Amino-terminal deletion mutants of the Rous sarcoma virus glycoprotein do not block signal peptide cleavage but can block intracellular transport

Viral acylproteins: greasing the wheels of assembly

Viruses take advantage of the host's protein modification and targeting pathways to modify their own proteins and to ensure that they assume active configurations and locate appropriately for assembly. In many viruses, one recurrent theme in such processes is exploitation of cellular protein acylation pathways for the addition of myristic and palmitic acid to capsid or envelope proteins.

Oligomerization and transport of the envelope protein of Moloney murine leukemia virus-TB and of ts1, a neurovirulent temperature-sensitive mutant of MoMuLV-TB

Ts1, a temperature-sensitive mutant of Moloney murine leukemia virus-TB (MoMuLV-TB), causes a progressive hindlimb paralytic disease in susceptible strains of mice. Previously, it has been shown that a single amino acid substitution, Val-25----Ile in gPr80env, is responsible for the temperature sensitivity, inefficient transport, and processing of gPr80env at the restrictive temperature and the neurovirulence of ts1. Since the neurovirulence of ts1 is associated with inefficient transport and processing of gPr80env and since in other systems involving viral envelope proteins it has been shown that correct folding and oligomerization of envelope monomers are required for efficient transport, we have investigated the ability of gPr80env derived from either wild-type MoMuLV-TB or ts1 to associate into oligomeric complexes. In these experiments, we establish that at both the restrictive and the nonrestrictive temperatures gPr80env molecules derived from MoMuLV-TB associate to form oligomeric complexes and these oligomers are most likely trimers. gPr80env molecules derived from ts1 also oligomerize at both temperatures; however, at the restrictive temperature, most of the molecules within the trimeric complexes remain as gPr80env and are not processed to gp70 and Prp15E. These results indicate that lack of oligomerization of gPr80env is not responsible for the transport defect of ts1. Therefore, by interacting specifically with critical sites within target cells, oligomers of mutant gPr80env rather than "tangles" of monomeric viral envelope proteins may be involved in the neurodegenerative disorder produced by ts1.

Analysis of mutations in the envelope gene of Moloney murine leukemia virus: separation of infectivity from superinfection resistance

Six deletion mutations and an insertion were generated in the env gene of cloned copies of Moloney murine leukemia virus DNA. All seven mutants were replication-defective as tested by transformation of NIH/3T3 cells. The mutant DNAs were introduced into NIH/3T3 cells to generate stable producer lines; all released virion particles into the medium, suggesting that none of the mutations affected overall viral gene expression, gag and pol gene expression, gag and pol gene functions, or virion budding. Several of the mutations reduced the lifetime of the env protein or blocked its export to the cell surface. One mutation altering the membrane-spanning region and the cytoplasmic tail of the TM protein had no effect on export of the protein, proteolytic processing, or incorporation into virion particles, but still blocked the infectivity of the resulting virus. The results suggest that alterations in the transmembrane region can affect early steps of infection, such as the fusion of virion and host membranes. Cells expressing this mutant env protein were fully resistant to superinfection by wild-type virus. Thus, induction of virus resistance, presumably reflecting blocking the virus receptor, can be separated from virus infectivity.

Human fur gene encodes a yeast KEX2-like endoprotease that cleaves pro-beta-NGF in vivo

Extracts from BSC-40 cells infected with vaccinia recombinants expressing either the yeast KEX2 prohormone endoprotease or a human structural homologue (fur gene product) contained an elevated level of a membrane-associated endoproteolytic activity that could cleave at pairs of basic amino acids (-LysArg- and -ArgArg-). The fur-directed activity (furin) shared many properties with Kex2p including activity at pH 7.3 and a requirement for calcium. By using antifurin antibodies, immunoblot analysis detected two furin translation products (90 and 96 kD), while immunofluorescence indicated localization to the Golgi apparatus. Coexpression of either Kex2p or furin with the mouse beta-nerve growth factor precursor (pro-beta-NGF) resulted in greatly enhanced conversion of the precursor to mature nerve growth factor. Thus, the sequence homology shared by furin and the yeast KEX2 prohormone processing enzyme is reflected by significant functional homology both in vitro and in vivo.

