Directional selection associated with clonal expansion of p53 mutant cells during neoplastic development of carcinogen-treated rat embryo lung epithelial cells.

In this study, rat embryo lung organ cultures were exposed to benzo[a]pyrene (B[a]P). After carcinogen-treatment the cells were dissociated and an epithelial cell line (BP) was developed from the primary cell culture derived from the carcinogen-treated explants. Investigations were performed on the sequential changes occurring in the course of neoplastic progression of BP cells and in the tumor cells that arose in vivo from implanted BP cells. During the neoplastic progression a mutation was shown to occur in p53 gene at codon 130 (AAG > AGG; Lys > Arg) in a single cell which expanded and gave rise to a predominant subpopulation. This mutational event was already detected at passage 14 but was probably not a direct consequence of a specific alteration caused by the carcinogen in the target cell. This mutation was retained through the subsequent progressional steps first as a heterozygous mutation, then converted to a homozygous state. From passage 18 on, it was possible in BP cell cultures to detect foci of larger morphologically distinct cells emerging on a background of cells maintaining the original morphology. These foci were shown to derive from a single cell carrying the p53 mutation in a homozygous state. During the neoplastic progression the mutant p53 allele frequency steadily increased and this mutant allele eventually came to predominate completely in the late stages of the neoplastic progression, including in the transplantation-induced tumors. The pattern of a directional selection for mutant p53 gene towards fixation is probably applicable to a wide range of human malignancies and may reflect the particular importance of this gene for tumorigenesis.

Cellular responses to DNA damage in the absence of Poly(ADP-ribose) polymerase.

Poly(ADP-ribose) polymerase (PARP) is a nuclear enzyme which is catalytically activated by DNA strand interruptions. The involvement of PARP has been implicated in different cellular responses to genotoxic damage, including cell survival, DNA repair, transformation, and cell death. However, the exact contribution of PARP polypeptide or its enzymatic product has remained ill defined. Recent studies with two different PARP knock out mice have demonstrated the beneficial role of PARP in maintaining genomic integrity and in survival responses after exposure to whole body gamma-irradiation. Other studies have demonstrated the instrumental role of PARP in death of the neuronal cells after ischemia-reperfusion injury. The recombination inhibiting function of PARP at DNA strand breaks was more evident in a model system deficient in activities of two major DNA strand break binding proteins, PARP and DNA-dependent protein kinase. The present review summarizes similarities and differences obtained with the two PARP knock out mice and reanalyzes the role of PARP in various cellular responses to DNA damage.