African swine fever virus polyproteins pp220 and pp62 assemble into the core shell

African swine fever virus (ASFV), a complex enveloped DNA virus, expresses two polyprotein precursors, pp220 and pp62, which after proteolytic processing give rise to several major components of the virus particle. We have analyzed the structural role of polyprotein pp62, the precursor form of mature products p35 and p15, in virus morphogenesis. Densitometric analysis of one- and two-dimensional gels of purified virions showed that proteins p35 and p15, as well as the pp220-derived products, are present in equimolecular amounts in the virus particle. Immunoelectron microscopy revealed that the pp62-derived products localize at the core shell, a matrix-like domain placed between the DNA-containing nucleoid and the inner envelope, where the pp220-derived products are also localized. Pulse-chase experiments indicated that the processing of both polyprotein precursors is concomitant with virus assembly. Furthermore, using inducible ASFV recombinants, we show that pp62 processing requires the expression of the pp220 core precursor, whereas the processing of both precursors pp220 and pp62 is dependent on expression of the major capsid protein p72. Interestingly, when p72 expression is blocked, unprocessed pp220 and pp62 polyproteins assemble into aberrant zipper-like elements consisting of an elongated membrane-bound protein structure reminiscent of the core shell. Moreover, the two polyproteins, when coexpressed in COS cells, interact with each other to form zipper-like structures. Together, these findings indicate that the mature products derived from both polyproteins, which collectively account for about 30% of the virion protein mass, are the basic components of the core shell and that polyprotein processing represents a maturational process related to ASFV morphogenesis.     

Repression of African swine fever virus polyprotein pp220-encoding gene leads to the assembly of icosahedral core-less particles

African swine fever virus (ASFV) polyprotein pp220, encoded by the CP2475L gene, is an N-myristoylated precursor polypeptide that, after proteolytic processing, gives rise to the major structural proteins p150, p37, p34, and p14. These proteins localize at the core shell, a matrix-like virus domain placed between the DNA-containing nucleoid and the inner envelope. In this study, we have examined the role of polyprotein pp220 in virus morphogenesis by means of an ASFV recombinant, v220i, containing an inducible copy of the CP2475L gene regulated by the Escherichia coli repressor-operator system. Under conditions that repress pp220 expression, the virus yield of v220i was about 2.6 log units lower than that of the parental virus or of the recombinant grown under permissive conditions. Electron microscopy revealed that pp220 repression leads to the assembly of icosahedral particles virtually devoid of the core structure. Analysis of recombinant v220i by immunoelectron microscopy, immunoblotting, and DNA hybridization showed that mutant particles essentially lack, besides the pp220-derived products, a number of major core proteins as well as the viral DNA. On the other hand, transient expression of the CP2475L gene in COS cells showed that polyprotein pp220 assembles into electron-dense membrane-bound coats, whereas a mutant nonmyristoylated version of pp220 does not associate with cellular membranes but forms large cytoplasmic aggregates. Together, these findings indicate that polyprotein pp220 is essential for the core assembly and suggest that its myristoyl moiety may function as a membrane-anchoring signal to bind the developing core shell to the inner viral envelope.     

Assembly of African swine fever virus: role of polyprotein pp220.

Polyprotein processing is a common strategy of gene expression in many positive-strand RNA viruses and retroviruses but not in DNA viruses. African swine fever virus (ASFV) is an exception because it encodes a polyprotein, named pp220, to produce several major components of the virus particle, proteins p150, p37, p34, and p14. In this study, we analyzed the assembly pathway of ASFV and the contribution of the polyprotein products to the virus structure. Electron microscopic studies revealed that virions assemble from membranous structures present in the viral factories. Viral membranes became polyhedral immature virions after capsid formation on their convex surface. Beneath the lipid envelope, two distinct domains appeared to assemble consecutively: first a thick protein layer that we refer to as core shell and then an electron-dense nucleoid, which was identified as the DNA-containing domain. Immunofluorescence studies showed that polyprotein pp220 is localized in the viral factories. At the electron microscopic level, antibodies to pp220 labeled all identifiable forms of the virus from the precursor viral membranes onward, thus indicating an early role of the polyprotein pp220 in ASFV assembly. The subviral localization of the polyprotein products, examined on purified virions, was found to be the core shell. In addition, quantitative studies showed that the polyprotein products are present in equimolar amounts in the virus particle and account for about one-fourth of its total protein content. Taken together, these results suggest that polyprotein pp220 may function as an internal protein scaffold which would mediate the interaction between the nucleoid and the outer layers similarly to the matrix proteins of other viruses.     

