Retinoblastoma family proteins as key targets of the small DNA virus oncoproteins

RB, the most investigated tumor suppressor gene, is the founder of the RB family of growth/tumor suppressors, which comprises also p107 (RBL1) and Rb2/p130 (RBL2). The protein products of these genes, pRb, p107 and pRb2/p130, respectively, are also known as 'pocket proteins', because they share a 'pocket' domain responsible for most of the functional interactions characterizing the activity of this family of cellular factors. The interest in these genes and proteins springs essentially from their ability to regulate negatively cell cycle processes and for their ability to slow down or abrogate neoplastic growth. The pocket domain of the RB family proteins is dramatically hampered in its functions by the interference of a number of proteins produced by the small DNA viruses. In the last two decades, the 'viral hypothesis' of cancer has received a considerable renewed impulse from the notion that small DNA viruses, such as Adenovirus, Human papillomavirus (HPV) and Polyomavirus, produce factors that can physically interact with major cellular regulators and alter their function. These viral proteins (oncoproteins) act as multifaceted molecular devices that have evolved to perform very specific tasks. Owing to these features, viral oncoproteins have been widely employed as invaluable experimental tools for the identification of several key families of regulators, particularly of the cell cycle homeostasis. Adenovirus early-region 1A (E1A) is the most widely investigated small DNA tumor virus oncoprotein, but relevant interest in human oncology is raised by the E1A-related E7 protein from transforming HPV strains and by Polyomavirus oncoproteins, particularly large and small T antigens from Simian virus 40, JC virus and BK virus.     

Molecular mechanisms of hyperplasia induction by human papillomavirus E7

Infections of human papillomavirus (HPV) induce a variety of benign tumors, such as warts and condylomas. During the process of aberrant cell proliferation, genetic mutations are accumulated in the cells, from which malignant tumor cells arise. The viral oncoproteins E6 and E7 are known to help disrupt the cell cycle checkpoint machinery and accelerate chromosomal instability, events which are critical in malignant conversion. However, the mechanisms involved in the hyperplasia caused by HPV infection have remained unknown. We analysed the effects of regulatory genes of HPV18, a typical high-risk-type HPV, on the formation of the epithelial organ by using an organotypic culture system, and found that E7 had potent activity to induce hyperplasia, to which the disruption of the pRb pathway was well correlated. However, analysis with the E7 variants indicated that other pocket proteins are also involved in the activity.     

Che-1 affects cell growth by interfering with the recruitment of HDAC1 by Rb

DNA tumor virus oncoproteins bind and inactivate Rb by interfering with the Rb/HDAC1 interaction. Che-1 is a recently identified human Rb binding protein that inhibits the Rb growth suppressing function. Here we show that Che-1 contacts the Rb pocket region and competes with HDAC1 for Rb binding site, removing HDAC1 from the Rb/E2F complex in vitro and from the E2F target promoters in vivo. Che-1 overexpression activates DNA synthesis in quiescent NIH-3T3 cells through HDAC1 displacement. Consistently, Che-1-specific RNA interference affects E2F activity and cell proliferation in human fibroblasts but not in the pocket protein-defective 293 cells. These findings indicate the existence of a pathway of Rb regulation supporting Che-1 as the cellular counterpart of DNA tumor virus oncoproteins.     

Biological activities and molecular targets of the human papillomavirus E7 oncoprotein.

The human papillomavirus (HPV) E7 protein is one of only two viral proteins that remain expressed in HPV-associated human cancers. HPV E7 proteins share structural and functional similarities with oncoproteins encoded by other small DNA tumor viruses such as adenovirus E1A and SV40 large tumor antigen. The HPV E7 protein plays an important role in the viral life cycle by subverting the tight link between cellular differentiation and proliferation in normal epithelium, thus allowing the virus to replicate in differentiating epithelial cells that would have normally withdrawn from the cell division cycle. The transforming activities of E7 largely reflect this important function.     

The DNA damage response in viral-induced cellular transformation

The DNA damage response (DDR) has emerged as a critical tumour suppressor pathway responding to cellular DNA replicative stress downstream of aberrant oncogene over-expression. Recent studies have now implicated the DDR as a sensor of oncogenic virus infection. In this review, we discuss the mechanisms by which tumour viruses activate and also suppress the host DDR. The mechanism of tumour virus induction of the DDR is intrinsically linked to the need for these viruses to promote an S-phase environment to replicate their nucleic acid during infection. However, inappropriate expression of viral oncoproteins can also activate the DDR through various mechanisms including replicative stress, direct interaction with DDR components and induction of reactive oxygen species. Given the growth-suppressive consequences of activating the DDR, tumour viruses have also evolved mechanisms to attenuate these pathways. Aberrant expression of viral oncoproteins may therefore promote tumourigenesis through increased somatic mutation and aneuploidy due to DDR inactivation. This review will focus on the interplay between oncogenic viruses and the DDR with respect to cellular checkpoint control and transformation.     

