Identification of a functional domain in a GADD45-mediated G2/M checkpoint.

Cell cycle checkpoints are essential for the maintenance of genomic stability in response to DNA damage. We demonstrated recently that GADD45, a DNA damage-inducible protein, activates a G(2)/M checkpoint induced by either UV radiation or alkylating agents. GADD45 can interact in vivo with the G(2) cell cycle-specific kinase, Cdc2, proliferating cell nuclear antigen (PCNA), and the cell cycle kinase inhibitor p21(waf1). The ability of GADD45 to induce a G(2)/M arrest may be caused in part by the inhibition of Cdc2 kinase activity. Here, we report the identification of a region of GADD45 that is involved in this G(2)/M checkpoint. Mutants of GADD45 that lacked either the first 35 or the last 80 residues still retained an ability to induce G(2)/M arrest. A mutant with a deletion of the central region (residues 50-76), which is conserved in the family members GADD45beta and GADD45gamma, lacked such activity. This mutant also lacked an ability to bind to Cdc2, PCNA, and p21(waf1) in vivo. Consistently, either GADD45beta or GADD45gamma bind to Cdc2 in vivo. However, unlike GADD45, neither GADD45beta nor GADD45gamma inhibited the Cdc2 kinase or induced G(2)/M arrest. The unique effect of GADD45 may be caused by the presence of a region containing DEDDDR residues. Alanine substitutions in the region abolished GADD45 induction of a G(2)/M arrest and its inactivation of the Cdc2 kinase but not its binding to Cdc2, PCNA, or p21(waf1). Therefore, the binding of GADD45 to Cdc2 was insufficient to induce a G(2)/M arrest, and additional activity contributed by the DEDDDR residues may be necessary to regulate the G(2)/M checkpoint.

GADD45 induction of a G2/M cell cycle checkpoint.

G1/S and G2/M cell cycle checkpoints maintain genomic stability in eukaryotes in response to genotoxic stress. We report here both genetic and functional evidence of a Gadd45-mediated G2/M checkpoint in human and murine cells. Increased expression of Gadd45 via microinjection of an expression vector into primary human fibroblasts arrests the cells at the G2/M boundary with a phenotype of MPM2 immunopositivity, 4n DNA content and, in 15% of the cells, centrosome separation. The Gadd45-mediated G2/M arrest depends on wild-type p53, because no arrest was observed either in p53-null Li-Fraumeni fibroblasts or in normal fibroblasts coexpressed with p53 mutants. Increased expression of cyclin B1 and Cdc25C inhibited the Gadd45-mediated G2/M arrest in human fibroblasts, indicating that the mechanism of Gadd45-mediated G2/M checkpoint is at least in part through modulation of the activity of the G2-specific kinase, cyclin B1/p34(cdc2). Genetic and physiological evidence of a Gadd45-mediated G2/M checkpoint was obtained by using GADD45-deficient human or murine cells. Human cells with endogenous Gadd45 expression reduced by antisense GADD45 expression have an impaired G2/M checkpoint after exposure to either ultraviolet radiation or methyl methanesulfonate but are still able to undergo G2 arrest after ionizing radiation. Lymphocytes from gadd45-knockout mice (gadd45 -/-) also retained a G2/M checkpoint initiated by ionizing radiation and failed to arrest at G2/M after exposure to ultraviolet radiation. Therefore, the mammalian genome is protected by a multiplicity of G2/M checkpoints in response to specific types of DNA damage.

Genomic instability and telomerase activity in human bronchial epithelial cells during immortalization by human papillomavirus-16 E6 and E7 genes.