Polyprotein processing in African swine fever virus: a novel gene expression strategy for a DNA virus.

This report shows that African swine fever virus (ASFV)--a large DNA-containing virus--synthesizes a polyprotein to produce several of its structural proteins. By immunoprecipitation analysis, we have found that ASFV polyprotein is a 220 kDa myristoylated polypeptide (pp220) which, after proteolytic processing, gives rise to four major structural proteins: p150, p37, p34 and p14. Processing of the ASFV polyprotein takes place at the consensus sequence Gly-Gly-X and occurs through an ordered cascade of proteolytic cleavages. So far, polyprotein processing as a mechanism of gene expression had been found only in positive-strand RNA viruses and retroviruses. According to the results presented here, ASFV is the first example of a DNA virus that synthesizes a polyprotein as a strategy of gene expression.     

African swine fever virus protease, a new viral member of the SUMO-1-specific protease family

African swine fever virus (ASFV) is a complex DNA virus that employs polyprotein processing at Gly-Gly-Xaa sites as a strategy to produce several major core components of the viral particle. The virus gene S273R encodes a 31-kDa protein that contains a "core domain" with the conserved catalytic residues characteristic of SUMO-1-specific proteases and the adenovirus protease. Using a COS cell expression system, it was found that protein pS273R is capable of cleaving the viral polyproteins pp62 and pp220 in a specific way giving rise to the same intermediates and mature products as those produced in ASFV-infected cells. Furthermore, protein pS273R, like adenovirus protease and SUMO-1-specific enzymes, is a cysteine protease, because its activity is abolished by mutation of the predicted catalytic histidine and cysteine residues and is inhibited by sulfhydryl-blocking reagents. Protein pS273R is expressed late after infection and is localized in the cytoplasmic viral factories, where it is found associated with virus precursors and mature virions. In the virions, the protein is present in the core shell, a domain where the products of the viral polyproteins are also located. The identification of the ASFV protease will allow a better understanding of the role of polyprotein processing in virus assembly and may contribute to our knowledge of the emerging family of SUMO-1-specific proteases.     

Proteolytic processing in African swine fever virus: evidence for a new structural polyprotein, pp62.

We have identified an open reading frame (ORF), CP530R, within the EcoRI C' fragment of the African swine fever virus (ASFV) genome that encodes a polyprotein of 62 kDa (pp62). Antisera raised against different regions of ORF CP530R recognized a polypeptide of 62 kDa in ASFV-infected cells during the late phase of virus replication, after the onset of viral DNA synthesis. Pulse-chase experiments showed that polyprotein pp62 is posttranslationally processed to give rise to two proteins of 35 kDa (p35) and 15 kDa (p15). This proteolytic processing was found to take place at the consensus sequence Gly-Gly-X through an ordered cascade of proteolytic cleavages like that which also occurs with ASFV polyprotein pp220 (C. Simón-Mateo, G. Andrés, and E. Viñuela, EMBO J. 12:2977-2987, 1993). Immunofluorescence studies showed that polyprotein pp62 is localized in the viral factories. In addition, immunoprecipitation analysis of purified virus particles showed that mature products p35 and p15 are major structural proteins. According to these results, polyprotein processing represents an essential strategy for the maturation of ASFV structural proteins.     

Assembly and processing of avian retroviral gag polyproteins containing linked protease dimers.

