Proteolytic processing of avian sarcoma and leukosis viruses pol-endo recombinant proteins reveals another pol gene domain

A C-terminal "Tail" Region in the Rous Sarcoma Virus Integrase Provides High Plasticity of Functional Integrase Oligomerization during Intasome Assembly

The retrovirus integrase (IN) inserts the viral cDNA into the host DNA genome. Atomic structures of five different retrovirus INs complexed with their respective viral DNA or branched viral/target DNA substrates have indicated these intasomes are composed of IN subunits ranging from tetramers, to octamers, or to hexadecamers. IN precursors are monomers, dimers, or tetramers in solution. But how intasome assembly is controlled remains unclear. Therefore, we sought to unravel the functional mechanisms in different intasomes. We produced kinetically stabilized Rous sarcoma virus (RSV) intasomes with human immunodeficiency virus type 1 strand transfer inhibitors that interact simultaneously with IN and viral DNA within intasomes. We examined the ability of RSV IN dimers to assemble two viral DNA molecules into intasomes containing IN tetramers in contrast to one possessing IN octamers. We observed that the last 18 residues of the C terminus ("tail" region) of IN (residues 1-286) determined whether an IN tetramer or octamer assembled with viral DNA. A series of truncations of the tail region indicated that these 18 residues are critical for the assembly of an intasome containing IN octamers but not for an intasome containing IN tetramers. The C-terminally truncated IN (residues 1-269) produced an intasome that contained tetramers but failed to produce an intasome with octamers. Both intasomes have similar catalytic activities. The results suggest a high degree of plasticity for functional multimerization and reveal a critical role of the C-terminal tail region of IN in higher order oligomerization of intasomes, potentially informing future strategies to prevent retroviral integration.

Structural biology of retroviral DNA integration

Three-dimensional macromolecular structures shed critical light on biological mechanism and facilitate development of small molecule inhibitors. Clinical success of raltegravir, a potent inhibitor of HIV-1 integrase, demonstrated the utility of this viral DNA recombinase as an antiviral target. A variety of partial integrase structures reported in the past 16 years have been instrumental and very informative to the field. Nonetheless, because integrase protein fragments are unable to functionally engage the viral DNA substrate critical for strand transfer inhibitor binding, the early structures did little to materially impact drug development efforts. However, recent results based on prototype foamy virus integrase have fully reversed this trend, as a number of X-ray crystal structures of active integrase-DNA complexes revealed key mechanistic details and moreover established the foundation of HIV-1 integrase strand transfer inhibitor action. In this review we discuss the landmarks in the progress of integrase structural biology during the past 17 years.

Retroviral reverse transcriptases (other than those of HIV-1 and murine leukemia virus): a comparison of their molecular and biochemical properties

This chapter reviews most of the biochemical data on reverse transcriptases (RTs) of retroviruses, other than those of HIV-1 and murine leukemia virus (MLV) that are covered in detail in other reviews of this special edition devoted to reverse transcriptases. The various RTs mentioned are grouped according to their retroviral origins and include the RTs of the alpharetroviruses, lentiviruses (both primate, other than HIV-1, and non-primate lentiviruses), betaretroviruses, deltaretroviruses and spumaretroviruses. For each RT group, the processing, molecular organization as well as the enzymatic activities and biochemical properties are described. Several RTs function as dimers, primarily as heterodimers, while the others are active as monomeric proteins. The comparisons between the diverse properties of the various RTs show the common traits that characterize the RTs from all retroviral subfamilies. In addition, the unique features of the specific RTs groups are also discussed.

Integrase-mediated nonviral gene transfection with enhanced integration efficiency

Retroviruses efficiently integrate their genome into the host chromosome. Two elements of the retrovirus genome are needed for the integration: long terminal repeats (LTRs) and integrase protein. We attempted to incorporate the retrovirus integration machinery in lipid vesicle-mediated gene transfection with the aim of achieving efficient stable transfection in a nonviral gene transfection system. A DNA fragment, in which a neomycin-resistant gene was flanked between partial LTR sequences derived from the Rous sarcoma virus (RSV), was constructed. This DNA fragment was transfected together with purified recombinant RSV integrase or integrase expression vectors by means of lipid vesicle-mediated gene transfection. The integrase-mediated transfection enhanced the stable transfection efficiency. The length and the end structure of the LTR sequences were important in achieving high efficiency. Under optimal conditions, the stable transfection efficiency showed a 16-fold improvement over that without integrase.

Subcellular localization and integration activities of rous sarcoma virus reverse transcriptase

Reverse transcriptases (RTs) alphabeta and beta from avian Rous sarcoma virus (RSV) harbor an integrase domain which is absent in nonavian retroviral RTs. RSV integrase contains a nuclear localization signal which enables the enzyme to enter the nucleus of the cell in order to perform integration of the proviral DNA into the host genome. In the present study we analyzed the subcellular localization of RSV RT, since previous results indicated that RSV finishes synthesis of the proviral DNA in the nucleus. Our results demonstrate that the heterodimeric RSV RT alphabeta and the beta subunit, when expressed independently, can be detected in the nucleus, whereas the separate alpha subunit lacking the integrase domain is prevalent in the cytoplasm. These data suggest an involvement of RSV RT in the transport of the preintegration complex into the nucleus. In addition, to analyze whether the integrase domain, located at the carboxyl terminus of beta, exhibits integration activities, we investigated the nicking and joining activities of heterodimeric RSV RT alphabeta with an oligodeoxynucleotide-based assay system and with a donor substrate containing the supF gene flanked by the viral long terminal repeats. Our data show that RSV RT alphabeta is able to perform the integration reaction in vitro; however, it does so with an estimated 30-fold lower efficiency than the free RSV integrase, indicating that RSV RT is not involved in integration in vivo. Integration with RSV RT alphabeta could be stimulated in the presence of human immunodeficiency virus type 1 nucleocapsid protein or HMG-I(Y).