Domain deletion in the extracellular portion of the EGF-receptor reduces ligand binding and impairs cell surface expression

Cultured NIH-3T3 cells were transfected with cDNA constructs encoding human epidermal growth factor-receptor (EGF-R)* and two deletion mutants in the extracellular portion of the receptor molecule. One mutant is devoid of 124 amino-terminal amino acids, and the other lacks 76 residues. Mutant receptors were not delivered to the cell surface unless the transfected cells contained also endogenous EGF-Rs, suggesting that receptor interaction complements the mutation and allows surface display of mutant receptors. Immunoprecipitation experiments revealed an association between mutant and endogenous EGF-Rs when both proteins were expressed in the same cell. Hence, receptor-oligomers may exist in the plane of the membrane even in the absence of ligand binding, and oligomerization may play a role in normal trafficking of EGF-Rs to the cell surface. Mutant receptors retained partial ligand binding activity as 125I-labeled EGF was covalently cross-linked to both mutant receptors, and EGF stimulated, albeit weakly, their protein tyrosine kinase activity. Both mutant EGF-Rs bind EGF with a 10-fold lower affinity than that of the solubilized wild type EGF-R. These results provide further evidence that the region flanked by the two cysteine-rich domains plays a crucial role in defining ligand-binding specificity of EGF-R.

Creation and expression of myristylated forms of Rous sarcoma virus gag protein in mammalian cells

Rous sarcoma virus (RSV), a member of the avian sarcoma and leukosis family of retroviruses, has long been known to be capable of infecting and transforming mammalian cells; however, such transformed cells do not release virus particles. The RSV gag product (Pr76gag) produced in these cells is not released into the culture medium or proteolytically processed to release mature products. Thus, the behavior of Pr76gag in mammalian cells is much like that of mammalian retroviral Gag proteins which have been altered so as to block the addition of myristic acid at residue 2 (Gly). Because the RSV gag product does not possess a myristic acid addition site, we hypothesized that the creation of one by oligonucleotide-directed mutagenesis might permit particles to be released from mammalian cells. Two myristylated forms of Pr76 were created. In Pr76myr1, the first 10 amino acids have been exchanged for those of p60v-src, which are known to be sufficient for myristylation. In Pr76myr2, the Glu at the second residue has been substituted with Gly. The alleles encoding the modified and wild-type forms of Pr76 have been expressed at high levels in mammalian (CV-1) cells by using an SV40-based vector. Surprisingly, we have found that expression of high levels of the unmodified (wild-type) product, Pr76myr0, results in low levels of particle formation and precursor processing. This indicates that myristic acid is not the sole determinant for targeting. However, the addition of myristic acid to Pr76myr1 or Pr76myr2 resulted in a fivefold enhancement in Gag function. In all aspects examined, the behavior of myristylated Pr76 was identical to that of the authentic product produced in avian cells. We also show that processing is mediated by the gag-encoded protease and that removal of the amino terminus to create Pr76gagX results in an inability to form particles or be processed. This suggests that proper targeting is prerequisite for activation of the RSV protease in mammalian cells.

Processing, surface expression, and immunogenicity of carboxy-terminally truncated mutants of G protein of human respiratory syncytial virus

Posttranslational processing and cell surface expression were examined for three C-terminally truncated mutants of the G protein of respiratory syncytial virus expressed from engineered cDNAs. The truncated mutants, encoded by cDNAs designated G71, G180, and G230, contained the N-terminal 71, 180, and 230 amino acids, respectively, of the 298-amino-acid G protein. To facilitate detection of G71, which reacted inefficiently with G-specific antisera, we constructed a parallel set of cDNAs, designated G71/13, G180/13, and G230/13, to encode the same truncated species with the addition of a C-terminal 13-amino-acid reporter peptide which could be detected efficiently with an antipeptide serum. G71, G180, and G230 were expressed as species of Mr 7,500, 48,000, and 51,000, respectively, compared with 84,000 for parental G protein. The proteins encoded by G180 and G230, like parental G protein, contained both N-linked and O-linked carbohydrate. Also, the protein encoded by G71/13 appeared to be O glycosylated, showing that even this highly truncated form contained the structural information required to target the protein for O glycosylation. As for parental G protein, the estimated Mrs of the proteins encoded by G180 and G230 were approximately twice the calculated molecular weight of the polypeptide chain. Experiments with monensin showed that most of this difference between the calculated and observed Mr was due to posttranslational processing in or beyond the trans-Golgi compartment, presumably owing to the addition of carbohydrate or aggregation into dimers or both. Like parental G protein, all three truncated forms accumulated abundantly at the cell surface, and in each case the C terminus was extracellular. Thus, the N-terminal 71 amino acids of the G protein contained all the structural information required for efficient membrane insertion and cell surface expression, whereas the extracellular domain was dispensable for these activities. Cotton rats were immunized with recombinant vaccinia viruses expressing the G71, G180, G230, or parental G protein to compare their abilities to induce serum antibodies and resistance to challenge virus replication. The G71 and G180 recombinants failed to induce significant levels of G-specific antibodies or resistance to challenge, whereas the immunogenicity of G230 equaled or exceeded that of parental G protein. This suggested that the C-terminal 68 amino acids of the 236-amino-acid ectodomain do not contribute to the major epitope(s) of the G protein that is involved in inducing protective immunity.

