The role of myristylation, a fatty acid modification of nascent polypeptides, in the assembly and intracellular transport of D-type retroviral capsids was investigated through the use of oligonucleotide-directed mutagenesis. Myristic acid is normally esterified through an amide linkage to a glycine residue at the amino terminus of the Mason-Pfizer monkey virus gag gene products. Mutant pA-1, which has a codon for valine substituted for that of the normally myristylated glycine, is completely noninfectious. While the mutant gag polyprotein precursors are synthesized at normal levels, they are not myristylated and are not cleaved to the mature virion proteins. No extracellular virus particles are released from mutant pA-1-infected cells, but intracytoplasmic A-type particles (capsids) accumulate in the cytoplasm. Since none of the intracellular capsids can be found associated with the plasma membrane, these results strongly suggest that myristylation is a critical signal for intracytoplasmic transport of completed viral capsids to their normal site of budding and release.
The functional roles of the matrix (MA) protein in the assembly and maturation of retroviruses was investigated with a series of MA mutants of Mason‐Pfizer monkey virus (M‐PMV), an immunosuppressive type D retrovirus. The mutants we describe here were generated by the introduction of random point mutations within the MA coding domain by use of sodium bisulphite mutagenesis. Studies of these mutants show that the MA protein plays a critical role in three different, sequential events in the final stages of type D retrovirus replication: (i) folding of the gag gene‐encoded precursor poly‐proteins into a stable conformation for capsid assembly in the cytoplasm of infected cells; (ii) capsid transport from the site of assembly to the plasma membrane; and (iii) capsid association with, and extrusion of the membrane during virus budding. The mutants described here interfere with or block M‐PMV replication at each of these stages. Large numbers of preassembled capsids accumulate within the cytoplasm of transport‐defective mutant‐infected cells, suggesting that transport of M‐PMV capsids to the plasma membrane is an active and specific intracellular targeting process. The initial association of the capsid with the membrane may depend upon this intracytoplasmic transport process but additional protein‐lipid interactions that involve the MA protein are required for membrane extrusion around the preformed capsids; in cells infected with the budding‐defective mutant, assembled capsids accumulate under the inner surface of the cell plasma membrane, and are retarded in their release from the infected cell.
Human immunodeficiency virus type 1 (HIV-1) Nef is a myristylated protein with a relative molecular mass of 27 kDa, is localized to the cytoplasmic surfaces of cellular membranes, and has been reported to down-modulate CD4 in human T cells. To understand the mechanism of HIV-1 Nef-mediated down-modulation of cell surface CD4, we expressed Nef protein in human T-cell line VB. Expression of HIV-1 Nef protein down-modulated surface CD4 molecules. In pulse-chase experiments, CD4 molecules in Nef-expressing cells were synthesized at normal levels. However, the bulk of newly synthesized CD4 protein was degraded with a half-life of approximately 6 h, compared with the 24-h half-life in control cells. This Nef-induced acceleration of CD4 turnover was inhibited by lysosomotropic agents NH4Cl and chloroquine as well as by the protease inhibitor leupeptin. Surface CD4 biotinylation experiments demonstrated that CD4 molecules in Nefexpressing T cells are transported to the plasma membrane with normal kinetics but are then rapidly internalized. Therefore, HIV-1 Nef-induced down-modulation of CD4 is due to rapid internalization of surface CD4 and subsequent degradation by an acid-dependent process, potentially lysosomal. Additionally, in a Nef-expressing cell, we find accelerated dissociation of the T-cell tyrosine kinase p561k" and CD4 but only after the complex reaches the plasma membrane. This implies that HIV-1 Nef protein might play a role in triggering a series of T-cell activation-like events, which contribute to p561ck dissociation and internalization of surface CD4 molecules.
The envelope glycoprotein precursor of retroviruses undergoes proteolytic cleavage in the Golgi complex to yield the mature surface and transmembrane (TM) glycoproteins of the virus. We report here that the TM glycoprotein of Mason-Pfizer monkey virus undergoes a second proteolytic processing event during a late maturation step that can follow virus release and Gag polyprotein cleavage. Cleavage results in the conversion of the cell-associated TM glycoprotein (gp22) to a virus-associated gp2O. Processing continues after virus release and yields virions that contain predominantly gp2O. A mutation within the active site of the Mason-Pfizer monkey virus aspartyl protease was shown to block both TM glycoprotein cleavage and the processing of the Gag polyprotein precursor. The role of the viral protease in cleavage of the TM glycoprotein localizes the cleavage site to the cytoplasmic domain of this protein. Surprisingly, point mutations within the matrix (MA) coding region of the gag gene can affect the extent to which gp22 is processed to gp2O and in one case
Rous sarcoma virus (RSV) and its relatives are unique in that they appear to encode their viral protease in the gag reading frame. As a result, this 124-amino-acid sequence is found at the carboxy terminus of each Gag precursor molecule and, upon ribosome frameshifting, embedded within each Gag-Pol molecule. However, rigorous proof has never been obtained for the activity of this 124-amino-acid Gag domain during virion assembly in vivo. If the active protease actually included amino acids encoded downstream in the pol reading frame, then the sequence organization would be more in line with those of other retroviruses. To examine this issue, mutations that disrupt the addition of amino acids by ribosome frameshifting were analyzed for their effects on particle assembly and Gag processing in a mammalian expression system (
The capsid precursor protein (Gag) of Mason-Pfizer monkey virus, the prototype type D retrovirus, has been expressed to high levels in bacteria under the control of the phage T7 promoter. Electron microscopic studies of induced cells revealed the assembly of capsid-like structures within inclusion bodies that formed at the poles of the cells 6 h after induction with isopropyl--D-thiogalactopyranoside (IPTG). The inclusion bodies and enclosed capsid-like structures were solubilized completely in 8 M urea, but following renaturation, we observed assembly in vitro of capsid-like structures that demonstrated apparent icosahedral symmetry. These results demonstrate for the first time that retroviral capsid precursors have the propensity to self-assemble in vitro and point to new approaches for the analysis of retroviral assembly and structure.
The carboxy terminus-encoding portion of the gag gene of Mason-Pfizer monkey virus (M-PMV), the prototype immunosuppressive primate type D retrovirus, encodes a 36-amino-acid, proline-rich protein domain that, in the mature virion, becomes the p4 capsid protein. The p4 domain has no known role in M-PMV replication. We found that two mutants with premature termination codons that remove half or all of the p4 domain produced lower levels of stable Gag protein and of self-assembled capsids. Interestingly, yeast twohybrid screening revealed that p4 specifically interacted with TCP-1␥, a subunit of the chaperonin TRiC (TCP-1 ring complex). TRiC is a cytosolic chaperonin that is known to be involved in both folding and subunit assembly of a variety of cellular proteins. TCP-1␥ also associated with high specificity with the M-PMV pp24/16-p12 domain and human immunodeficiency virus p6. Moreover, in cells, Gag polyprotein associated with the TRiC chaperonin complex and this association depended on ATP hydrolysis. In the p4 truncation mutants, the Gag-TRiC association was significantly reduced. These results strongly suggest that cytosolic chaperonin TRiC is involved in Gag folding and/or capsid assembly. We propose that TRiC associates transiently with nascent M-PMV Gag molecules to assist in their folding. Consequently, properly folded Gag molecules carry out the intermolecular interactions involved in self-assembly of the immature capsid.
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