Assembly and maturation of retroviral particles requires the aggregation and controlled proteolytic cleavage of polyprotein core precursors by a precursor-encoded protease (PR). Active, mature retroviral PR is a dimer, and the accumulation of precursors at sites of assembly may facilitate subunit interaction and subsequent activation of this enzyme. In addition, it has been suggested that cellular cytoplasmic components act as inhibitors of PR activity, so that processing is delayed until the nascent virions leave this compartment and separate from the surface of host cells. To investigate the mechanisms that control PR activity during virus assembly, we studied the in vivo processing of retroviral gag precursors that contain tandemly linked PR subunits in which dimerization is concentration independent. Sequences encoding four different linked protease dimers were independently joined to the end of the Rous sarcoma virus (RSV) gag gene in a simian virus 40-based plasmid vector which expresses a myristoylated gag precursor upon transfection of COS-1 cells. Three of these plasmids produced gag precursors that were incorporated into viruslike particles and proteolytically cleaved by the dimers to mature core proteins that were indistinguishable from the processed products of wild-type gag. The amount of viral gag protein that was assembled and packaged in these transfections was inversely related to the relative proteolytic activities of the linked PR dimers. The fourth gag precursor, which contained the most active linked PR dimer, underwent rapid intracellular processing and did not form viruslike particles. In the absence of the plasma membrane targeting signal, processing of all four linked PR dimer-containing gag precursors was completed entirely within the cell. From these results, we conclude that the delay in polyprotein core precursor processing that occurs during normal virion assembly does not depend on a cytoplasmic inhibitor of PR activity. We suggest that dimer formation is not only necessary but may be sufficient for the initiation of PR-directed maturation of gag and gag-pol precursors.     

The African Swine Fever Virus Virion Membrane Protein pE248R Is Required for Virus Infectivity and an Early Postentry Event

