Senescence: a telomeric limit to immortality or a cellular response to physiologic stresses?

Cells entering a state of senescence undergo a irreversible cell cycle arrest, associated by a set of functional and morphological changes. Senescence occurs following telomeres shortening (replicative senescence) or exposure to other acute or chronic physiologic stress signals (a phenomenon termed stasis: stress or aberrant signaling-induced senescence). In this review, I discuss the pathways of cellular senescence, the mechanisms involved and the role that these pathways have in regulating the initiation and progression of cancer. Telomere-initiated senescence or loss of telomere function trigger focal recruitement of protein sensors of the DNA double-strand breaks leading to the activation of the DNA damage checkpoint responses and the tumour suppressor gene product, p53, which in turn induces the cell-cycle inhibitor, p21(WAF1). Loss of p53 and pRb function allows continued cell division despite increasing telomere dysfunction and eventually entry into telomere crisis. Immortalisation is an essential prerequisite for the formation of a tumour cell. Therefore, a developing tumour cell must circumvent at least two proliferative barriers--cellular senescence and crisis--to achieve neoplastic transformation. These barriers are regulated by telomere shortening and by the p16(INK4a)/Rb and p53 tumour suppressor pathways. Elucidation of the genes and emerging knowledge about the regulatory mechanisms that lead to senescence and determine the pattern of gene expression in senescent cells may lead to more effective treatments for cancer.     

Tumor suppressor pRb2/p130 gene and its derived product Spa310 spacer domain as perspective candidates for cancer therapy

Tumor suppressor pRb2/p130 gene belongs to the retinoblastoma (Rb) gene family, which also includes pRb/p105 and pRb/p107. The members of the Rb gene family have attracted a great deal of interest because of their essential role in regulating cell cycle and, consequently, cell proliferation. This mini review discusses the potential therapeutic applications both of pRb2/p130 and its derived product Spa310 spacer domain in cancer treatment.     

DNA-damage-responsive acetylation of pRb regulates binding to E2F-1

The pRb (retinoblastoma protein) tumour suppressor protein has a crucial role in regulating the G1- to S-phase transition, and its phosphorylation by cyclin-dependent kinases is an established and important mechanism in controlling pRb activity. In addition, the targeted acetylation of lysine (K) residues 873/874 in the carboxy-terminal region of pRb located within a cyclin-dependent kinase-docking site hinders pRb phosphorylation and thereby retains pRb in an active state of growth suppression. Here, we report that the acetylation of pRb K873/874 occurs in response to DNA damage and that acetylation regulates the interaction between the C-terminal E2F-1-specific domain of pRb and E2F-1. These results define a new role for pRb acetylation in the DNA damage signalling pathway, and suggest that the interaction between pRb and E2F-1 is controlled by DNA-damage-dependent acetylation of pRb.     

A novel form of pRb expressed during normal myelopoiesis and in tumour-associated macrophages

The retinoblastoma (Rb) tumour suppressor promotes cell cycle exit, terminal differentiation and survival during normal development and is functionally inactivated in most human cancers. We have identified a novel myeloid-specific form of retinoblastoma protein (pRb), termed deltaRb-p70, that exists in vivo as an N-terminally truncated form of full-length pRb. DeltaRb-p70 appears to be the product of alternative translation and is expressed in primary myeloid cells in fetal liver, bone marrow and spleen. It is also expressed in the human myelomonocytic cell line U937 and is down-regulated as U937s are induced to differentiate. We have also detected deltaRb-p70 expression in primary human breast tumours and we have determined that deltaRb-p70 is specifically expressed in tumour-associated macrophages. These data identify a novel mechanism for regulating pRb expression that is unique to the myeloid system.     

Distinct E2F-mediated transcriptional program regulates p14ARF gene expression

The tumor suppressor p14(ARF) gene is induced by ectopically expressed E2F, a positive regulator of the cell cycle. The gene is expressed at low levels in normally growing cells in contrast to high levels in varieties of tumors. How p14(ARF) gene is regulated by E2F in normally growing cells and tumor cells remains obscure. Here we show that regulation of p14(ARF) gene by E2F is distinct from that of classical E2F targets. It is directly mediated by E2F through a novel E2F-responsive element that varies from the typical E2F site. The element responds to E2F activity resulting from ectopic E2F1 expression, inactivation of pRb by adenovirus E1a or shRNA, but not to phosphorylation of pRb by serum stimulation or ectopic cyclin D1/cyclin-dependent kinase-4 expression in normal human fibroblasts. The element has activity in various tumor cells with defective pRb, but not in normally growing cells. These results indicate that the distinct regulation constitutes the basis of p14(ARF) function as a tumor suppressor, discriminating abnormal growth signals caused by defects in pRb function from normal growth signals.     

Rb family proteins differentially regulate distinct cell lineages during epithelial development

pRb, p107 and p130 are important regulators of cell cycle and have extensive overlapping functions; however, only Rb has been shown to be a bone fide tumor suppressor. Defining the overlapping versus distinct pocket protein functions is therefore an important step to understanding the unique role of Rb. Using lung as a model, the present studies demonstrate that pocket proteins are important not only in regulating cell cycle and survival but also in cell lineage specification. An inducible lung-specific Rb knockout strategy was used to demonstrate that Rb is specifically required for restricting neuroendocrine cell fate despite functional compensation for Rb deficiency in other cell types. Ablation of total Rb family function resulted in opposing effects in specification along distinct cell lineages, providing evidence that pocket proteins inhibit neuroendocrine cell fate while being required for differentiation in other cell types. These findings identify a novel role for pocket proteins in cell fate determination, and establish a unique cell lineage-specific function for Rb that explains, at least in part, why Rb and p16 are inactivated in phenotypically distinct carcinomas.     

The retinoblastoma protein alters the phosphorylation state of polyomavirus large T antigen in murine cell extracts and inhibits polyomavirus origin DNA replication

The retinoblastoma tumor suppressor protein (pRb) can associate with the transforming proteins of several DNA tumor viruses, including the large T antigen encoded by polyomavirus (Py T Ag). Although pRb function is critical for regulating progression from G1 to S phase, a role for pRb in S phase has not been demonstrated or excluded. To identify a potential effect of pRb on DNA replication, pRb protein was added to reaction mixtures containing Py T Ag, Py origin-containing DNA (Py ori-DNA), and murine FM3A cell extracts. We found that pRb strongly represses Py ori-DNA replication in vitro. Unexpectedly, however, this inhibition only partially depends on the interaction of pRb with Py T Ag, since a mutant Py T Ag (dl141) lacking the pRb interaction region was also significantly inhibited by pRb. This result suggests that pRb interferes with or alters one or more components of the murine cell replication extract. Furthermore, the ability of Py T Ag to be phosphorylated in such extracts is markedly reduced in the presence of pRb. Since cyclin-dependent kinase (CDK) phosphorylation of Py T Ag is required for its replication function, we hypothesize that pRb interferes with this phosphorylation event. Indeed, the S-phase CDK complex (cyclin A-CDK2), which phosphorylates both pRb and Py T Ag, alleviates inhibition caused by pRb. Moreover, hyperphosphorylated pRb is incapable of inhibiting replication of Py ori-DNA in vitro. We propose a new requirement for maintaining pRb phosphorylation in S phase, namely, to prevent deleterious effects on the cellular replication machinery.