Viral oncoproteins target the DNA methyltransferases

Small DNA tumour viruses have evolved a number of mechanisms to drive nondividing cells into S phase. Virally encoded oncoproteins such as adenovirus E1A and human papillomavirus (HPV) E7 can bind an array of cellular proteins to override proliferation arrest. The DNA methyltransferase Dnmt1 is the major mammalian enzyme responsible for maintaining CpG methylation patterns in the cell following replication. One of the hallmarks of tumour cells is disrupted DNA methylation patterns, highlighting the importance of the proper regulation of DNA methyltransferases in normal cell proliferation. Here, we show that adenovirus 5 E1A and HPV-16 E7 associate in vitro and in vivo with the DNA methyltransferase Dnmt1. Consistent with this interaction, we find that E1A and E7 can purify DNA methyltransferase activity from nuclear extracts. These associations are direct and mediated by the extreme N-terminus of E1A and the CR3 zinc-finger domain of E7. Furthermore, we find that a point mutant at leucine 20 of E1A, a residue known to be critical for its transformation functions, is unable to bind Dnmt1 and DNA methyltransferase activity. Finally, both E1A and E7 can stimulate the methyltransferase activity of Dnmt1 in vitro. Our results provide the first indication that viral oncoproteins bind and regulate Dnmt1 enzymatic activity. These observations open up the possibility that this association may be used to control cellular proliferation pathways and suggest a new mechanism by which small DNA tumour viruses can steer cells through the cell cycle.     

Rb inactivation leads to E2F1-mediated DNA double-strand break accumulation

Although it is unclear which cellular factor(s) is responsible for the genetic instability associated with initiating and sustaining cell transformation, it is known that many cancers have mutations that inactivate the Rb-mediated proliferation pathway. We show here that pRb inactivation and the resultant deregulation of one E2F family member, E2F1, leads to DNA double-strand break (DSB) accumulation in normal diploid human cells. These DSBs occur independent of Atm, p53, caspases, reactive oxygen species, and apoptosis. Moreover, E2F1 does not contribute to c-Myc-associated DSBs, indicating that the DSBs associated with these oncoproteins arise through distinct pathways. We also find E2F1-associated DSBs in an Rb mutated cancer cell line in the absence of an exogenous DSB stimulus. These basal, E2F1-associated DSBs are not observed in a p16(ink4a) inactivated cancer cell line that retains functional pRb, unless pRb is depleted. Thus, Rb status is key to regulating both the proliferation promoting functions associated with E2F and for preventing DNA damage accumulation if E2F1 becomes deregulated. Taken together, these data suggest that loss of Rb creates strong selective pressure, via DSB accumulation, for inactivating p53 mutations and that E2F1 contributes to the genetic instability associated with transformation and tumorigenesis.     

Transgenic animal models of human papillomavirus-dependent disease (Review)

Human papillomaviruses (HPVs) are DNA tumor viruses that induce hyperproliferative lesions in cutaneous and mucosal epithelia. A wide variety of studies implicate the viral E6 and E7 oncoproteins as cell immortalizing agents, and show that these proteins work, respectively, by interfering with the function of the p53 and pRb tumor suppressor genes. Most of these studies have been performed using cell culture models. However, recently, a variety of in vivo mouse model systems have been developed for the study of HPV-dependent disease. These models use tissue-specific promoters to deliver HPV oncoprotein expression to specific body sites. Using this strategy, mouse models have been designed for the study of cancer progression in epithelia, and additional models have been designed to use E6 and E7, respectively, to probe the role of p53 and pRb on tissue differentiation and function. In the present report, we summarize the literature describing these systems, and highlight some of the important findings derived from these studies.     

Human fibroblasts require the Rb family of tumor suppressors, but not p53, for PML-induced senescence

Cellular senescence is a permanent cell cycle arrest that can be triggered by a variety of stresses including short telomeres and activated oncogenes. Promyelocytic leukemia protein (PML) is a central component of the senescence response, and is able to trigger the process when overexpressed in human diploid fibroblasts (HDFs). Senescence induced by PML in HDFs is characterized by a modest increase in p53 levels and activity, the accumulation of hypophosphorylated Rb and a reduced expression of E2F-dependent genes. To dissect the p53 and Rb family requirements for PML-induced senescence, we used the oncoproteins E6 and E7 from human papillomavirus type 16. We found that the coexpression of E6 and E7 inhibited the growth arrest and senescence induced by PML. In addition, these viral oncoproteins blocked the formation of PML bodies and excluded both p53 and Rb from PML bodies. Expression of dominant-negative p53 alone failed to block PML-induced senescence and expression of E6 only delayed the process. On the other hand, expression of E7 was sufficient to block PML-induced senescence, while an E7 mutant unable to bind Rb did not. Together, these data indicate that PML-induced senescence engages the Rb tumor-suppressor pathway predominantly.     