Requirements for minus-strand transfer catalyzed by Rous sarcoma virus reverse transcriptase

We have examined the specific minus-strand transfer reactions that occur after the synthesis of minus strong-stop DNA and nonspecific strand switching on homopolymeric poly(rA) templates with different types of Rous sarcoma virus (RSV) reverse transcriptases. Three different types of reverse transcriptases can be isolated from virions of RSV: heterodimeric alphabeta and homodimeric alpha and beta. The mechanism of minus-strand transfer was examined using a model primer-template substrate corresponding to the 5'- and 3'-terminal RNA regions of the RSV genome. The results reveal that the RNase H activity of RSV reverse transcriptases is required for minus-strand transfer. Less than 2% of strand transfer of the extended product is detectable with RNase H-deficient enzymes. We could show that the alpha homodimer lacking the integrase domain can perform strand transfer almost as efficiently as the alphabeta and alphaPol heterodimers. In contrast, the activities of beta and Pol for minus-strand transfer are reduced. Furthermore, a two- to fivefold increase in minus-strand transfer activities was observed in the presence of human immunodeficiency virus type 1 nucleocapsid protein.

Asymmetric subunit organization of heterodimeric Rous sarcoma virus reverse transcriptase alphabeta: localization of the polymerase and RNase H active sites in the alpha subunit

The genes encoding the alpha (63-kDa) and beta (95-kDa) subunits of Rous sarcoma virus (RSV) reverse transcriptase (RT) or the entire Pol polypeptide (99 kDa) were mutated in the conserved aspartic acid residue Asp 181 of the polymerase active site (YMDD) or in the conserved Asp 505 residue of the RNase H active site. We have analyzed heterodimeric recombinant RSV alphabeta and alphaPol RTs within which one subunit was selectively mutated. When alphabeta heterodimers contained the Asp 181-->Asn mutation in their beta subunits, about 42% of the wild-type polymerase activity was detected, whereas when the heterodimers contained the same mutation in their alpha subunits, only 7.5% of the wild-type polymerase activity was detected. Similar results were obtained when the conserved Asp 505 residue of the RNase H active site was mutated to Asn. RNase H activity was clearly detectable in alphabeta heterodimers mutated in the beta subunit but was lost when the mutation was present in the alpha subunit. In summary, our data imply that the polymerase and RNase H active sites are located in the alpha subunit of the heterodimeric RSV RT alphabeta.

Effect of serine and tyrosine phosphorylation on retroviral proteinase substrates

Vimentin, a cellular substrate of HIV type 1 (HIV-1) proteinase, contains a protein kinase C (PKC) phosphorylation site at one of its cleavage sites. Peptides representing this site were synthesized in P2 Ser-phosphorylated and nonphosphorylated forms. While the nonphosphorylated peptide was a fairly good substrate of the enzyme, phosphorylation prevented hydrolysis. Phosphorylation of human recombinant vimentin by PKC prevented its processing within the head domain, where the phosphorylation occurred. Oligopeptides representing naturally occurring cleavage sites at the C-terminus of the Rous sarcoma virus integrase were assayed as substrates of the avian proteinase. Unlike the nonphosphorylated peptides, a Ser-phosphorylated peptide was not hydrolyzed by the enzyme at the Ser-Pro bond, suggesting the role of previously established phosphorylation in processing at this site. Ser-phosphorylated and Tyr-phosphorylated forms of model substrates were also tested as substrates of the HIV-1 and the avian retroviral proteinases. In contrast to the moderate effect of P4 Ser phosphorylation, phosphorylation of P1 Tyr prevented substrate hydrolysis by HIV-1 proteinase. Substrate phosphorylation had substantially smaller effects on the hydrolysis by the avian retroviral proteinase. As the active retroviral proteinase as well as various protein kinases are incorporated into mature virions, substrate phosphorylation resulting in attenuation or prevention of proteolytic processing may have important consequences in the regulation of the retroviral life cycle as well as in virus-host cell interactions.

Soluble Rous sarcoma virus reverse transcriptases alpha, alphabeta, and beta purified from insect cells are processive DNA polymerases that lack an RNase H 3' --> 5' directed processing activity

Reverse transcriptase (RT) isolated from Rous sarcoma virus (RSV) consists of heterodimeric RTalphabeta, RTalpha, and RTbeta. The alpha subunit (63 kDa) contains an N-terminal polymerase and a C-terminal RNase H domain. The N terminus of beta (95 kDa) corresponds to alpha with the integrase domain attached to the C terminus (32 kDa). We have constructed baculoviruses expressing the genes for alpha or beta or the entire pol (99 kDa). Infection of insect cells with recombinant virus yielded highly active and soluble RSV RT enzymes that could be purified to >90% homogeneity. HPLC gel filtration showed that alpha is a dimeric enzyme that can be partially monomerized upon the addition of 45% Me(2)SO. DNA synthesis on DNA-DNA and DNA-RNA primer-templates in the presence of competitor substrates revealed that alphabeta and beta as well as alpha are processive polymerases. However, the affinity of beta and alphabeta for primer-template substrates appears to be higher than that of alpha. All RSV enzymes investigated have the potential to displace RNA-RNA duplexes more efficiently than human immunodeficiency virus type 1 RT. Unlike human immunodeficiency virus type 1 RT, RSV RTs can catalyze an initial RNase H endonucleolytic cleavage of the RNA template but not a 3' --> 5' directed processing activity.

