Conditional replication of a recombinant adenovirus studied using neomycin as a selective marker

An E1B-defective adenovirus, named r2/Ad carrying the neo expression cassette, was constructed by homologous recombination. The construction, selection (using neomycin as a selective marker), and propagation of the recombinant virus was performed in human embryonic kidney 293 cells (HEK 293). An in vitro study demonstrated that this recombinant virus has the ability to replicate in and lyse some p53-deficient human tumor cells such as human glioma tumor cells (U251) and human bladder cells (EJ), but not in some cells with functional p53, such as human adenocarcinoma cells (A549) and human fibroblast cells (MRC-5). Also, based on the cytopathic effect (CPE), it was demonstrated, under identical conditions, that the U251 cells were more sensitive to r2/Ad replication than the EJ cells. In this paper, we report that r2/Ad could be very useful in studying the in vitro selective replication of E1B-defective adenovirus and has great potential in cancer gene therapy.     

p53-Independent and -Dependent Requirements for E1B-55K in Adenovirus Type 5 Replication

The adenovirus type 5 mutant dl1520 was engineered previously to be completely defective for E1B-55K functions. Recently, this mutant (also known as ONYX-015) has been suggested to replicate preferentially in p53(-) and some p53(+) tumor cell lines but to be attenuated in primary cultured cells (C. Heise, A. Sampson-Johannes, A. Williams, F. McCormick, D. D. F. Hoff, and D. H. Kirn, Nat. Med. 3:639-645, 1997). It has been suggested that dl1520 might be used as a "magic bullet" that could selectively lyse tumor cells without harm to normal tissues. However, we report here that dl1520 replication is independent of p53 genotype and occurs efficiently in some primary cultured human cells, indicating that the mutant virus does not possess a tumor selectivity. Although it was not the sole host range determinant, p53 function did reduce dl1520 replication when analyzed in a cell line expressing temperature-sensitive p53 (H1299-tsp53) (K. L. Fries, W. E. Miller, and N. Raab-Traub, J. Virol. 70:8653-8659, 1996). As found earlier for other E1B-55K mutants in HeLa cells (Y. Ho, R. Galos, and J. Williams, Virology 122:109-124, 1982), dl1520 replication was temperature dependent in H1299 cells. When p53 function was restored at low temperature in H1299-tsp53 cells, it imposed a modest defect in viral DNA replication and accumulation of late viral cytoplasmic mRNA. However, in both H1299 and H1299-tsp53 cells, the defect in late viral protein synthesis appeared to be much greater than could be accounted for by the modest defects in late viral mRNA levels. We therefore propose that in addition to countering p53 function and modulating viral and cellular mRNA nuclear transport, E1B-55K also stimulates late viral mRNA translation.     

Cell-specific modulation of papovavirus replication by tumor suppressor protein p53

Small DNA tumor viruses like human papillomaviruses, simian virus 40, and adenoviruses modulate the activity of cellular tumor suppressor proteins p53 and/or pRB. These viruses replicate as nuclear multicopy extrachromosomal elements during the S phase of the cell cycle, and it has been suggested that inactivation of p53 and pRb is necessary for directing the cells to the S phase. Mouse polyomavirus (Py), however, modulates only the pRB protein activity without any obvious interference with the action of p53. We show here that Py replication was not suppressed by the p53 protein indeed in all tested different mouse cell lines. In addition, E1- and E2-dependent papillomavirus origin replication was insensitive to the action of p53 in mouse cells. We show that in hamster (Chinese hamster ovary) or human (osteosarcoma 143) cell lines the replication of both Py and papillomavirus origins was efficiently blocked by p53. The block of Py replication in human and hamster cells is not caused by the downregulation of large T-antigen expression. The deletion analysis of the p53 protein shows that the RPA binding, proline-rich regulatory, DNA-binding, and oligomerization domains are necessary for p53 action in both replication systems. These results indicate that in mouse cells the p53 protein could be inactive for the suppression of papovavirus replication.     

