Phosphatidylinositol 3-Kinase-, Actin-, and Microtubule-Dependent Transport of Semliki Forest Virus Replication Complexes from the Plasma Membrane to Modified Lysosomes
Like other positive-strand RNA viruses, alphaviruses replicate their genomes in association with modified intracellular membranes. Alphavirus replication sites consist of numerous bulb-shaped membrane invaginations (spherules), which contain the double-stranded replication intermediates. Time course studies with Semliki Forest virus (SFV)-infected cells were combined with live-cell imaging and electron microscopy to reveal that the replication complex spherules of SFV undergo an unprecedented large-scale movement between cellular compartments. The spherules first accumulated at the plasma membrane and were then internalized using an endocytic process that required a functional actin-myosin network, as shown by blebbistatin treatment. Wortmannin and other inhibitors indicated that the internalization of spherules also required the activity of phosphatidylinositol 3-kinase. The spherules therefore represent an unusual type of endocytic cargo. After endocytosis, spherule-containing vesicles were highly dynamic and had a neutral pH. These primary carriers fused with acidic endosomes and moved long distances on microtubules, in a manner prevented by nocodazole. The result of the large-scale migration was the formation of a very stable compartment, where the spherules were accumulated on the outer surfaces of unusually large and static acidic vacuoles localized in the pericentriolar region. Our work highlights both fundamental similarities and important differences in the processes that lead to the modified membrane compartments in cells infected by distinct groups of positive-sense RNA viruses.All positive-strand RNA viruses replicate their genomes in association with cellular membranes. The formation and activity of the membrane-bound replication complexes (RCs) can result in extensive alteration of membrane structures (11,40,48). Different viruses use different cytoplasmic membrane compartments as platforms for replication. Currently, there is only a limited understanding of how the virus-encoded and cellular proteins coordinate the formation of the replicationinduced membrane structures. We address the mechanisms of membrane-bound replication with alphaviruses, particularly Semliki Forest virus (SFV). The alphaviruses comprise several human and animal pathogens, including the encephalitogenic alphaviruses (e.g., Western, Eastern, and Venezuelan equine encephalitis viruses) as well as the recently reemerging chikungunya virus, which belongs to the SFV clade of alphaviruses. During the past 5 years, chikungunya virus has caused more than 2 million infections and 500 deaths, and a new strain has spread throughout the areas surrounding the Indian Ocean (50). The alphaviruses use mosquitoes as intermediate hosts and transmission vectors, and at present no vaccines or antivirals are available to control these infections.The cytoplasmic replication of alphaviruses depends on the four viral nonstructural (ns) proteins, nsP1 to nsP4, which are all essential and act as a membrane-bound replication complex. The nsPs are tran...
Assembly of Alphavirus Replication Complexes from RNA and Protein Components in a Novel trans -Replication System in Mammalian Cells
For positive-strand RNA viruses, the viral genomic RNA also acts as an mRNA directing the translation of the replicase proteins of the virus. Replication takes place in association with cytoplasmic membranes, which are heavily modified to create specific replication compartments. Here we have expressed by plasmid DNA transfection the large replicase polyprotein of Semliki Forest virus (SFV) in mammalian cells from a nonreplicating mRNA and provided a separate RNA containing the replication signals. The replicase proteins were able to efficiently and specifically replicate the template in trans, leading to accumulation of RNA and marker gene products expressed from the template RNA. The replicase proteins and double-stranded RNA replication intermediates localized to structures similar to those seen in SFV-infected cells. Using correlative light electron microscopy (CLEM) with fluorescent marker proteins to relocate those transfected cells, in which active replication was ongoing, abundant membrane modifications, representing the replication complex spherules, were observed both at the plasma membrane and in intracellular endolysosomes. Thus, replication complexes are faithfully assembled and localized in the trans-replication system. We demonstrated, using CLEM, that the replication proteins alone or a polymerase-negative polyprotein mutant together with the template did not give rise to spherule formation. Thus, the trans-replication system is suitable for cell biological dissection and examination in a mammalian cell environment, and similar systems may be possible for other positive-strand RNA viruses.
Semliki Forest virus RNA replication takes place in association with specific cytoplasmic vacuoles, derived from the endosomal apparatus. Of the four virus-encoded replicase proteins, nsP1 serves as the membrane anchor of the replication complex. An amphipathic peptide segment, G 245 STLYTESRKLLRSWHLPSV 264 , has been implicated in the membrane binding of nsP1. nsP1 variants with changes within the peptide were studied after protein expression and in the context of virus infection. Proteins with mutations R253E and W259A accumulated in the cytoplasm and were very poorly palmitoylated. The same mutations also drastically affected the localization of the precursor polyprotein P123, and they were lethal when introduced into the virus genome. Mutations R253A and L255A؉L256A partially changed the localization of nsP1, and the respective viruses acquired compensatory changes. L255A؉L256A only yielded virus encoding L255A؉L256V, indicating the importance of a hydrophobic residue in the central 256 position. When fused to green fluorescent protein, the peptide was required in at least two tandem copies to effect a change in localization, but even then the fusion protein was associated with membranes in a nonspecific manner. Thus, the amphipathic peptide is a crucial element for the membrane association of nsP1 and the replication complex. It provides essential affinity for membranes, and other regions of nsP1 also appear to contribute to the localization of the protein.
The replication complexes of positive-strand RNA viruses are always associated with cellular membranes. The morphology of the replication-associated membranes is altered in different ways in different viral systems, but many viruses induce small membrane invaginations known as spherules as their replication sites. We show here that for Semliki Forest virus (SFV), an alphavirus, the size of the spherules is tightly connected with the length of the replicating RNA template. Cells with different model templates, expressed in trans and copied by the viral replicase, were analyzed with correlative light and electron microscopy. It was demonstrated that the viral-genome-sized template of 11.5 kb induced spherules that were ϳ58 nm in diameter, whereas a template of 6 kb yielded ϳ39-nm spherules. Different sizes of viral templates were replicated efficiently in trans, as assessed by radioactive labeling and Northern blotting. The replication of two different templates, in cis and trans, yielded two size classes of spherules in the same cell. These results indicate that RNA plays a crucial determining role in spherule assembly for SFV, in direct contrast with results from other positive-strand RNA viruses, in which either the presence of viral RNA or the RNA size do not contribute to spherule formation.
Hepatitis E virus (HEV) is a positive-strand RNA virus and a major causative agent of acute sporadic and epidemic hepatitis. HEV replication protein is encoded by ORF1 and contains the predicted domains of methyltransferase (MT), protease, macro domain, helicase (HEL) and polymerase (POL). In this study, the full-length protein pORF1 (1693 aa) and six truncated variants were expressed by in vitro translation and in human HeLa and hepatic Huh-7 cells by using several vector systems. The proteins were visualized by three specific antisera directed against the MT, HEL and POL domains. In vitro translation of full-length pORF1 yielded smaller quantities of two fragments. However, these fragments were not observed after pORF1 expression and pulse-chase studies in human cells, and their production was not dependent on the predicted protease domain in pORF1. The weight of evidence supports the proposition that pORF1 is not subjected to specific proteolytic processing, which is unusual among animal positive-strand RNA viruses but common for plant viruses. pORF1 was membrane associated in cells and localized to a perinuclear region, where it partially overlapped with localization of the endoplasmic reticulum (ER) marker BAP31 and was closely interspersed with staining of the ERGolgi intermediate compartment marker protein ERGIC-53. Co-localization with BAP31 was enhanced by treatment with brefeldin A. Therefore, HEV may utilize modified early secretory pathway membranes for replication.
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