The Rb family of cell cycle regulatory factors: clinical implications

The retinoblastoma gene family is composed of three members: the product of the retinoblastoma gene (pRb), which is one of the most well studied tumor suppressor genes and two related proteins, pRb2/p130 and p107, which have been shown to be structurally and functionally similar to pRb. The three retinoblastoma family members show growth suppressive properties, although the growth arrest mediated by each of the three pocket regions of the proteins is not identical. This supports the idea that although the three members may complement each other, they are not fully functional or redundant. Among the three family members, the retinoblastoma-related gene product pRb2/p130 is a tumor suppressor gene and an effective candidate target for gene therapy approach. The aim of this review is to examine the role of the Rb family members in growth regulation discussing their putative prognostic and therapeutical impact in human cancer.     

The retinoblastoma tumor-suppressor gene, the exception that proves the rule

The retinoblastoma tumor-suppressor gene (Rb1) is centrally important in cancer research. Mutational inactivation of Rb1 causes the pediatric cancer retinoblastoma, while deregulation of the pathway in which it functions is common in most types of human cancer. The Rb1-encoded protein (pRb) is well known as a general cell cycle regulator, and this activity is critical for pRb-mediated tumor suppression. The main focus of this review, however, is on more recent evidence demonstrating the existence of additional, cell type-specific pRb functions in cellular differentiation and survival. These additional functions are relevant to carcinogenesis suggesting that the net effect of Rb1 loss on the behavior of resulting tumors is highly dependent on biological context. The molecular mechanisms underlying pRb functions are based on the cellular proteins it interacts with and the functional consequences of those interactions. Better insight into pRb-mediated tumor suppression and clinical exploitation of pRb as a therapeutic target will require a global view of the complex, interdependent network of pocket protein complexes that function simultaneously within given tissues.     

Association of UNP, a ubiquitin-specific protease, with the pocket proteins pRb, p107 and p130

The murine Unp gene encodes a widely expressed ubiquitin-specific protease. The predicted sequence of the UNP protein features motifs common to viral oncoproteins through which these proteins interact with the retinoblastoma gene product pRb, as well as the related 'pocket proteins' p107 and p130. We have explored the possibility that UNP interacts with pocket proteins, and report here that such associations can be detected in vitro and in cells. Associations of UNP and pocket proteins are sensitive to site-directed mutations in a manner directly analogous to those documented in viral oncoproteins. We conclude that within cells UNP does physically associate with pRb, and can also associate with p107 and p130.     

SV40 and cell cycle perturbations in malignant mesothelioma

Although epidemiological findings have established that exposure to asbestos fibers is the major cause of malignant mesothelioma (MM), recent studies have implicated simian virus 40 (SV40) in the etiology of some of these tumors. Cytogenetic and molecular genetic evidence suggests that multiple somatic genetic events are required for tumorigenic conversion of a mesothelial cell. As with many other types of cancer, in MM critical oncogenic events exert their action via perturbations of the cell cycle. Interactions between the retinoblastoma (Rb) family of proteins and oncoproteins encoded by SV40 lead to cell cycle alterations. Likewise, inhibition of the p53 tumor suppressor by SV40 can inactivate a crucial cell cycle checkpoint, thereby permitting cells to undergo mitosis regardless of the presence of DNA damage. Many MMs exhibit loss and/or inactivation of the tumor suppressors p16(INK4a)and p14(ARF), components of the pRb and p53 cell cycle regulatory pathways, respectively. Recent investigations have demonstrated that SV40 large T antigen, isolated from frozen biopsies of human MM specimens, binds to and inactivates various tumor suppressor gene products such as pRb and p53. In this review, we discuss how SV40-oncosuppressor interactions can lead to functional alterations of the pRb- and p53-dependent cell cycle regulatory pathways and thereby contribute to neoplastic transformation of human mesothelial cells.     

The molecular mechanism of human papillomavirus-induced carcinogenesis in head and neck squamous cell carcinoma

Head and neck squamous cell carcinoma (HNSCC) is the sixth most common cancer worldwide. Recently, the incidence of oropharyngeal cancer (OPC) has increased markedly in comparison to that of HNSCC, which is associated with the use of tobacco or alcohol or both. This increase has resulted mainly from the global rise in the number of human papillomavirus (HPV)-related oropharyngeal cancers (HPV-OPCs). HPV-OPC has several unique characteristics, including presentation in younger patients, better response rates to treatment, and better prognosis compared to alcohol- and smoking-related HNSCC. HPV infection status is now an independent prognostic factor for survival in patients with OPC. In general, HPV oncoproteins E6 and E7 are the primary viral factors responsible for the initiation and progression of HPV-related cancers via the inactivation of p53 and pRb. However, alterations in additional factors, including genomic instability, HPV DNA integration, and epigenetic alterations, could be equally important for neoplastic transformation and tumor progression. The impact of genomic instability and external environmental factors on the initiation of cervical cancer development through high-risk HPV infection has been well characterized, although less is known about the mechanism underlying HPV-induced carcinogenesis in HNSCC. This review provides an overview of the biology and molecular mechanisms of HPV-related cancers, including a particular focus on several recent studies on the comprehensive characterization of genomic alterations in HPV-associated HNSCC.