Ennio Prosperi

Multiple roles of the cell cycle inhibitor p21CDKN1A in the DNA damage response

Among cell cycle regulatory proteins that are activated following DNA damage, the cyclin-dependent kinase inhibitor p21(CDKN1A) plays essential roles in the DNA damage response, by inducing cell cycle arrest, direct inhibition of DNA replication, as well as by regulating fundamental processes, like apoptosis and transcription. These functions are performed through the ability of p21 to interact with a number of proteins involved in these processes. Despite an initial controversy, during the last years several lines of evidence have also indicated that p21 may be directly involved in DNA repair. In particular, the participation of p21 in nucleotide excision repair (NER), base excision repair (BER), and DNA translesion synthesis (TLS), has been suggested to occur thanks to its interaction with proliferating cell nuclear antigen (PCNA), a crucial protein involved in several aspects of DNA metabolism, and cell-cycle regulation. In this review, the multiple roles of p21 in the DNA damage response, including regulation of cell cycle, apoptosis and gene transcription, are discussed together with the most recent findings supporting the direct participation of p21 protein in DNA repair processes. In particular, spatio-temporal dynamics of p21 recruitment to sites of DNA damage will be considered together with several lines of evidence indicating a regulatory role for p21. In addition, the relevance of post-translational regulation in the fate (e.g. degradation) of p21 protein after cell exposure to DNA damaging agents will be analyzed. Both sets of evidence will be discussed in terms of the overall DNA damage response.

Multiple roles of the proliferating cell nuclear antigen: DNA replication, repair and cell cycle control

The proliferating cell nuclear antigen (PCNA), the auxiliary protein of DNA polymerase delta and epsilon, is involved in DNA replication and repair. This protein forms a homotrimeric structure which, encircling DNA, loads the polymerase on the DNA template. A role for PCNA in the cell cycle control is recognised on the basis of the interaction with cyclins, cyclin-dependent kinases (cdks) and the cdk-inhibitor p21 waf1/cip1/sdi1 protein. Association with the growth-arrest and DNA-damage inducible proteins gadd45 and MyD118, further demonstrates the role of PCNA as a component of the cell cycle control apparatus.

Human proliferating cell nuclear antigen, poly(ADP-ribose) polymerase-1, and p21waf1/cip1. A dynamic exchange of partners

We addressed the analysis of the physical and functional association of proliferating cell nuclear antigen (PCNA), a protein involved in many DNA transactions, with poly(ADP-ribose) polymerase (PARP-1), an enzyme that plays a crucial role in DNA repair and interacts with many DNA replication/repair factors. We demonstrated that PARP-1 and PCNA co-immunoprecipitated both from the soluble and the DNA-bound fraction isolated from S-phase-synchronized HeLa cells. Immunoprecipitation experiments with purified proteins further confirmed a physical association between PARP-1 and PCNA. To investigate the effect of this association on PARP-1 activity, an assay based on the incorporation of radioactive NAD was performed. Conversely, the effect of PARP-1 on PCNA-dependent DNA synthesis was assessed by a DNA polymerase δ assay. A marked inhibition of both reactions was found. Unexpectedly, PARP-1 activity also decreased in the presence of p21waf1/cip1. By pull-down experiments, we provided the first evidence for an association between PARP-1 and p21, which involves the C-terminal part of p21 protein. This association was further demonstrated to occur also in vivo in MNNG (N-methyl-N′-nitro-N-nitrosoguanidine)-treated human fibroblasts. These observations suggest that PARP-1 and p21 could cooperate in regulating the functions of PCNA during DNA replication/repair.

Replication fork stalling in WRN-deficient cells is overcome by prompt activation of a MUS81-dependent pathway

Failure to stabilize and properly process stalled replication forks results in chromosome instability, which is a hallmark of cancer cells and several human genetic conditions that are characterized by cancer predisposition. Loss of WRN, a RecQ-like enzyme mutated in the cancer-prone disease Werner syndrome (WS), leads to rapid accumulation of double-strand breaks (DSBs) and proliferating cell nuclear antigen removal from chromatin upon DNA replication arrest. Knockdown of the MUS81 endonuclease in WRN-deficient cells completely prevents the accumulation of DSBs after fork stalling. Also, MUS81 knockdown in WS cells results in reduced chromatin recruitment of recombination enzymes, decreased yield of sister chromatid exchanges, and reduced survival after replication arrest. Thus, we provide novel evidence that WRN is required to avoid accumulation of DSBs and fork collapse after replication perturbation, and that prompt MUS81-dependent generation of DSBs is instrumental for recovery from hydroxyurea-mediated replication arrest under such pathological conditions.