The African swine fever virus (ASFV) protein pE248R, encoded by the gene E248R, is a late structural component of the virus particle. The protein contains intramolecular disulfide bonds and has been previously identified as a substrate of the ASFV-encoded redox system. Its amino acid sequence contains a putative myristoylation site and a hydrophobic transmembrane region near its carboxy terminus. We show here that the protein pE248R is myristoylated during infection and associates with the membrane fraction in infected cells, behaving as an integral membrane protein. Furthermore, the protein localizes at the inner envelope of the virus particles in the cytoplasmic factories. The function of the protein pE248R in ASFV replication was investigated by using a recombinant virus that inducibly expresses the gene E248R. Under repressive conditions, the ASFV polyproteins pp220 and pp62 are normally processed and virus particles with morphology indistinguishable from that of those produced in a wild-type infection or under permissive conditions are generated. Moreover, the mutant virus particles can exit the cell as does the parental virus. However, the infectivity of the pE248R-deficient virions was reduced at least 100-fold. An investigation of the defect of the mutant virus indicated that neither virus binding nor internalization was affected by the absence of the protein pE248R, but a cytopathic effect was not induced and early and late gene expression was impaired, indicating that the protein is required for some early postentry event.African swine fever virus (ASFV) is a large enveloped deoxyvirus that causes a severe hemorrhagic disease in domestic pigs (38). The ASFV genome is a double-stranded DNA molecule of 170 to 190 kbp that encodes more than 150 polypeptides (47). The icosahedral virus particle contains more than 50 polypeptides and is composed of several concentric domains, including an internal DNA-containing nucleoid surrounded by a protein layer designated the core shell, an inner envelope, and an outer icosahedral capsid (8, 10, 20). An additional membrane acquired by budding through the plasma membrane envelops the extracellular virion (14).The complex process of virus assembly occurs at specialized cytoplasmic sites, designated viral factories, and is initiated by the recruitment and modification of endoplasmic reticulum (ER) cisternae, which collapse to form the virus inner envelope, where the viral membrane proteins p54 and p17 are localized (8, 16, 21, 32, 37). This model, however, has been recently questioned, and based on data obtained using samples prepared by high-pressure freezing, it has been suggested that the inner envelope of ASFV consists of a single lipid bilayer (28). The icosahedral capsid layer, formed by protein p72, is then progressively assembled on one side of this envelope, while on the other side, the core shell domain, mainly constituted by the processing products of the polyproteins pp220 and pp62, is simultaneously constructed (6, 7, 20, 26). Finally, the viral DNA and nucleoproteins are packaged and condensed to form the nucleoid (15).The functions of several virus proteins in the formation of the different domains of the virus particle have been investigated in recent years. Thus, the structural proteins p72 and pB438L and the nonstructural pB602L protein, described as a chaperone of p72 (22), have been shown to be required for the construction of the icosahedral capsid (24, 25, 26), while the polyprotein pp220 is essential for the formation of the inner core, constituted by the nucleoid and core shell domains (7). It has also been demonstrated that the processing of the polyproteins pp220 and pp62 by the virus-encoded protease is necessary for the assembly of a proper core (5). In addition, it is known that the transmembrane protein p54 is critical for the recruitment of envelope precursors to assembly sites (35), although the mechanisms underlying the conversion of ER cisternae into functional viral envelopes are mostly unknown. Studies of other transmembrane proteins detected as structural components of the virus particle could shed light on this matter. Some of the virion membrane proteins could also play a role in virus entry, as has been described for the proteins p12, identified as a viral attachment protein (11, 19), and p54, also involved in binding of virus to target cells (27).The ASFV protein pE248R is a late structural component of the virus particle (33) that belongs to a class of myristoylated membrane proteins related to vaccinia virus L1 (30), one of the substrates of the pathway for the formation of disulfide bonds encoded by this virus (41). The protein pE248R also contains intramolecular disulfide bridges and has been recently identified as a possible final substrate of the ASFV-encoded redox system (33). In the present study, we investigated the membrane association, the localization in the virion, and the role of the protein pE248R in ASFV replication. Our results indicate that pE248R is a myristoylated integral membrane protein localized at the inner envelope of the virus particle. By using a conditional lethal ASFV mutant, vE248Ri, with an inducible copy of the gene E248R, we showed that the protein pE248R is required for virus infectivity and an early postentry event but not virus assembly.     

Plasma membrane targeting of chimeric intracisternal A-type particle polyproteins leads to particle release and specific activation of the viral proteinase.

Retrovirus morphogenesis involves assembly of structural Gag polyproteins with subsequent budding from the plasma membrane, followed by proteolytic cleavage by the viral proteinase (PR) and extracellular maturation to the infectious virion. Intracisternal A-type particles (IAPs) are defective retroviruses that assemble and bud at the membranes of the endoplasmic reticulum (ER), where they remain as immature particles consisting exclusively of uncleaved polyproteins. To analyze requirements for intracellular polyprotein transport and PR activation, we constructed deletion and substitution mutations in the IAP gag gene, including the putative ER-targeting signal. Mutant polyproteins were transported to various intracellular locations, including the nucleus, the cytoplasm, the ER, and the plasma membrane. Interestingly, assembly of capsid-like particle structures occurred at almost all sites. However, only those polyproteins transported to the plasma membrane were efficiently and specifically cleaved by viral PR, with cleavage occurring predominantly within the virus particle. Thus, at least in the experimental system presented here, retroviral particle assembly can occur at almost any location within the cell, while polyprotein processing and, consequently, virion maturation are confined to a specific cellular site. These results suggest that a factor restricted to the plasma membrane is required to trigger PR activation and maturation of infectious retroviruses.     