Independent isolates of the emerging subgroup J avian leukosis virus derive from a common ancestor

A new subgroup of avian leukosis virus (ALV) that includes a unique env gene, designated J, was identified recently in England. Sequence analysis of prototype English isolate HPRS-103 revealed several other unique genetic characteristics of this strain and provided information that it arose by recombination between exogenous and endogenous virus sequences. In the past several years, ALV J type viruses (ALV-J) have been isolated from broiler breeder flocks in the United States. We were interested in determining the relationship between the U.S. and English isolates of ALV-J. Based on sequence data from two independently derived U.S. field isolates, we conclude that the U.S. and English isolates of ALV-J derive from a common ancestor and are not the result of independent recombination events.

Programming the Rous sarcoma virus protease to cleave new substrate sequences

The Rous sarcoma virus protease displays a high degree of specificity and catalyzes the cleavage of only a limited number of amino acid sequences. This specificity is governed by interactions between side chains of eight substrate amino acids and eight corresponding subsite pockets within the homodimeric enzyme. We have examined these complex interactions in order to learn how to introduce changes into the retroviral protease (PR) that direct it to cleave substrates. Mutant enzymes with altered substrate specificity and wild-type or greater catalytic rates have been constructed previously by substituting single key amino acids in each of the eight enzyme subsites with those residues found in structurally related positions of human immunodeficiency virus (HIV)-1 PR. These individual amino acid substitutions have now been combined into one enzyme, resulting in a highly active mutant Rous sarcoma virus (RSV) protease that displays many characteristics associated with the HIV-1 enzyme. The hybrid protease is capable of catalyzing the cleavage of a set of HIV-1 viral polyprotein substrates that are not recognized by the wild-type RSV enzyme. Additionally, the modified PR is inhibited completely by the HIV-1 PR-specific inhibitor KNI-272 at concentrations where wild-type RSV PR is unaffected. These results indicate that the major determinants that dictate RSV and HIV-1 PR substrate specificity have been identified. Since the viral protease is a homodimer, the rational design of enzymes with altered specificity also requires a thorough understanding of the importance of enzyme symmetry in substrate selection. We demonstrate here that the enzyme homodimer acts symmetrically in substrate selection with each enzyme subunit being capable of recognizing both halves of a peptide substrate equally.

Comparative studies on the substrate specificity of avian myeloblastosis virus proteinase and lentiviral proteinases

The retroviral proteinase (PR) seems to play crucial roles in the viral life cycle, therefore it is an attractive target for chemotherapy. Previously we studied the specificity of human immunodeficiency virus (HIV) type 1 and type 2 as well as equine infectious anemia virus PRs using oligopeptide substrates. Here a similar approach is used to characterize the specificity of avian myeloblastosis virus (AMV) PR and to compare it with those of the previously characterized lentiviral PRs. All peptides representing naturally occurring Gag and Gag-Pol cleavage sites were substrates of the AMV PR. Only half of these peptides were substrates of HIV-1 PR. The Km values for AMV PR were in a micromolar range previously found for the lentiviral PRs; however, the kcat values were in a 10 30-fold lower range. A series of peptides containing single amino acid substitutions in a sequence representing a naturally occurring HIV cleavage site was used to characterize the seven substrate binding subsites of the AMV PR. The largest differences were found at the P4 and P2 positions of the substrate. Detailed analysis of the results by molecular modeling and comparison with previously reported data revealed the common characteristics of the specificity of the retroviral PRs as well as its strong dependence on the sequence context of the substrate.

Human immunodeficiency virus, type 1 protease substrate specificity is limited by interactions between substrate amino acids bound in adjacent enzyme subsites

The specificity of the retroviral protease is determined by the ability of substrate amino acid side chains to bind into eight individual subsites within the enzyme. Although the subsites are able to act somewhat independently in selection of amino acid side chains that fit into each pocket, significant interactions exist between individual subsites that substantially limit the number of cleavable amino acid sequences. The substrate peptide binds within the enzyme in an extended anti-parallel beta sheet conformation with substrate amino acid side chains adjacent in the linear sequence extending in opposite directions in the enzyme-substrate complex. From this geometry, we have defined both cis and trans steric interactions, which have been characterized by a steady state kinetic analysis of human immunodeficiency virus, type-1 protease using a series of peptide substrates that are derivatives of the avian leukosis/sarcoma virus nucleocapsid-protease cleavage site. These peptides contain both single and double amino acid substitutions in seven positions of the minimum length substrate required by the retroviral protease for specific and efficient cleavage. Steady state kinetic data from the single amino acid substituted peptides were used to predict effects on protease-catalyzed cleavage of corresponding double substituted peptide substrates. The calculated Gibbs' free energy changes were compared with actual experimental values in order to determine how the fit of a substrate amino acid in one subsite influences the fit of amino acids in adjacent subsites. Analysis of these data shows that substrate specificity is limited by steric interactions between pairs of enzyme subsites. Moreover, certain enzyme subsites are relatively tolerant of substitutions in the substrate and exert little effect on adjacent subsites, whereas others are more restrictive and have marked influence on adjacent cis and trans subsites.