Loss of p21CDKN1A impairs entry to quiescence and activates a DNA damage response in normal fibroblasts induced to quiescence

The cell cycle inhibitor p21CDKN1A induces cell cycle arrest under different conditions, including senescence and terminal differentiation. Still debated is its involvement in the reversible transition from proliferation to a non-dividing quiescent state (G0), in which a significant role has been attributed to cell cycle inhibitor p27CDKN1B. Here we provide evidence showing that high p21 protein levels are necessary to enter and maintain the quiescence state following contact inhibition and growth factor withdrawal. In fact, entry into quiescence was impaired, both in human fibroblasts in which p21 gene has been deleted, or protein expression knocked-down by RNA interference. Importantly, in the absence of p21, human fibroblasts activate a DNA damage-like signalling pathway, as shown by phosphorylation of histone H2AX and Chk1 proteins. In addition, we show that in the absence of p21, checkpoint is activated by an unscheduled entry into S phase, with a reduced efficiency in DNA maturation, in the presence of high c-myc protein levels. These results highlight the role of p21 in counteracting inappropriate proliferation stimuli for genome stability maintenance.

Apoptosis-prone phenotype of human colon carcinoma cells with a high level amplification of the c- myc gene

Although apoptosis can be induced by the enforced expression of exogenously introduced c-myc genes, it is not clear whether overexpression resulting from the amplification of the resident c-myc gene in tumor cells is sufficient to induce apoptosis. We have investigated the relationship between c-myc gene amplification and the propensity of tumor cells to undergo apoptosis, using the SW613-12A1 and SW613-B3 cell lines, which are representatives, respectively, of tumorigenic and non-tumorigenic clones isolated from the SW613-S human colon carcinoma cell line. Tumorigenic clones are characterized by a high level of amplification and expression of the c-myc gene, whereas cells of non-tumorigenic clones have a small number of copies and a lower level of expression of this gene. Analysis of c-myc mRNA level in cells cultured under low serum conditions indicated that the expression of the gene is tightly regulated by serum growth factors in non-tumorigenic B3 cells, whereas it is poorly regulated in tumorigenic 12A1 cells, the level of mRNAs remaining relatively high in serum-starved 12A1 cells. Under these conditions, 12A1 cells showed clear evidence of apoptosis, whereas B3 cells were completely refractory to the induction of apoptosis. Moreover, the study of cell lines derived from non-tumorigenic apoptosis-resistant clones following the introduction by transfection of exogenous c-myc gene copies showed that they have acquired an apoptosis-prone phenotype. Altogether, our results strongly suggest that deregulated c-myc expression due to high-level amplification confers an apoptosis-prone phenotype to tumor cells. The possible consequences of these observations for cancer therapy are discussed.

Small ribosomal subunits associate with nuclear myosin and actin in transit to the nuclear pores

We have followed at high resolution the ribosomal protein S6 entering the nucleus of HeLa cells, stopping in some (not all) interchromatin granules clusters and reaching, via Cajal bodies, the nucleolus. There, S6 is assembled with other proteins and rRNA into small ribosomal subunit (SSU), released in the nucleoplasm, and exported through the nuclear pores. We show for the first time the spatial association of nuclear myosin I (NMI) and actin with the SSU already at the nucleolar periphery to the nuclear pore. A blockade of NMI or actin induces an upstream accumulation of the S6 protein en route to the nucleolus, and a temperature lower than normal influences RNA export. Our data strongly suggest a functional relationship of SSU with NMI and actin. In our hypothesis, an active, myosin‐driven movement of the small ribosomal subunit can be responsible for the export of ∼10% of SSUs. This hypothesis is supported by ultrastructural, immunofluorescence, and biochemical analyses. The currently accepted model for the subunit release suggests a diffusive, temperature‐independent mechanism. However, the advantage of the double mechanism would assure that the movement of a part of the subunits could be modulated, increased, or decreased according to the needs of the cell at a specific moment in the cell cycle.—Cisterna, B., Necchi, D., Prosperi, E., Biggiogera, M. Small ribosomal subunits associate with nuclear myosin and actin in transit to the nuclear pores. FASEB J. 20, E1257–E1263 (2006)

p21 waf1/cip1 -null human fibroblasts are deficient in nucleotide excision repair downstream the recruitment of PCNA to DNA repair sites