The African swine fever virus nonstructural protein pB602L is required for formation of the icosahedral capsid of the virus particle

African swine fever virus (ASFV) protein pB602L has been described as a molecular chaperone for the correct folding of the major capsid protein p72. We have studied the function of protein pB602L during the viral assembly process by using a recombinant ASFV, vB602Li, which inducibly expresses the gene coding for this protein. We show that protein pB602L is a late nonstructural protein, which, in contrast with protein p72, is excluded from the viral factory. Repression of protein pB602L synthesis inhibits the proteolytic processing of the two viral polyproteins pp220 and pp62 and leads to a decrease in the levels of protein p72 and a delocalization of the capsid protein pE120R. As shown by electron microscopy analysis of cells infected with the recombinant virus vB602Li, the viral assembly process is severely altered in the absence of protein pB602L, with the generation of aberrant "zipper-like" structures instead of icosahedral virus particles. These "zipper-like" structures are similar to those found in cells infected under restrictive conditions with the recombinant virus vA72 inducibly expressing protein p72. Immunoelectron microscopy studies show that the abnormal forms generated in the absence of protein pB602L contain the inner envelope protein p17 and the two polyproteins but lack the capsid proteins p72 and pE120R. These findings indicate that protein pB602L is essential for the assembly of the icosahedral capsid of the virus particle.     

Mutational analysis of tobacco etch virus polyprotein processing: cis and trans proteolytic activities of polyproteins containing the 49-kilodalton proteinase.

The genome of tobacco etch virus contains a single open reading frame with the potential to encode a 346-kilodalton (kDa) polyprotein. The large polyprotein is cleaved at several positions by a tobacco etch virus genome-encoded, 49-kDa proteinase. The locations of the 49-kDa proteinase-mediated cleavage sites flanking the 71-kDa cytoplasmic pinwheel inclusion protein, 6-kDa protein, 49-kDa proteinase, and 58-kDa putative polymerase have been determined by using cell-free expression, proteolytic processing, and site-directed mutagenesis systems. Each of these sites is characterized by the conserved sequence motif Glu-Xaa-Xaa-Tyr-Xaa-Gln-Ser or Gly (in which cleavage occurs after the Gln residue). The amino acid residue (Gln) predicted to occupy the -1 position relative to the scissile bond has been substituted, by mutagenesis of cloned cDNA, at each of four cleavage sites. The altered sites were not cleaved by the 49-kDa proteinase. A series of synthetic polyproteins that contained the 49-kDa proteinase linked to adjoining proteins via defective cleavage sites were expressed, and their proteolytic activities were analyzed. As part of a polyprotein, the proteinase was found to exhibit cis (intramolecular) and trans (intermolecular) activity.     

African swine fever virus structural protein p54 is essential for the recruitment of envelope precursors to assembly sites

The assembly of African swine fever virus (ASFV) at the cytoplasmic virus factories commences with the formation of precursor membranous structures, which are thought to be collapsed cisternal domains recruited from the surrounding endoplasmic reticulum (ER). This report analyzes the role in virus morphogenesis of the structural protein p54, a 25-kDa polypeptide encoded by the E183L gene that contains a putative transmembrane domain and localizes at the ER-derived envelope precursors. We show that protein p54 behaves in vitro and in infected cells as a type I membrane-anchored protein that forms disulfide-linked homodimers through its unique luminal cysteine. Moreover, p54 is targeted to the ER membranes when it is transiently expressed in transfected cells. Using a lethal conditional recombinant, vE183Li, we also demonstrate that the repression of p54 synthesis arrests virus morphogenesis at a very early stage, even prior to the formation of the precursor membranes. Under restrictive conditions, the virus factories appeared as discrete electron-lucent areas essentially free of viral structures. In contrast, outside the assembly sites, large amounts of aberrant zipper-like structures formed by the unprocessed core polyproteins pp220 and pp62 were produced in close association to ER cisternae. Altogether, these results indicate that the transmembrane structural protein p54 is critical for the recruitment and transformation of the ER membranes into the precursors of the viral envelope.     

Characterization of poliovirus 2A proteinase by mutational analysis: residues required for autocatalytic activity are essential for induction of cleavage of eukaryotic initiation factor 4F polypeptide p220.