Loss of p14ARF in tumor cells facilitates replication of the adenovirus mutant dl1520 (ONYX-015)

The adenovirus mutant dl1520 (ONYX-015) does not express the E1B-55K protein that binds and inactivates p53. This virus replicates in tumor cells with mutant p53, but not in normal cells with functional p53. Although intra-tumoral injection of dl1520 shows promising responses in patients with solid tumors, previous in vitro studies have not established a close correlation between p53 status and dl1520 replication. Here we identify loss of p14ARF as a mechanism that allows dl1520 replication in tumor cells retaining wild-type p53. We demonstrate that the re-introduction of p14ARF into tumor cells with wild-type p53 suppresses replication of dl1520 in a p53-dependent manner. Our study supports the therapeutic use of dl1520 in tumors with lesions within the p53 pathway other than mutation of p53.     

E1B55K-Deleted Adenovirus (ONYX-015) Overrides G1/S and G2/M Checkpoints and Causes Mitotic Catastrophe and Endoreduplication in p53-Proficient Normal Cells

In order to take advantage of cell replication machinery, viruses have evolved complex strategies to override cell cycle checkpoints and force host cells into S phase. To do so, virus products must interfere not only with the basal cell cycle regulators, such as pRb or Mad2, but also with the main surveillance pathways such as those controlled by p53 and ATM. Recently, a number of defective viruses has been produced which, lacking the latter ability, are incapable of replicating in normal cells but should be able to grow and finally lyse those cells that, such as the tumor cells, have lost their surveillance mechanisms. A prototype of these oncolytic viruses is the E1B55K-defective Adenovirus ONYX-015, which was predicted to selectively replicate and kill p53-deficient cancer cells. We found that, despite wt p53 and notwithstanding the activation of the checkpoint regulators p53, ATM, and Mad2, ONYX-015 actively replicated in HUVEC cells. Furthermore, ONYX-015 replication induced a specific phenotype, which is distinct from that of the E4-deleted adenovirus dlE4 Ad5, although both viruses express the main regulatory region E1A. This phenotype includes overriding of the G1/S and G2/M checkpoints, over-expression of MAD2 and retardation of mitosis and accumulation of polyploid cells, suggesting the occurrence of alterations at the mitotic-spindle checkpoint and impairment of the post-mitotic checkpoint. Our data suggest that viral E1A and E4 region products can override all host cell-checkpoint response even at the presence of a full activation of the ATM/p53 pathway. Furthermore, the E4 region alone seems to act independently of the E1B55K virus product in impairing the ATM-dependent, p53-independent G2/M checkpoint since dlE4 Ad5-infected cells arrested in G2 while ONYX-015-infected cells did enter mitosis.     

The Epstein-Barr Virus Protein BRLF1 Activates S Phase Entry through E2F1 Induction

The Epstein-Barr Virus (EBV) immediate-early protein BRLF1 is one of two transactivators which mediate the switch from latent to lytic replication in EBV-infected cells. DNA viruses often modulate the function of critical cell cycle proteins to maximize the efficiency of virus replication. Here we have examined the effect of BRLF1 on cell cycle progression. A replication-deficient adenovirus expressing BRLF1 (AdBRLF1) was used to infect normal human fibroblasts and various epithelial cell lines. BRLF1 expression induced S phase entry in contact-inhibited fibroblasts and in the human osteosarcoma cell line U-2 OS. AdBRLF1 infection produced a dramatic increase in the level of E2F1 but not E2F4. In contrast, the levels of Rb, p107, and p130 were decreased in AdBRLF1-infected cells. Electrophoretic mobility shift assays confirmed an increased level of free E2F1 in the AdBRLF1-infected human fibroblasts. Consistent with the previously described effect of E2F1, AdBRLF1-infected fibroblasts had increased levels of p53 and p21 and died by apoptosis. BRLF1-induced activation of E2F1 may be required for efficient EBV lytic replication, since at least one critical viral replication gene (the viral DNA polymerase) is activated by E2F (C. Liu, N. D. Sista, and J. S. Pagano, J. Virol. 70:2545-2555, 1996).     

