The Endoplasmic Reticulum Chaperone BiP/GRP78 Is Important in the Structure and Function of the Human Cytomegalovirus Assembly Compartment

We previously demonstrated that the endoplasmic reticulum (ER) chaperone BiP functions in human cytomegalovirus (HCMV) assembly and egress. Here, we show that BiP localizes in two cytoplasmic structures in infected cells. Antibodies to the extreme C terminus, which includes BiP''s KDEL ER localization sequence, detect BiP in regions of condensed ER near the periphery of the cell. Antibodies to the full length, N terminus, or larger portion of the C terminus detect BiP in the assembly compartment. This inability of C-terminal antibodies to detect BiP in the assembly compartment suggests that BiP''s KDEL sequence is occluded in the assembly compartment. Depletion of BiP causes the condensed ER and assembly compartments to dissociate, indicating that BiP is important for their integrity. BiP and pp28 are in association in the assembly compartment, since antibodies that detect BiP in the assembly compartment coimmunoprecipitate pp28 and vice versa. In addition, BiP and pp28 copurify with other assembly compartment components on sucrose gradients. BiP also coimmunoprecipitates TRS1. Previous data show that cells infected with a TRS1-deficient virus have cytoplasmic and assembly compartment defects like those seen when BiP is depleted. We show that a fraction of TRS1 purifies with the assembly compartment. These findings suggest that BiP and TRS1 share a function in assembly compartment maintenance. In summary, BiP is diverted from the ER to associate with pp28 and TRS1, contributing to the integrity and function of the assembly compartment.Human cytomegalovirus (HCMV), the largest of the human herpesviruses, is capable of encoding over 200 proteins, which are expressed in temporal fashion as immediate-early, early, delayed-early, and late genes. Despite the extensive coding capacity of HCMV, its replication cycle is slow. During this protracted period, the virus must maintain optimal replication conditions in the host cell. However, the increasing strain of the infection induces cellular stress responses with consequences that may be deleterious to the progress of the infection. We and others have previously shown that HCMV has multiple mechanisms to deal with the deleterious aspects of cellular stress responses while maintaining beneficial ones (2, 8-10, 14, 17, 18, 22-24, 26, 27, 50, 51).An example of these mechanisms is the viral control of endoplasmic reticulum (ER) stress and the unfolded protein response (UPR). Due to the number of HCMV proteins that are glycosylated, or receive other ER-dependent posttranslational modifications, the load of proteins in the ER can exceed its capacity, resulting in ER stress and the activation of the UPR (18, 47, 51). However, we and others have shown that HCMV controls and modulates the UPR, maintaining aspects that may benefit the viral infection while inhibiting aspects that would be detrimental (18, 51).The UPR is normally controlled by transmembrane sensors which initiate the complex UPR signaling cascade when activated by ER stress (reviewed in references 20, 35, 38, and 52). The ER molecular chaperone BiP (immunoglobulin heavy chain-binding protein), also called glucose-regulated protein 78 (GRP78), is believed to bind these sensors and keep them inactive during unstressed conditions. However, when unfolded or misfolded proteins accumulate in the ER, BiP leaves these sensors to perform its chaperone function, thus allowing the sensors to activate UPR signaling. We have previously shown that during HCMV infection, BiP is vastly overproduced (8), suggesting that BiP may have other functions in the viral infection. Indeed, it has been shown that BiP binds to the viral proteins US2 and US11; this interaction is necessary for the virus-mediated degradation of major histocompatibility complex class I and II (15, 47). Further, we have shown that depletion of BiP, using either the BiP-specific subtilase cytotoxin SubAB (32) or short hairpin RNAs, caused infectious virion formation in the cytoplasm to cease and nucleocapsids to accumulate just outside the outer nuclear membrane (8). This result suggested that BiP has a significant role in virion formation and cytoplasmic egress.Although the exact mechanism of virion formation in the cytoplasm is not well understood, studies have identified a perinuclear structure, referred to as the cytoplasmic assembly compartment, that is involved in the process. Several viral proteins, for example, tegument proteins (pp28, pp65) (36) and viral glycoproteins (gB, gH, gL, gO, gp65) (36, 46), have been identified as part of this structure. Defining the exact origin of this compartment has been complicated by the observation of specific organellar markers in and around the compartment, while other markers of the same organelles are not detected. For example, immunofluorescence examination suggests that the early endosomal marker early endosome antigen 1 (EEA1) has been observed in the center of the assembly compartment (12, 13); however, Rab4 and Rab5, other early endosomal markers, were not detected (16). Such observations suggest that the virus directs specific viral and cellular proteins to the assembly compartment as needed for assembly compartment function.In the present study, we further examine the role of BiP during an HCMV infection, including its localization and interactions with other proteins. We show here that in infected cells, BiP localizes in two distinct structures, regions of condensed ER near the periphery of the cell and the assembly compartment. The data suggest that BiP diversion from the ER to the assembly compartment is due to occlusion of its ER localization signal. Depletion of BiP causes both condensed ER and assembly compartments to disperse, indicating that BiP is important for their formation or maintenance. BiP and pp28 appear to associate in the assembly compartment, since BiP from the assembly compartment coimmunoprecipitates pp28 and vice versa. In addition, both BiP and pp28 copurify with the assembly compartment on sucrose gradients. BiP also coimmunoprecipitates TRS1. Previous studies (1, 4) have shown that cells infected with HCMV with a mutation in the TRS1 gene show cytoplasmic and assembly compartment defects like those seen when BiP is depleted (reference 8 and the studies presented below). We show that a fraction of TRS1 purifies with the assembly compartment, indicating a shared assembly compartment function with BiP. In summary, our data suggest that BiP is diverted from the ER to associate with pp28 and TRS1, contributing to the integrity and function of the assembly compartment.