Oligomeric structure of a prototype retrovirus glycoprotein

The structure of the Rous sarcoma virus envelope glycoprotein complex was studied by sedimentation gradient centrifugation analyses of detergent-solubilized wild-type and mutant envelope (env) gene products. These studies show that the envelope glycoprotein forms an oligomer during biosynthesis, which is most likely a trimer, and that this is the form of the complex found in virions. Our results are consistent with oligomer formation and transport out of the endoplasmic reticulum being closely linked. From analyses of mutant envelope proteins we conclude that the extracellular domain of the glycoprotein is sufficient for oligomer formation but that the transmembrane domain is required to stabilize this complex. Additional experiments suggest that interactions between external domains of the membrane-spanning, gp37 polypeptides are those most important for the formation of trimers. The significance of these observations to retroviral replication and implications for antiviral drug development are discussed.

A new Epstein-Barr virus transactivator, R, induces expression of a cytoplasmic early antigen

Several Epstein-Barr virus (EBV) early promoters respond to a new EBV transactivator encoded by BRLF1, designated R. Transactivation was measured in chloramphenicol acetyltransferase assays on Raji, BHK, and Vero cells that were cotransfected with the transactivator and target promoters linked to the cat gene. The divergent promoter of BamHI-H was particularly responsive to R transactivation. This large promoter region consists of a leftward TATA box for the NotI repeat gene (BHLF1) and a probable rightward TATA box for the EA-R gene (BHRF1) separated by 940 base pairs of unusual sequence complexity. Sequences within this divergent promoter region appear to confer inducibility by EBV transactivators R and Z (BZLF1). The Z transactivator stimulated expression in both the leftward and rightward directions, and R stimulated expression primarily in the rightward direction, but the MS transactivator (BMLF1) had no activity in either direction. The adenovirus E3 promoter also responded to the R transactivator, but several other herpesvirus and human promoters were nonresponsive. When the divergent promoter was linked to the EA-R gene as it is in the EBV genome, the R and Z transactivators also induced the expression of EA-R in cotransfected cells. This cytoplasmic early antigen is encoded by BHRF1 and may be anchored in intracellular membranes by a carboxy-terminal transmembrane region.

Adenovirus preterminal protein synthesized in COS cells from cloned DNA is active in DNA replication in vitro

Replication of the DNA genome of human adenovirus serotype 2 requires three virus-encoded proteins. Two of these proteins, the preterminal protein (pTP) and the adenovirus DNA polymerase, are transcribed from a single promoter at early times after virus infection. The mRNAs for these proteins share several exons, including one encoded near adenovirus genome coordinate 39. By using plasmids containing DNA fragments postulated to encode the various exons of pTP mRNA, the contributions of each exon to the synthesis of an active pTP have been measured. Only plasmids that contain both the open reading frame for pTP (genome coordinates 29.4 to 23.9) and the HindIII J fragment that contains the exon at genome coordinate 39 can express functional pTP.

Expression of enzymatically active adenovirus DNA polymerase from cloned DNA requires sequences upstream of the main open reading frame

Replication of human adenovirus (Ad) DNA requires three virus-encoded proteins that are coordinately transcribed from a single promoter at early times after infection. The mRNAs for two of these proteins, the preterminal protein (pTP) and the Ad DNA polymerase (Ad Pol), share several exons, including one encoded near Ad genome coordinate 39. Plasmids containing the putative exons that encode Ad Pol mRNA were constructed to determine if enzymatically active Ad Pol protein could be synthesized. An Ad Pol of 140 kDa was detected by immunoprecipitation with specific antibody and its enzymatic activity was confirmed by complementation of Ad DNA replication in vitro. In addition to an Ad2 DNA fragment from 24.7 to 9.2 map units which contains an open reading frame for a protein of 120 kDa, the HindIII-J fragment that encodes the exon at genome coordinate 39 can be shown to be essential for production of full-length (140 kDa), enzymatically active Ad Pol.