Monoclonal antibodies against Rous sarcoma virus integrase protein exert differential effects on integrase function in vitro

We have prepared and characterized several monoclonal antibodies (MAbs) against the Rous sarcoma virus integrase protein (IN) with the aim of employing these specific reagents as tools for biochemical and biophysical studies. The interaction of IN with the purified MAbs and their Fab fragment derivatives was demonstrated by Western blot (immunoblot), enzyme-linked immunosorbent assay, and size exclusion chromatography. A series of truncated IN proteins was used to determine regions in the protein important for recognition by the antibodies. The MAbs described here recognize epitopes that lie within the catalytic core region of IN (amino acids 50 to 207) and are likely to be conformational. A detailed functional analysis was carried out by investigating the effects of Fab fragments as well as of intact MAbs on the activities of IN in vitro. These studies revealed differential effects which fall into three categories. (i) One of the antibodies completely neutralized the processing as well as the joining activity and also reduced the DNA binding capacity as determined by a nitrocellulose filter binding assay. On the other hand, this MAb did not abolish the cleavage-ligation reaction on a disintegration substrate and the nonspecific cleavage of DNA by IN. The cleavage pattern generated by the IN-MAb complex on various DNA substrates closely resembled that produced by mutant IN proteins which show a deficiency in multimerization. Preincubation of IN with substrate protected the enzyme from inhibition by this antibody. (ii) Two other antibodies showed a general inhibition of all IN activities tested. (iii) In contrast, a fourth MAb stimulated the in vitro joining activity of IN. Size exclusion chromatography demonstrated that IN-Fab complexes from representatives of the three categories of MAbs exhibit different stoichiometric compositions that suggest possible explanations for their contrasting effects and may provide clues to the relationship between the structure and function of IN.

Ribosomal frameshifting at the Gag-Pol junction in avian leukemia sarcoma virus forms a novel cleavage site

The Gag and Gag-Pol precursors of avian sarcoma leukemia virus (ASLV) are translated from viral genomic-size mRNA at a molar ratio of about 20:1. Translation of Gag is terminated at the stop codon UAG located at the carboxyl-terminus of the viral protease (PR), whereas a ribosomal frameshift occurring at the carboxyl-terminus of Gag allows translation of the Gag-Pol precursor. To determine how PR is released from the Gag-Pol precursor, a single base (A or T) was inserted at the Gag-Pol junction in order to adjust the translation into a single reading frame. These mutations allow processing of the viral precursor when expressed in bacterial cells, but cause cessation of viral production after transfection of avian cells. The viral PR released from the large precursor is one amino acid longer than PR cleaved from the Gag polyprotein and is terminated by an Ile instead of a Leu residue.

HPRS-103 (exogenous avian leukosis virus, subgroup J) has an env gene related to those of endogenous elements EAV-0 and E51 and an E element found previously only in sarcoma viruses

The avian leukosis and sarcoma virus (ALSV) group comprises eight subgroups based on envelope properties. HPRS-103, an exogenous retrovirus recently isolated from meat-type chicken lines, is similar to the viruses of these subgroups in group antigen but differs from them in envelope properties and has been assigned to a new subgroup, J. HPRS-103 has a wide host range in birds, and unlike other nontransforming ALSVs which cause late-onset B-cell lymphomas, HPRS-103 causes late-onset myelocytomas. Analysis of the sequence of an infectious clone of the complete proviral genome indicates that HPRS-103 is a multiple recombinant of at least five ALSV sequences and one EAV (endogenous avian retroviral) sequence. The HPRS-103 env is most closely related to the env gene of the defective EAV-E51 but divergent from those of other ALSV subgroups. Probing of restriction digests of line 0 chicken genomic DNA has identified a novel group of endogenous sequences (EAV-HP) homologous to that of the HPRS-103 env gene but different from sequences homologous to EAV and E51. Unlike other replication-competent nontransforming ALSVs, HPRS-103 has an E element in its 3' noncoding region, as found in many transforming ALSVs. A deletion found in the HPRS-103 U3 EFII enhancer factor-binding site is also found in all replication-defective transforming ALSVs (including MC29, which causes rapid-onset myelocytomas).

Reverse transcriptase and protease activities of avian leukosis virus Gag-Pol fusion proteins expressed in insect cells

Protease (PR)-defective avian leukosis virus particles display 300-fold-reduced levels of reverse transcriptase (RT) activity relative to wild-type particles. This observation suggests that during virion assembly RT is activated by proteolytic maturation of the Gag-Pol polyprotein precursor. To study the relationship between proteolytic cleavage and RT activation, we subjected PR-defective virion cores to digestion with purified viral PR and analyzed the structure of the major polypeptides produced as well as RT activity. Under conditions in which Gag precursors were fully matured, the RT domain was only incompletely released from the Gag-Pol precursor, remaining tethered to the upstream Gag domains PR or NC-PR. In the same reaction, RT activity was stimulated only three-fold, or 100-fold less than expected for a fully active RT. The poor activation suggested that the NC or PR domains could repress RT activity. To test this idea, we constructed recombinant baculoviruses expressing 19 different fusion proteins with upstream Gag or downstream Pol sequences attached to RT. Each protein was partially purified and assayed for its inherent RT activity. The results are consistent with the idea that Gag sequences can inhibit RT activity but indicate that the size of the Pol domain as well as the status of the PR domain (wild-type or mutant) also can profoundly influence activity. Several of the constructed Gag-Pol fusion proteins contained a wild-type PR domain. Some of these underwent intracellular PR-mediated processing, while others did not. All proteins in which the PR domain was preceded by upstream Gag sequences showed specific proteolysis. By contrast, all proteins initiated with a methionine placed one residue upstream of the natural N terminus of PR failed to show specific proteolysis. Amino-terminal sequencing of one such protein yielded the correct amino acid sequence and showed that the initiating methionine was not removed. One interpretation of these findings is that activation of PR requires the generation of the precise N terminus of the mature PR.