Hepatitis B viral X protein overcomes inhibition of E2F1 activity by pRb on the human Rb gene promoter

Hepatitis B virus X (HBx) protein is known as an oncogenic transactivator, E2F1 as a positive regulator of the cell cycle, and pRb as a tumor suppressor. Here, we investigated the functional interactions of these proteins on the human Rb promoter. Interestingly, HBx transactivated the Rb promoter cooperatively with E2F1 in HepG2 cells but not in HeLa cells, in which the functions of p53 and pRb are inactive. Combinatorial cotransfection analyses in HepG2 cells showed that HBx overcame the inhibition of E2F1 activity by pRb but not that by p53. Domain analysis showed that aa 47-70 and aa 117-133 of HBx are important for this effect. These results suggest that HBx could inhibit the pRb tumor suppressor and increase E2F1 activity. Our data support the oncogenic potential of HBx, which may cause HBV-infected cells to grow continuously in the development of hepatocellular carcinoma.     

Abrogation of the S phase DNA damage checkpoint results in S phase progression or premature mitosis depending on the concentration of 7-hydroxystaurosporine and the kinetics of Cdc25C activation

DNA damage causes cell cycle arrest in G(1), S, or G(2) to prevent replication on damaged DNA or to prevent aberrant mitosis. The G(1) arrest requires the p53 tumor suppressor, yet the topoisomerase I inhibitor SN38 induces p53 after the G(1) checkpoint such that the cells only arrest in S or G(2). Hence, SN38 facilitates comparison of p53 wild-type and mutant cells with regard to the efficacy of drugs such as 7-hydroxystaurosporine (UCN-01) that abrogate S and G(2) arrest. UCN-01 abrogated S and G(2) arrest in the p53 mutant breast tumor cell line MDA-MB-231 but not in the p53 wild-type breast line, MCF10a. This resistance to UCN-01 in the p53 wild-type cells correlated with suppression of cyclins A and B. In the p53 mutant cells, low concentrations of UCN-01 caused S phase cells to progress to G(2) before undergoing mitosis and death, whereas high concentrations caused rapid premature mitosis and death of S phase cells. UCN-01 inhibits Chk1/2, which should activate the mitosis-inducing phosphatase Cdc25C, yet this phosphatase remained inactive during S phase progression induced by low concentrations of UCN-01, probably because Cdc25C is also inhibited by the constitutive kinase, C-TAK1. High concentrations of UCN-01 caused rapid activation of Cdc25C, which is attributed to inhibition of C-TAK1, as well as Chk1/2. Hence, UCN-01 has multiple effects depending on concentration and cell phenotype that must be considered when investigating mechanisms of checkpoint regulation.     

Down-regulation of p53 by double-stranded RNA modulates the antiviral response

p53 has been well characterized as a tumor suppressor gene, but its role in antiviral defense remains unclear. A recent report has demonstrated that p53 can be induced by interferons and is activated after vesicular stomatitis virus (VSV) infection. We observed that different nononcogenic viruses, including encephalomyocarditis virus (EMCV) and human parainfluenza virus type 3 (HPIV3), induced down-regulation of p53 in infected cells. Double-stranded RNA (dsRNA) and a mutant vaccinia virus lacking the dsRNA binding protein E3L can also induce this effect, indicating that dsRNA formed during viral infection is likely the trigger for down-regulation of p53. The mechanism of down-regulation of p53 by dsRNA relies on translation inhibition mediated by the PKR and RNase L pathways. In the absence of p53, the replication of both EMCV and HPIV3 was retarded, whereas, conversely, VSV replication was enhanced. Cell cycle analysis indicated that wild-type (WT) but not p53 knockout (KO) fibroblasts undergo an early-G(1) arrest following dsRNA treatment. Moreover, in WT cells the onset of dsRNA-induced apoptosis begins after p53 levels are down-regulated, whereas p53 KO cells, which lack the early-G(1) arrest, rapidly undergo apoptosis. Hence, our data suggest that the down-regulation of p53 facilitates apoptosis, thereby limiting viral replication.     