The poliovirus proteinase 2A is autocatalytically released from the poliovirus polyprotein by cotranslational cleavage at its own amino terminus, resulting in separation of structural and nonstructural protein precursors. Cleavage is a prerequisite for further processing of the structural protein precursor and consequently for poliovirus encapsidation. A second function of 2Apro is in the rapid shutoff of host cell protein synthesis that occurs upon infection with poliovirus. This is associated with proteolytic cleavage of the p220 component of eukaryotic initiation factor eIF-4F, which is induced but not directly catalyzed by 2Apro. We introduced single-amino-acid substitutions in the 2Apro-coding region of larger poliovirus precursors that were subsequently translated in vitro and thus demonstrated that His-20, Asp-38, and Cys-109 (which constitute the putative catalytic triad) are essential for, and that His-117 is an important determinant of, the autocatalytic activity of 2Apro. This is consistent with the proposal that 2Apro is structurally related to a subclass of trypsinlike serine proteinases. Moreover, 2Apro containing a Cys109Ser substitution retained a small but significant autocatalytic activity. Cleavage of p220 was not induced by those mutants that had reduced proteolytic activity, indicating that the cellular factor that cleaves p220 is probably activated by 2Apro-catalyzed proteolytic cleavage.     

African Swine Fever Virus Is Enveloped by a Two-Membraned Collapsed Cisterna Derived from the Endoplasmic Reticulum

During the cytoplasmic maturation of African swine fever virus (ASFV) within the viral factories, the DNA-containing core becomes wrapped by two shells, an inner lipid envelope and an outer icosahedral capsid. We have previously shown that the inner envelope is derived from precursor membrane-like structures on which the capsid layer is progressively assembled. In the present work, we analyzed the origin of these viral membranes and the mechanism of envelopment of ASFV. Electron microscopy studies on permeabilized infected cells revealed the presence of two tightly apposed membranes within the precursor membranous structures as well as polyhedral assembling particles. Both membranes could be detached after digestion of intracellular virions with proteinase K. Importantly, membrane loop structures were observed at the ends of open intermediates, which suggests that the inner envelope is derived from a membrane cisterna. Ultraestructural and immunocytochemical analyses showed a close association and even direct continuities between the endoplasmic reticulum (ER) and assembling virus particles at the bordering areas of the viral factories. Such interactions become evident with an ASFV recombinant that inducibly expresses the major capsid protein p72. In the absence of the inducer, viral morphogenesis was arrested at a stage at which partially and fully collapsed ER cisternae enwrapped the core material. Together, these results indicate that ASFV, like the poxviruses, becomes engulfed by a two-membraned collapsed cisterna derived from the ER.     

Poliovirus capsid proteins derived from P1 precursors with glutamine-valine cleavage sites have defects in assembly and RNA encapsidation.