trans-acting viral protease is necessary and sufficient for activation of avian leukosis virus reverse transcriptase

The structural and enzymatic components of retroviral cores are formed by proteolytic cleavage of precursor polypeptides, mediated by the viral protease (PR). We described previously the construction of PR-defective avian leukosis viruses. These mutant viruses are noninfectious, and their major internal components are the uncleaved gag and gag-pol polyproteins (Pr76gag and Pr180gag-pol). The reverse transcriptase (RT) activity associated with the PR-defective virions is approximately 500-fold reduced relative to that of wild-type virions, suggesting that specific cleavages activate RT activity. To gain a better understanding of the role that PR plays in the processing and activation of RT, we performed complementation experiments wherein wild-type or PR mutant gag precursors were separately coexpressed with frame-corrected wild-type or PR mutant gag-pol precursors. The results demonstrate that, as in other retrovirus systems, gag-pol precursors can be assembled into virions only when they are rescued by a gag precursor. If the gag precursor is wild type, then the rescued Pr180gag-pol is completely and properly matured, irrespective of whether its embedded PR domain is wild type or mutant. In both cases, the virions produced are fully and equally infectious. This indicates that an active-site mutation in the PR domain of the gag-pol precursor has no effect on avian leukosis virus infectivity when particles are assembled from wild-type gag precursors. In contrast, if the gag precursor has an active-site mutation in PR or is deleted for PR, then the virions are noninfectious and the gag and gag-pol precursors remain unprocessed, even if the embedded PR domain of Pr180gag-pol is wild type. Thus, in this system, virion-associated Pr180gag-pol displays no detectable cis- or trans-acting PR activity. As assayed with an exogenous template, virions with processed gag-pol polyprotein display high levels of RT activity while those with unprocessed Pr180gag-pol display greatly reduced RT activity. These results demonstrate that during virion assembly, the PR supplied by a gag precursor is both necessary and sufficient for trans-activation of RT through proteolytic maturation of copackaged gag-pol polyprotein.

Role of the avian retroviral protease in the activation of reverse transcriptase during virion assembly

The retroviruses of the avian sarcoma-leukosis virus group synthesize their viral protease (PR) in two precursor forms--as a carboxy-terminal domain of the Gag precursor and as an embedded domain within the Gag-Pol precursor. We have shown previously that the Gag-derived PR is fully capable of processing the Gag precursor in the absence of the embedded PR (R.P. Bennett, S. Rhee, R.C. Craven, E. Hunter, and J.W. Wills, J. Virol. 65:272-280, 1991). In this study, we examined the question of whether or not the PR domain of Gag-Pol has an essential role in the maturation of the Pol proteins. The Gag-Pol precursor was expressed in the absence of Gag by use of a simian virus 40-based vector in which the gag and pol reading frames were fused. The fusion protein accumulated to high levels in transfected cells without being released into the medium but could be rescued into particles by coexpression of the Gag protein from a second vector. The resulting particles contained mature Gag and Pol proteins and active reverse transcriptase (RT). Using this complementation system, the effects of PR defects in the Gag and/or Gag-Pol proteins on the activation of RT were examined. The results showed that the presence of a functional PR on the Gag precursor, but not on Gag-Pol, was required for full activation of RT. The embedded PR of Gag-Pol was unable to carry out any detectable processing of the Gag precursor and was able to activate RT to only a low level in the absence of a functional Gag PR domain. Finally, some point mutations in the Gag-Pol PR domain inhibited activation of RT in trans by a wild-type PR, suggesting that the correct conformation of the PR domain in Gag-Pol is prerequisite for activation of RT.

Retroviral integrase domains: DNA binding and the recognition of LTR sequences

Integration of retroviral DNA into the host chromosome requires a virus-encoded integrase (IN). IN recognizes, cuts and then joins specific viral DNA sequences (LTR ends) to essentially random sites in host DNA. We have used computer-assisted protein alignments and mutagenesis in an attempt to localize these functions within the avian retroviral IN protein. A comparison of the deduced amino acid sequences for 80 retroviral/retrotransposon IN proteins reveals strong conservation of an HHCC N-terminal 'Zn finger'-like domain, and a central D(35)E region which exhibits striking similarities with sequences deduced for bacterial IS elements. We demonstrate that the HHCC region is not required for DNA binding, but contributes to specific recognition of viral LTRs in the cutting and joining reactions. Deletions which extend into the D(35)E region destroy the ability of IN to bind DNA. Thus, we propose that the D(35)E region may specify a DNA-binding/cutting domain that is conserved throughout evolution in enzymes with similar functions.