Mutants of the Rous sarcoma virus envelope glycoprotein that lack the transmembrane anchor and cytoplasmic domains: analysis of intracellular transport and assembly into virions

The envelope glycoprotein complex of Rous sarcoma virus consists of a knoblike, receptor-binding gp85 polypeptide that is linked through disulfide bonds to a membrane-spanning gp37 spike. We used oligonucleotide-directed mutagenesis to assess the role of the hydrophobic transmembrane region and hydrophilic cytoplasmic domain of gp37 in intracellular transport and assembly into virions. Early termination codons were introduced on either side of the hydrophobic transmembrane region, and the mutated env genes were expressed from the late promoter of simian virus 40. This resulted in the synthesis of glycoprotein complexes composed of a normal gp85 and a truncated gp37 molecule that lacked the cytoplasmic domain alone or both the cytoplasmic and transmembrane domains. The biosynthesis and intracellular transport of the truncated proteins were not significantly different from those of the wild-type glycoproteins, suggesting that any protein signals for biosynthesis and intracellular transport of this viral glycoprotein complex must reside in its extracellular domain. The glycoprotein complex lacking the cytoplasmic domain of gp37 is stably expressed on the cell surface in a manner similar to that of the wild type. In contrast, the complex lacking both the transmembrane and cytoplasmic domains is secreted as a soluble molecule into the media. It can be concluded, therefore, that the transmembrane domain alone is essential for anchoring the RSV env complex in the cell membrane and that the cytoplasmic domain is not required for anchor function. Insertion of the mutated genes into an infectious proviral genome allowed us to assess the ability of the truncated gene products to be assembled into virions and to determine whether such virions were infectious. Viral genomes encoding the secreted glycoprotein were noninfectious, whereas those encoding a glycoprotein complex lacking only the cytoplasmic domain of gp37 were infectious. Virions produced from these mutant-infected cells contained normal levels of glycoprotein. The cytoplasmic tail of gp37 is thus not required for the assembly of envelope glycoproteins into virions. It is unlikely, therefore, that this region of gp37 interacts with viral core proteins during the selective incorporation of viral glycoproteins into the viral envelope.

Computer-assisted predictions of signal peptidase processing sites

Computer programs are presented which incorporate 2 different algorithms for predicting the site of signal peptide cleavage for eukaryotic preproteins. These programs can be used to identify sites of signal peptidase cleavage of putative preproteins to facilitate the design and interpretation of signal peptide mutagenesis experiments, and to engineer artificial prepolypeptides.

The rate of bulk flow from the endoplasmic reticulum to the cell surface

Tripeptides containing the acceptor sequence for Asn-linked glycosylation (Asn-X-Ser/Thr) were added to CHO and HepG2 cells. The tripeptides were glycosylated in the ER and then secreted into the medium, via the Golgi complex in which the oligosaccharide chains were processed. The half-time for secretion, approximately 10 min, was faster than that of known proteins transported through the same pathway. Since much evidence suggests that oligosaccharide chains are not signals for transport, it appears that no signal is necessary for rapid and efficient transport from the ER to the Golgi, or from the Golgi to the cell surface. Rather, it appears that proteins retained as permanent residents en route through the ER-Golgi transport pathway must contain specific retention signals.

Expression of the Rous sarcoma virus env gene from a simian virus 40 late-region replacement vector: effects of upstream initiation codons

Expression of the Rous sarcoma virus envelope gene (env) from a simian virus 40 (SV40) late-region replacement vector is dependent on the position of env within the SV40 late-region sequences. The difference in expression levels appeared to be due to differences in the efficiency with which the env-specific transcripts were translated, because transcription levels from different constructions were similar. Deletion of the nucleotides encoding the agnoprotein initiator codon, located upstream of the env sequences in the poorly expressed construct, resulted in high levels of env expression. The agnoprotein initiator codon and overlapping open reading frame thus act as strong barriers to further ribosome scanning and prevent initiation at the env AUG codon. We conclude that AUG codons present in the late region of SV40 can reduce expression of inserted genes positioned downstream. Nevertheless, intrinsic properties of the gene may determine its ultimate level of expression.