The cyclin-dependent kinase inhibitor p21waf1/cip1 is known to impair DNA synthesis by binding to PCNA, the co-factor of DNA polymerases δ and ε. However, a positive role for p21 in nucleotide excision repair (NER) has been suggested. In this study, the sensitivity to DNA damage and DNA repair efficiency were investigated in p21-null human fibroblasts obtained by targeted homologous recombination. After UV-C irradiation, p21−/− cells showed a threefold reduction in clonogenic survival and an increased susceptibility to apoptosis, as compared with parental p21+/+ cells. Removal of cyclobutane pyrimidine dimers was significantly reduced in p21−/− cells both in the whole genome, and at the level of the rDNA gene cluster, as determined by immunoassay and Southern blot, respectively. After DNA damage, the recruitment of PCNA as detergent-insoluble form associated to DNA repair sites in p21−/− fibroblasts, was comparable to that observed in parental p21+/+ cells. However, PCNA remained associated with DNA for a longer period in p21−/− than in p21+/+ cells. These results suggest that in human cells, p21 is required for NER at a step located downstream the recruitment of PCNA to DNA repair sites.

p21CDKN1A does not interfere with loading of PCNA at DNA replication sites, but inhibits subsequent binding of DNA polymerase delta at the G1/S phase transition.

The ability of the cyclin-dependent kinase (CDK) inhibitor p21CDKN1A to interact with PCNA recruited to DNA replication sites was investigated to elucidate the relevance of this interaction in cell cycle arrest. To this end, expression of p21 protein fused to green fluorescent protein (GFP) was induced in HeLa cells. G1 phase cell cycle arrest induced by p21GFP occurred also at the G1/S transition, as shown by cyclin A immunostaining of GFP-positive cells. Confocal microscopy analysis and co-immunoprecipitation studies showed that p21GFP co-localized and interacted with chromatin-bound PCNA and CDK2. GFP-p21 mutant forms unable to bind to PCNA (p21PCNA-) or CDK (p21CDK-) induced cell cycle arrest, although immunoprecipitation experiments showed these mutants to be unstable. Expression of HA-tagged p21wt or mutant proteins confirmed the ability of both mutants to arrest cell cycle. p21wtHA and p21CDK-HA, but not p21PCNA-, co-localized and co-immunoprecipitated with chromatin-bound PCNA. Association of p21 to chromatin-bound PCNA resulted in the loss of interaction with the p125 catalytic subunit of DNA polymerase d (pol d). These results suggest that in vivo p21 does not interfere with loading of PCNA at DNA replication sites, but prevents, or displaces subsequent binding of pol d to PCNA at the G1/S phase transition.

Early effects of AZT on mitochondrial functions in the absence of mitochondrial DNA depletion in rat myotubes

Zidovudine (AZT) is a potent inhibitor of human immunodeficiency virus (HIV) replication. In humans, as well as in animal models, long-term treatment with AZT induces a severe myopathy characterised by structural and functional alterations of mitochondria associated with depletion of mitochondrial DNA (mtDNA). In the present work, we compared the effects induced by AZT on mitochondria upon short- or long-term treatments of cultured rat myotubes. Morphological alterations were investigated by electron microscopy, and mtDNA depletion and deletions were analysed by Southern blot. Mitochondrial membrane potential was determined after JC-1 staining by laser-scanning confocal microscopy in whole cells, and by flow cytometry in isolated muscle mitochondria. We found that the early effects of AZT on mitochondrial functions were a marked, yet reversible reduction in mitochondrial membrane potential, in the absence of any effect on mtDNA. The long-term treatment, in addition to mitochondrial membrane potential alterations, induced morphological changes in mitochondria, and a remarkable reduction in the amount of mtDNA, without any significant evidence of mtDNA deletions. In both treatments, a block of the spontaneous contraction of myotubes was observed. To study in more detail the early effects induced by AZT, the ability of the drug to interact with cardiolipin, an important component of internal mitochondrial membrane, was investigated by atomic force microscopy (AFM) in an artificial membrane model system. The results suggest that the primary effects of AZT may be related to a physical interference with the membrane structure leading to a consequent modification of its physical characteristics.