Latent membrane protein 1 (LMP1) of Epstein-Barr virus (EBV) is an integral membrane protein whichhas transforming potential and is necessary but not sufficient for B-cell immortalization by EBV. LMP1 molecules aggregate in the plasma membrane and recruit tumour necrosis factor receptor (TNF-R) -associated factors (TRAFs) which are presumably involved in the signalling cascade leading to NF-κB activation by LMP1. Comparable activities are mediated by CD40 and other members of the TNF-R family, which implies that LMP1 could function as a receptor. LMP1 lacks extended extracellular domains similar to β-adrenergic receptors but, in contrast, it also lacks any motifs involved in ligand binding. By using LMP1 mutants which can be oligomerized at will, we show that the function of LMP1 in 293 cells and B cells is solely dependent on oligomerization of its carboxyterminus. Biochemically, oligomerization is an intrinsic property of the transmembrane domain of wild-type LMP1 and causes a constitutive phenotype which can be conferred to the signalling domains of CD40 or the TNF-2 receptor. In EBV, immortalized B cells crosslinking in conjunction with membrane targeting of the carboxy-terminal signalling domain of LMP1 is sufficient for its biological activities. Thus, LMP1 acts like a constitutively activated receptor whose biological activities are ligand-independent.
. 79:3703-3712). Here we describe the characterization of the product of the EBV BFLF2 gene, which belongs to a family of conserved herpesviral genes which include the UL31 genes of herpes simplex virus and of pseudorabies virus and whose products are known to interact with UL34, the positional homolog of BFRF1. BFLF2 is an early transcript and is expressed in a variety of cell lines upon EBV lytic cycle activation. Western blotting of purified virion preparations showed that BFLF2 is a component of intracellular virions but is absent from mature extracellular virions. Coimmunoprecipitation experiments indicated that BFLF2 interacts with BFRF1, which was confirmed by immunofluorescence confocal microscopy showing that the two proteins colocalize on the nuclear membrane not only upon cotransfection in epithelial cells but also during viral replication. In cells carrying an EBV mutant with the BFRF1 gene deleted (293-BFRF1-KO cells) BFLF2 expression was low, and it was restored to wild-type levels upon treatment of the cells with the proteasome inhibitor MG132. Furthermore, recomplementing the 293-BFRF1-KO cells by BFRF1 transfection restored BFLF2 expression to the wild-type level. In addition, when expressed alone BFLF2 was localized diffusely inside the nucleus, whereas in the presence of BFRF1 the two proteins colocalized at the nuclear rim. Finally, 293 epithelial cells transfected with either protein or cotransfected were analyzed by electron microscopy to investigate potential alterations in the morphology of the nuclear membrane. The ultrastructural analysis revealed that (i) BFRF1 caused duplications of the nuclear membrane, similar to those reported to occur during the course of herpesviral replication, and (ii) while BFLF2 alone did not cause any apparent alteration, coexpression of the two proteins dramatically induced profound convolutions of the duplicated nuclear membrane. Both biochemical and morphological analysis showed association of the BFRF1-BFLF2 complex with a component of the nuclear lamina, lamin B. Taken together, these results and those of the accompanying paper (Farina et al., J. Virol. 79:3703-3712) indicate an important role of BFRF1 and BFLF2 in the early steps of EBV maturation at the nuclear membrane.Two conserved herpesvirus proteins, designated UL34 and UL31, of herpes simplex virus (HSV) and pseudorabies virus (PrV) are involved in the early steps of viral maturation at the nuclear envelope (reviewed in reference 26). With many similarities and a few differences, accumulating evidence indicates that these proteins and their homologs play similar roles in nuclear egress of both alpha-and betaherpesviruses (9,17,23,30,33,34,36,37,40,48,50). The physical interaction between the two proteins appears to be important to facilitate virion envelopment at the inner nuclear membrane, a process which probably also involves nuclear lamina disruption, to allow nucleocapsids to gain access at the interior face of the nuclear envelope (28, 39).We initially identified and characterized the prod...
