoblast differentiation by fibroblast growth factor, we found that p21 per se acts as a brake on osteoblast proliferation and differentiation. p21 is strongly downregulated during differentiation and is highly expressed in osteoblastic cell lines expressing activated FGFR2, which do not differentiate. p21 null osteoblasts differentiate faster than wild-type cells, are more susceptible to the differentiation-promoting action of BMP-2, and undergo increased differentiation-related apoptosis. Furthermore, transient overexpression of p21 from an adenovirus vector delayed the onset of differentiation both in wild-type and in p21 null osteoblasts. These results highlight a new function for p21 in osteoblast differentiation.

The structural nature of chromosomal instability in colon cancer cells.

Biological and genetic cell heterogeneity is a landmark of most colorectal cancers and provides a frame for tumor progression as an evolutional process. Classical models have hypothesized that increased genetic instability may contribute to modulating and shaping malignant transformation. This is true for the small subset of colorectal cancers displaying microsatellite instability. For the rest of colorectal tumors, numerical and/or structural chromosomal alterations are the most prominent outcome of genetic disruption. These observations have prompted some investigators to hypothesize about the presence of chromosomal instability in these cells. To characterize chromosomal instability in cancer cells, we have analyzed genetic clonal divergence in three colorectal cancer cell lines considered to be archetypes in cancer research (HCT116, LoVo, and SW480). A dynamic setting was designed to allow the calculation of mutation rates. Comprehensive analyses at the chromosomal level revealed distinctive patterns of genetic divergence. Aneuploid SW480 cells displayed high rates of structural alterations (>100-fold) as compared with near diploid LoVo cells. Numerical alterations also occurred more frequently in SW480 cells but at low rates as compared with rearrangements in the chromosomically unstable SW480 cells. These results strengthen the role of structural instability in the generation of genetic heterogeneity in colorectal cancer.