Defining nucleic acid-binding properties of avian retrovirus integrase by deletion analysis

Integration of retroviral DNA into the host genome requires the activity of retrovirus-encoded integration protein IN. We expressed Rous sarcoma virus (RSV) IN, 286 amino acid residues in length, by using in vitro transcription, followed by in vitro translation in rabbit reticulocyte lysate. The nucleic acid-binding activity of in vitro-translated IN was assessed by using DNA-cellulose affinity chromatography and poly(U)-Sepharose affinity chromatography and by sedimentation analysis in the presence or absence of DNA. In vitro-translated RSV IN exhibited nucleic acid-binding activity similar to that of IN purified from avian myeloblastosis virus. To identify regions of IN which bind to nucleic acids, several deletions of RSV IN were generated. The NH2-terminal 26 amino acids, including the two His residues of a His-Cys box, were not necessary for IN nucleic acid binding with any of the substrates tested. The substrates included native calf thymus DNA, poly(U), and a double-stranded linear DNA molecule with RSV long terminal repeat sequences at its termini. The COOH-terminal region (residues 178 to 286) of IN bound quantitatively (greater than 90%) to poly(U) and to single-stranded circular phi X174 DNA but did not exhibit the double-stranded linear DNA-binding ability of the entire IN molecule.

Retroviral integrase domains: DNA binding and the recognition of LTR sequences

Integration of retroviral DNA into the host chromosome requires a virus-encoded integrase (IN). IN recognizes, cuts and then joins specific viral DNA sequences (LTR ends) to essentially random sites in host DNA. We have used computer-assisted protein alignments and mutagenesis in an attempt to localize these functions within the avian retroviral IN protein. A comparison of the deduced amino acid sequences for 80 retroviral/retrotransposon IN proteins reveals strong conservation of an HHCC N-terminal 'Zn finger'-like domain, and a central D(35)E region which exhibits striking similarities with sequences deduced for bacterial IS elements. We demonstrate that the HHCC region is not required for DNA binding, but contributes to specific recognition of viral LTRs in the cutting and joining reactions. Deletions which extend into the D(35)E region destroy the ability of IN to bind DNA. Thus, we propose that the D(35)E region may specify a DNA-binding/cutting domain that is conserved throughout evolution in enzymes with similar functions.

Expression of HIV-1 integrase in E. coli: immunological analysis of the recombinant protein

Sequences encoding the human immunodeficiency virus type 1 (HIV-1) integrase gene have been cloned and expressed in Escherichia coli. The expressed protein is a lambda cII fusion protein of 37 kD containing the carboxyl-terminal 23 [corrected] amino acids of reverse transcriptase fused to the entire integrase sequence and is insoluble, a feature which allows partial purification away from soluble bacterial proteins. As judged by its reactivity with HIV positive sera in Western blot and in enzyme-linked immunosorbent assay (ELISA), the recombinant integrase retains antigenicity similar to native protein. Additionally, ELISA data obtained with the cloned protein indicate that patients infected with HIV-1 who are at different stages of progression to AIDS have antibodies reactive with the cloned integrase. HIV-2 positive human sera are also reactive with the cloned integrase. Rabbit antibodies produced against the recombinant protein react both by ELISA and Western blot with the homologous bacterially expressed protein, recognize both virion HIV-1 integrase and reverse transcriptase in Western blots, and immunoprecipitate an HIV-1 virion protein of 34 kD. Unlike human antisera from patients infected with HIV-1 or HIV-2 which are frequently reactive with both HIV-1 and HIV-2 integrase, the rabbit antibodies are type specific, reacting with HIV-1, but not with HIV-2 integrase by Western blot.

Properties of avian retrovirus particles defective in viral protease

The structural and enzymatic components of retroviral cores are formed by proteolytic cleavage of precursor polypeptides, mediated by the viral protease (PR). We constructed an active-site mutation, D37I, in the PR of avian leukosis virus. The D37I mutation was introduced into an infectious DNA clone, and quail cell lines expressing the mutant virus were established. These cell lines produce normal amounts of virus particles, the major internal protein components of which are the uncleaved gag and gag-pol precursors. As in other retroviral systems, the protease-defective virions are noninfectious and retain the "immature" type A morphology as determined by thin-section transmission electron microscopy. The virion cores are stable at nonionic detergent concentrations that completely disrupt wild-type cores. Digestion of mutant virions with exogenous PR in the presence of detergent leads to complete and correct cleavage of the gag precursor but incomplete cleavage of the gag-pol precursor. The protease-defective virions encapsidate normal amounts of genomic RNA and tRNA(Trp) that is properly annealed to the primer-binding site, but some of the genomic RNA remains monomeric. Results from UV cross-linking experiments show that the gag polyprotein of mutant virions interacts with viral RNA and that this interaction occurs through the nucleocapsid (NC) domain. However, within mutant virions the interaction of the NC domain with RNA differs from that of mature NC with RNA in wild-type virions. Reverse transcriptase (RT) activity associated with mutant virions is diminished but still detectable. Digestion of the virions with PR leads to a fivefold increase in activity, but this PR-mediated activation of RT is incomplete. Since in vitro cleavage of the gag-pol precursor is also incomplete, we hypothesize that amino acid sequences N terminal to the reverse transcriptase domain inhibit RT activity.

Ribonucleases H of retroviral and cellular origin

Ribonucleases H (RNases H) are enzymes which catalyse the hydrolysis of the RNA-strand of an RNA-DNA hybrid. Retroviral reverse transcriptases possess RNase H activity in addition to their RNA- as well as DNA-dependent DNA-polymerizing activity. These enzymes transcribe the viral single stranded RNA-genome into double stranded DNA, which then can be handled by the host cell like one of its own genes. Various, sometimes highly repeated, sequences related to retroviruses and like these encompassing two separate domains, one of which potentially codes for a DNA polymerizing, the other for an RNase H activity, are found in genomes of uninfected cells. In addition proteins coded for by cellular genes (e.g. from E. coli and from yeast) are known, which exhibit RNase H activity, the biological function of which is not fully understood. In the light of these facts the question of whether retroviral RNases H could be promising targets for antiviral drugs is discussed.