p53 Status Does Not Determine Outcome of E1B 55-Kilodalton Mutant Adenovirus Lytic Infection

The ability of the adenovirus type 5 E1B 55-kDa mutants dl1520 and dl338 to replicate efficiently and independently of the cell cycle, to synthesis viral DNA, and to lyse infected cells did not correlate with the status of p53 in seven cell lines examined. Rather, cell cycle-independent replication and virus-induced cell killing correlated with permissivity to viral replication. This correlation extended to S-phase HeLa cells, which were more susceptible to virus-induced cell killing by the E1B 55-kDa mutant virus than HeLa cells infected during G₁. Wild-type p53 had only a modest effect on E1B mutant virus yields in H1299 cells expressing a temperature-sensitive p53 allele. The defect in E1B 55-kDa mutant virus replication resulting from reduced temperature was as much as 10-fold greater than the defect due to p53 function. At 39°C, the E1B 55-kDa mutant viruses produced wild-type yields of virus and replicated independently of the cell cycle. In addition, the E1B 55-kDa mutant viruses directed the synthesis of late viral proteins to levels equivalent to the wild-type virus level at 39°C. We have previously shown that the defect in mutant virus replication can also be overcome by infecting HeLa cells during S phase. Taken together, these results indicate that the capacity of the E1B 55-kDa mutant virus to replicate independently of the cell cycle does not correlate with the status of p53 but is determined by yet unidentified mechanisms. The cold-sensitive nature of the defect of the E1B 55-kDa mutant virus in both late gene expression and cell cycle-independent replication leads us to speculate that these functions of the E1B 55-kDa protein may be linked.     

E2F mediates sustained G2 arrest and down-regulation of Stathmin and AIM-1 expression in response to genotoxic stress

Exposure of cells to genotoxic agents results in activation of checkpoint pathways leading to cell cycle arrest. These arrest pathways allow repair of damaged DNA before its replication and segregation, thus preventing accumulation of mutations. The tumor suppressor retinoblastoma (RB) is required for the G(1)/S checkpoint function. In addition, regulation of the G(2) checkpoint by the tumor suppressor p53 is RB-dependent. However, the molecular mechanism underlying the involvement of RB and its related proteins p107 and p130 in the G(2) checkpoint is not fully understood. We show here that sustained G(2)/M arrest induced by the genotoxic agent doxorubicin is E2F-dependent and involves a decrease in expression of two mitotic regulators, Stathmin and AIM-1. Abrogation of E2F function by dominant negative E2F abolishes the doxorubicin-induced down-regulation of Stathmin and AIM-1 and leads to premature exit from G(2). Expression of the E7 papilloma virus protein, which dissociates complexes containing E2F and RB family members, also prevents the down-regulation of these mitotic genes and leads to premature exit from G(2) after genotoxic stress. Furthermore, genotoxic stress increases the levels of nuclear E2F-4 and p130 as well as their in vivo binding to the Stathmin promoter. Thus, functional complexes containing E2F and RB family members appear to be essential for repressing expression of critical mitotic regulators and maintaining the G(2)/M checkpoint.     