Assembly of poliovirus virions requires proteolytic cleavage of the P1 capsid precursor polyprotein between two separate glutamine-glycine (QG) amino acid pairs by the viral protease 3CD. In this study, we have investigated the effects on P1 polyprotein processing and subsequent assembly of processed capsid proteins caused by substitution of the glycine residue at the individual QG cleavage sites with valine (QG-->QV). P1 cDNAs encoding the valine substitutions were created by site-directed mutagenesis and were recombined into wild-type vaccinia virus to generate recombinant vaccinia viruses which expressed the mutant P1 precursors. The recombinant vaccinia virus-expressed mutant P1 polyproteins were analyzed for proteolytic processing defects in cells coinfected with a recombinant vaccinia virus (VVP3) that expresses the poliovirus 3CD protease and for processing and assembly defects by using a trans complementation system in which P1-expressing recombinant vaccinia viruses provide capsid precursor to a defective poliovirus genome that does not express functional capsid proteins (D. C. Ansardi, D. C. Porter, and C. D. Morrow, J. Virol. 67:3684-3690, 1993). The QV-substituted precursors were proteolytically processed at the altered sites both in cells coinfected with VVP3 and in cells coinfected with defective poliovirus, although the kinetics of cleavage at the altered sites were slower than those of cleavage at the wild-type QG site in the precursor. Completely processed capsid proteins VP0, VP3, and VP1 derived from the mutant precursor containing a valine at the amino terminus of VP3 (VP3-G001V) were unstable and failed to assemble stable subviral structures in cells coinfected with defective poliovirus. In contrast, capsid proteins derived from the P1 precursor with a valine substitution at the amino terminus of VP1 (VP1-G001V) assembled empty capsid particles but were deficient in assembling RNA-containing virions. The assembly characteristics of the VP1-G001V mutant were compared with those of a previously described VP3-VP1 cleavage site mutant (K. Kirkegaard and B. Nelsen, J. Virol. 64:185-194, 1990) which contained a deletion of the first four amino-terminal residues of VP1 (VP1-delta 1-4) and which was reconstructed for our studies into the recombinant vaccinia virus system. Complete proteolytic processing of the VP1-delta 1-4 precursor also occurred more slowly than complete cleavage of the wild-type precursor, and formation of virions was delayed; however, capsid proteins derived from the VP1-G001V mutant assembled RNA-containing virions less efficiently than those derived from the VP1-delta 1-4 precursor.(ABSTRACT TRUNCATED AT 400 WORDS)     

Proteinase 3C-mediated processing of VP1-2A of two hepatitis A virus strains: in vivo evidence for cleavage at amino acid position 273/274 of VP1.

Two prominent features distinguish hepatitis A virus (HAV) from other members of the picornavirus family. A C-terminally prolonged precursor of the structural protein VP1 is incorporated into assembly intermediates (e.g., the provirion), and a single proteinase is contained within the HAV polyprotein. Using an in vivo expression system, we show that proteolytic liberation of VP1 from its precursors P1-2A and VP1-2A is catalyzed by the virus-encoded proteinase 3Cpro. Among the proposed cleavage sites within VP1-2A, the Glu/Ser pair found at VP1 amino acid position 273/274 of most HAV strains is efficiently processed, whereas proteolysis of the Val/Ser site of the attenuated HM175 strain is protracted. Two mutations within VP1-2A (Lys[297]Arg and Ser[330]Asn) had no effect on 3Cpro-mediated cleavage at this site. Additional sites in this region of VP1-2A can also be utilized as substrates by the proteinase, yet less efficiently, and might give rise to smaller and larger VP1 polypeptides also detected in HAV-infected cells.     

Proteolytic activity of novel human immunodeficiency virus type 1 proteinase proteins from a precursor with a blocking mutation at the N terminus of the PR domain.

The mature human immunodeficiency virus type 1 proteinase (PR; 11 kDa) can cleave all interdomain junctions in the Gag and Gag-Pol polyprotein precursors. To determine the activity of the enzyme in its precursor form, we blocked release of mature PR from a truncated Gag-Pol polyprotein by introducing mutations into the N-terminal Phe-Pro cleavage site of the PR domain. The mutant precursor autoprocessed efficiently upon expression in Escherichia coli. No detectable mature PR was released; however, several PR-related products ranging in size from approximately 14 to 18 kDa accumulated. Products of the same size were generated when mutant precursors were digested with wild-type PR. Thus, PR can utilize cleavage sites in the region upstream of the PR domain, resulting in the formation of extended PR species. On the basis of active-site titration, the PR species generated from mutated precursor exhibited wild-type activity on peptide substrates. However, the proteolytic activity of these extended enzymes on polyprotein substrates provided exogenously was low when equimolar amounts of extended and wild-type PR proteins were compared. Mammalian cells expressing the mutated precursor produced predominantly precursor and considerably reduced amounts of mature products. Released particles consisted mostly of uncleaved or partially cleaved polyproteins. Our results suggest that precursor forms of PR can autoprocess but are less efficient in processing of the Gag precursor for formation of mature virus particles.