The avian retroviral integration protein cleaves the terminal sequences of linear viral DNA at the in vivo sites of integration

The purified integration protein (IN) of avian myeloblastosis virus is shown to nick double-stranded oligodeoxynucleotide substrates that mimic the ends of the linear form of viral DNA. In the presence of Mg2+, nicks are created 2 nucleotides from the 3' OH ends of both the U5 plus strand and the U3 minus strand. Similar cleavage is observed in the presence of Mn2+ but only when the extent of the reaction is limited. Neither the complementary strands nor sequences representing the termini of human immunodeficiency virus type 1 DNA were cleaved at analogous positions. Analysis of a series of substrates containing U5 base substitutions has defined the sequence requirements for site-selective nicking; nucleotides near the cleavage site are most critical for activity. The minimum substrate size required to demonstrate significant activity corresponds to the nearly perfect 15-base terminal inverted repeat. This in vitro activity of IN thus produces viral DNA ends that are joined to host DNA in vivo and corresponds to an expected early step in the integrative recombination reaction. These results provide the first enzymatic support using purified retroviral proteins for a linear DNA precursor to the integrated provirus.

Expression and processing of human immunodeficiency virus type 1 gag and pol genes by cells infected with a recombinant vaccinia virus

Human cells infected with a recombinant vaccinia virus containing human immunodeficiency virus type 1 gag-pol genes produced large amounts of human immunodeficiency virus gag proteins beginning at 1 h and peaking at 48 h postinfection. We show that these polyproteins are processed accurately into mature forms and that the viral polymerase gene is encoded as a 160-kilodalton gag-pol fusion protein, most likely by translational frameshifting from the gag into the pol reading frame.

Crystal structure of a retroviral protease proves relationship to aspartic protease family

Retroviral gag, pol and env gene products are translated as precursor polyproteins, which are cleaved by virus-encoded proteases to produce the mature proteins found in virions. On the basis of the conserved Asp-Thr/Ser-Gly sequence at the putative protease active sites, and other biochemical evidence, retroviral proteases have been predicted to be in the family of pepsin-like aspartic proteases. It has been suggested that aspartic proteases evolved from a smaller, dimeric ancestral protein, and a recent model of the human immunodeficiency virus (HIV) protease postulated that a symmetric dimer of this enzyme is equivalent to a pepsin-like aspartic protease. We have now determined the crystal structure of Rous sarcoma virus (RSV) protease at 3-A resolution and find it is dimeric and has a structure similar to aspartic proteases. This structure should provide a useful basis for the modelling of the structures of other retroviral proteases, such as that of HIV, and also for the rational design of protease inhibitors as potential antiviral drugs.

Analysis of mutant Moloney murine leukemia viruses containing linker insertion mutations in the 3' region of pol

Twelve linker insertion mutations have been constructed in the 3' part of the pol gene of Moloney murine leukemia virus. This region of the Moloney murine leukemia virus genome encodes IN or p46pol, which is required for integration of the retroviral DNA into the host cell chromosome. Viral proteins synthesized by these mutants were used to pseudotype a neo-containing retroviral vector. Ten of twelve linker insertion mutant pseudotypes were unable to generate stable proviruses in infected mouse cells, as measured by the formation of G418-resistant colonies. Two mutants mapping at the 3' terminus of the IN-encoding region were competent for the formation of stable vector proviruses (hundreds of G418-resistant colonies per mutant pseudotype-infected plate). Representative linker insertion mutants were also tested for the ability to synthesize viral unintegrated DNA in newly infected cells. All assayed mutants were capable of synthesizing all normal forms of viral unintegrated DNA. The structure of integrated vector proviruses generated by defective and nondefective linker insertion mutants was also analyzed. All replication-competent mutants generated normal proviruses, while the few obtainable proviruses generated by replication-defective mutants were sometimes aberrant in structure. These results argue strongly (and confirm previous data) that the IN-encoding region of pol does not play a significant role in DNA synthesis, but is absolutely required for the formation of normal proviral DNA.

Purification and structural characterization of the putative gag-pol protease of human immunodeficiency virus

We have purified a 10,774-dalton protein from human immunodeficiency virus (HIV) type 1 that is encoded in the protease domain of the pol open reading frame (ORF). Radiochemical amino acid microsequencing identified 12 amino acids from the stretch of 39 N-terminal residues of this protein, beginning with a PQITLW sequence at position 69 of the pol ORF. Radiosequencing of selected tryptic peptides of the protein identified 11 additional residues (Leu-9 and Val-2) in six peptides encompassing the entire molecule of 99 residues. A protein of similar size and identical N-terminal sequence (determined through the first 39 residues) was present among the processed HIV pol gene products in Escherichia coli which expressed the entire HIV pol ORF. The C terminus of both the viral and E. coli-expressed proteins was inferred to be contiguous with the N terminus of the p64-p51 reverse transcriptase on the basis of tryptic mapping and specific immunoreactivity with an antiserum against a dodecapeptide located upstream of the reverse transcriptase. Thus, the initial processing of the pol precursor that generates the native protease is apparently preserved across phylogenetic barriers. Although the purified viral protease lacked measurable proteolytic activity, the bacterial extracts were capable of processing an HIV gag precursor protein synthesized in E. coli.