Autophagy is a catabolic pathway that helps cells to survive under stressful conditions. Cells also use autophagy to clear microbiological infections, but microbes have learned how to manipulate the autophagic pathway for their own benefit. The experimental evidence obtained in this study suggests that the autophagic flux is blocked at the final steps during the reactivation of Epstein-Barr virus (EBV) from latency. This is indicated by the level of the lipidated form of LC3 that does not increase in the presence of bafilomycin and by the lack of colocalization of autophagosomes with lysosomes, which correlates with reduced Rab7 expression. Since the inhibition of the early phases of autophagy impaired EBV replication and viral particles were observed in autophagic vesicles in the cytoplasm of producing cells, we suggest that EBV exploits the autophagic machinery for its transportation in order to enhance viral production. The autophagic block was not mediated by ZEBRA, an immediate-early EBV lytic gene, whose transfection in Ramos, Akata, and 293 cells promoted a complete autophagic flux. The block occurred only when the complete set of EBV lytic genes was expressed. We suggest that the inhibition of the early autophagic steps or finding strategies to overcome the autophagic block, allowing viral degradation into the lysosomes, can be exploited to manipulate EBV replication. IMPORTANCEThis study shows, for the first time, that autophagy is blocked at the final degradative steps during EBV replication in several cell types. Through this block, EBV hijacks the autophagic vesicles for its intracellular transportation and enhances viral production. A better understanding of virus-host interactions could help in the design of new therapeutic approaches against EBV-associated malignancies.
The molecular mechanisms that underlie maturation and egress of Epstein-Barr virus (EBV) virions are only partially characterized. We have recently shown that the BFRF1 gene, the EBV positional homolog of herpes simplex virus type 1 and pseudorabies virus UL34, is expressed early during EBV lytic replication and that it is found predominantly on the nuclear membrane (A. Farina, R. Santarelli, R. Gonnella, R. Bei, R. Muraro, G. Cardinali, S. Uccini, G. Ragona, L. Frati, A. Faggioni, and A. Angeloni, J. Virol. 74:3235-3244, 2000). These data suggest that the BFRF1 protein might be involved in viral primary envelopment. To precisely determine the function of this protein, we have constructed an EBV mutant devoid of the BFRF1 gene (BFRF1-KO). 293 cells carrying BFRF1-KO showed no differences in comparison with wild-type EBV in terms of DNA lytic replication or expression of late viral proteins upon induction of the lytic cycle. However, binding assays and infection experiments using cell lines or human cord blood lymphocytes showed a clear reduction in the viral mutant titers. Complementation experiments with BFRF1-KO and a BFRF1 expression vector restored viral titers to levels similar to those for the wild-type control, showing that the modifications that we introduced were limited to the BFRF1 gene. Electron microscopic observations showed that the reduction in viral titers was due to sequestration of EBV nucleocapsids in the nuclei of lytically induced cells. This suggests that BFRF1 is involved in transport of the maturing virion across the nuclear membrane. This hypothesis was further supported by the observation that BFRF1 is present in maturing intracellular virions but not in their extracellular counterparts. This implies that BFRF1 is a key protein for EBV maturation.Epstein-Barr virus (EBV) is one of the eight known human herpesviruses. This member of the gammaherpesvirus subfamily infects B lymphocytes, in which it establishes a latent infection characterized by the expression of a limited set of viral genes (25). Viral reactivation from the latent state either occurs spontaneously or is induced by a variety of different stimuli (11,30,32,49,55), leading to viral lytic replication and shedding of viral progeny. The EBV lytic program consists of the sequential activation of three distinct classes of viral genes: immediate early, early, and late. The two transactivators BZLF1 (ZEBRA) and BRLF1 (Rta) are immediate-early genes that can initiate the switch between latency and lytic replication (14,24,41). Early genes are frequently but not exclusively involved in viral DNA replication; these genes include, among many others, those for the viral DNA polymerase (31) and its processivity factor BMRF1 (5), the bcl-2 homolog BHRF1 (38), and the major DNA binding protein BALF2 (8).Late genes are known to encode predominantly structural proteins, such as gp350/220, the most abundant glycoprotein of the viral envelope. gp350/220 mediates the binding of the virus to its cognate receptor CR2 (50). Herpesvirus DNA repli...
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