Human papilloma virus types 16 and 18 contribute to the development of cervical carcinomas in which the E6 and E7 genes are frequently retained and expressed in the tumors. Our study explored the ability of the E6 and/or E7 genes to immortalize normal human bronchial epithelial (NHBE) cells and to reactivate telomerase expression in these cells. We have introduced the human papillomavirus type 16 E6 or E7 genes alone or in combination (E6/E7) into NHBE cells using the retroviral construct pLXSN. Cells expressing either the E6 or the E7 oncoproteins alone displayed an increased colony-forming efficiency and a slightly extended in vitro life span before entering a crisis, from which immortalized cell lines were not obtained. Telomerase activity was not detected in cells expressing either E6 or E7 individually. Cells expressing the E6/E7 oncoproteins in combination had a substantially increased life span before entering crisis. A subpopulation of these cells escaped from crisis and achieved 130 population doublings, suggesting immortalization. Telomerase activity was detected in these postcrisis cells, but was not detected prior to crisis. In addition, karyotypic analysis showed evidence of genomic instability in mass cultures as well as clones expressing E6, E7, or E6/E7. Abnormalities included numerous monosomies and trisomies, chromatid gaps and breaks, double minutes, and aberrant chromosomes. These results demonstrate that expression of E6 and/or E7 is sufficient to induce genomic instability and an extended life span to NHBE cells, but the presence of both E6 and E7, along with at least one additional genetic or epigenetic event achieved during crisis, was required for reactivation of telomerase and the immortalization in this human cell type.

Differential effects of p53 mutants on the growth of human bronchial epithelial cells.

We investigated the effects of five different p53 mutants on the growth of primary cultures of normal human bronchial epithelial (NHBE) cells. The five defective viral pZIP-Neo constructs contained the following mutations at mutational hot-spots found in human cancers: codons 143ala, 175his, 248trp, 249ser, and 273his. NHBE cells were infected with the p53 mutants, wild-type p53, or the pZIP-Neo vector control. The 143ala, 248trp, and 273his mutants, as well as wild-type p53, decreased the colony-forming efficiency and inhibited the growth of NHBE cells. The 175his mutant did not significantly change the growth rates. In NHBE cells from three donors, the 249ser mutant conferred a substantial growth advantage to the NHBE cells in a colony-forming-efficiency assay. In NHBE cells isolated from one donor, the 249ser mutant also produced a significant life span extension. These cells grew rapidly through 80 population doublings and entered an apparent "crisis" in passage 14. Karyotypic analyses of one culture at multiple passages revealed aneuploid populations with alterations of chromosomes 5, 11, and 13; quantitative DNA analysis detected aneuploidy in late passages from that culture and two other primary cultures. These data demonstrated that the codon 249ser mutation could provide a growth advantage to bronchial epithelial cells and suggest that this mutant protein can induce genomic instability.

The XPB and XPD DNA helicases are components of the p53-mediated apoptosis pathway.

The molecular pathway of p53-dependent apoptosis (programmed cell death) is poorly understood. Because p53 binds to the basal transcription-repair complex TFIIH and modulates its DNA helicase activities, we hypothesized that TFIIH DNA helicases XPB and XPD are members of the p53-mediated apoptotic pathway. Whereas transfer of a wild-type p53 expression vector by microinjection or retroviral infection into primary normal human fibroblasts resulted in apoptosis, primary fibroblasts from individuals with xeroderma pigmentosum (XP), who are deficient in DNA repair and have germ-line mutations in the XPB or XPD gene, but not in the XPA or XPC gene, have a deficiency in the apoptotic response. This deficiency can be rescued by transferring the wild-type XPB or XPD gene into the corresponding mutant cells. XP-D lymphocytes also have a decreased apoptotic response to DNA damage by adriamycin, indicating a physiologically relevant deficiency. The XP-B or XP-D mutant cells undergo a normal apoptotic response when microinjected with the Ich-L, and ICE genes. Analyses of p53 mutants and the effects of microinjected anti-p53 antibody, Pab421, indicate that the carboxyl terminus of p53 may be required for apoptosis. Direct microinjection of the p53 carboxy-terminal-derived peptide (amino acid residues 319-393) resulted in apoptosis of primary normal human fibroblasts. These results disclose a novel pathway of p53-induced apoptosis.