Productive replication of adeno-associated virus can occur in human papillomavirus type 16 (HPV-16) episome-containing keratinocytes and is augmented by the HPV-16 E2 protein

We used a sensitive assay to test whether an adeno-associated virus (AAV) productive replication cycle can occur in immortalized human keratinocytes carrying episomal human papillomavirus type 16 (HPV-16) DNA. Following transfection with cloned AAV DNA, infectious AAV was produced, and the infectivity was blocked by anti-AAV antiserum. The HPV-16 E2 protein substantially increased the yield of AAV. Other HPV early proteins did not, in our experiments, show this ability. E2 has been shown to be able to affect p53 levels and to block cell cycle progression at mitosis. We tested the effect of changes in p53 expression on AAV replication and found that large differences in the level of p53 did not alter AAV DNA replication. In extension of this, we found that cellular help for AAV in response to stress was also independent of p53. To test if a mitotic block could trigger AAV DNA replication, we treated the cells with the mitotic inhibitor nocodazole. AAV DNA replication was stimulated by the presence of nocodazole in these and a number of other cell types tested. Yields of infectious virus, however, were not increased by this treatment. We conclude that the HPV-16 E2 protein stimulates AAV multiplication in these cells and propose that this occurs independently of the effects of E2 on p53 and cell cycle progression. Since the effect of E2 was not seen in keratinocytes lacking the HPV-16 episome, we suggest that E2 can help AAV by working in concert with other HPV-16 proteins.     

EB病毒感染人胎鼻咽上皮细胞逃避老化期过程中抑制p16INK4a表达

细胞周期调控紊乱是细胞永生化进程中一个重要的分子事件,本文利用Western blotting和S-P法分别检测p16~(INK4a)、p53、p21~(WAF1/CIP1)和E2F1的蛋白表达,试图从细胞周期调控的角度,探讨EB病毒诱导人胎鼻咽上皮细胞逃避老化期的分子机制。结果表明,EB病毒通过抑制p16~(INK4a)表达而阻断p16~(INK4a)/Rb途径,上调转录因子E2F1,而对p53、p21~(WAF1/CIP1)表达无明显的影响。结果初步揭示,EB病毒介导的p16~(INK4a)/Rb/E2F1细胞周期调控紊乱参与了人胎鼻咽上皮细胞逃避老化期过程,为进一步探讨鼻咽癌发病机制提供了科学依据。     

EB病毒感染人胎鼻咽上皮细胞逃避老化期过程中抑制p16^INK4a表达

细胞周期调控紊乱是细胞永生化进程中一个重要的分子事件,本文利用Western blotting和S-P法分别检测p16^INK4a、p53、p21^WAF1／CIP1和E2F1的蛋白表达,试图从细胞周期调控的角度,探讨EB病毒诱导人胎鼻咽上皮细胞逃避老化期的分子机制。结果表明,EB病毒通过抑制p16^INK4a表达而阻断p16^INK4a／Rb途径,上调转录因子E2F1,而对p53、p21^WAF1／CIP表达无明显的影响。结果初步揭示,EB病毒介导的p16^INK4a／Rb／E2F1细胞周期调控紊乱参与了人胎鼻咽上皮细胞逃避老化期过程,为进一步探讨鼻咽癌发病机制提供了科学依据。     

E2F and Ras synergize in transcriptionally activating p14ARF expression

The INK4a/ARF locus, which is frequently inactivated in human tumors, encodes two distinct tumor suppressive proteins, ARF and p16INK4a. ARF stabilizes and activates p53 by negating the effects of mdm2 on p53. Furthermore, its function is not restricted to the p53 pathway and it also inhibits cell proliferation in cells lacking p53. Expression of ARF is up-regulated in response to a number of oncogenic stimuli including E2F1. We show here that while oncogenic Ras does not significantly affect p1(4AR)F expression in normal human cells it activates p1(4AR)F in cells containing deregulated E2F. Moreover, oncogenic Ras and E2F1 synergize in activating p1(4AR)F expression. Activation of p1(4AR)F promoter by E2F1 persists in the absence of the consensus E2F-binding sites in this promoter, indicating that this activation also occurs through non- canonical binding sites. The activation by oncogenic Ras requires both E2F and Sp-1 activity, demonstrating the complex regulation of p14(ARF) in response to oncogenic stimuli.