Activity of avian retroviral protease expressed in Escherichia coli

The 3' end of the avian sarcoma leukosis virus (ASLV) gag gene encodes a 124-amino-acid protease (PR) responsible for processing the gag and pol polyprotein precursors into the mature virion structural proteins and the reverse transcriptase. Here we report the synthesis of the mature ASLV PR and a nucleocapsid (NC)-PR gag precursor fragment in Escherichia coli. E. coli extracts containing mature PR correctly cleaved a synthetic decapeptide homologous to a known ASLV cleavage site. Also, the NC-PR precursor fragment appeared to be correctly processed to produce NC and PR in the bacterial cells. This cleavage was blocked by a mutation in the putative active site of PR. These results strongly support the hypothesis that PR is involved in cleaving itself from the gag precursor.

Properties of avian sarcoma-leukosis virus pp32-related pol-endonucleases produced in Escherichia coli

The gag-pol precursor protein of the avian sarcoma-leukosis virus is processed into three known pol-encoded mature polypeptides; the 95- and 63-kilodalton (kDa) beta and alpha subunits, respectively, of reverse transcriptase and the 32-kDa pp32 protein. The pp32 protein possesses DNA endonuclease activity and is produced from the precursor by two proteolytic cleavage events, one of which removes 4.1 kDa of protein from the C terminus. A 36-kDa protein (p36pol) which retains this C-terminal segment is detectable in small quantities in virions. We have constructed Escherichia coli plasmid clones that express the C-terminal domains of pol corresponding to pp32 and p36. These proteins have been purified by column chromatographic methods to near homogeneity. No significant differences could be detected in the enzymatic properties of the bacterially produced p32pol and p36pol proteins. Both possess DNA endonuclease activity and, like the pp32 protein isolated from virions, can cleave near the junction of two tandem avian sarcoma-leukosis virus long terminal repeats in double-stranded supercoiled DNA substrates. In the presence of Mg2+, both p32pol and viral pp32 cleave either strand of DNA 2 nucleotides 5' to the junction.

Avian retrovirus pp32 DNA endonuclease is phosphorylated on Ser in the carboxyl-terminal region

The avian retrovirus pp32 DNA endonuclease and the beta polypeptide of the reverse transcriptase contain the same three phosphoserine (p-Ser) tryptic peptides. At least 95% of the Pi label is nearly equally distributed between two major p-Ser tryptic peptides derived from either beta or pp32. These polymerase gene-derived proteins were metabolically labeled with various radioactive amino acids or Pi, and the purified protein was subjected to cyanogen bromide or hydroxylamine cleavage. The results indicated that the two major p-Ser tryptic peptides map to the COOH-termini of both proteins. The two major p-Ser tryptic peptides isolated from Pi-labeled pp32 were subjected to proteolysis by three separate specific proteases. Analysis of the data suggested that these p-Ser are located on pp32 at amino acid positions 262 and 282 from the amino terminus of pp32 (286 amino acids in length). At present, we cannot exclude the possibility that one or both p-Ser peptides map between amino acid positions 124 to 150. The role of this site-specific phosphorylation of pp32 and beta is also discussed.

Synthetic peptides as substrates and inhibitors of a retroviral protease

Processing of the gag and pol gene precursor proteins of retroviruses is essential for infectivity and is directed by a viral protease that is itself included in one of these precursors. We demonstrate here that small synthetic peptides can be used as both model substrates and inhibitors to investigate the specificity and molecular parameters of the reaction. The results indicate that a peptide that extends five amino acids but not three amino acids in both directions from a known cleavage site is accurately hydrolyzed by the protease of avian sarcoma-leukosis virus. Substitutions of the amino acids to either side of the peptide bond to be cleaved affect the ability of the peptide (as well as a larger precursor protein) to serve as a substrate. The specificity is more stringent for the amino acid that will become the carboxyl end after cleavage. Some substitutions produced peptides that were not cleaved but could act as inhibitors of cleavage of a susceptible peptide. Thus, small model substrates may be used to explore both the binding and catalytic properties of these important proteases.

The alpha and beta chains of avian retrovirus reverse transcriptase independently expressed in Escherichia coli: characterization of enzymatic activities

Reverse transcriptase of the avian sarcoma and leukosis retroviruses is a heterodimer composed of a 63-kDa alpha and a 95-kDa beta polypeptide chain, both of which are encoded in the pol gene and are produced by proteolytic processing of a larger precursor. We previously constructed a bacterial expression clone of the entire pol coding region that produces a protein 4 kDa larger than the mature viral beta subunit. By use of this clone and synthetic oligonucleotides to introduce stop codons, two derivatives have been constructed: one that directs synthesis of a protein equivalent to the mature beta subunit and the other that directs synthesis of a protein equivalent to alpha subunit. Predicted amino acid sequences of these proteins differ from their viral counterparts only by an initiator methionine that was added to the N termini for expression in Escherichia coli. Both bacterially expressed proteins exhibit reverse transcriptase activity and appear to function as homodimers. The properties of these proteins resemble those of the viral reverse transcriptase heterodimer; however, the bacterially produced alpha dimer protein could be distinguished from the other proteins by its increased sensitivity to heat inactivation, which also has been reported for the corresponding viral product. These results show that correct folding and expression of enzymatic function does not require formation of a precursor. The alpha and beta clones provide a convenient source of individual pol gene products for further evaluation of their roles in the synthesis and integration of retroviral DNA.

A C-terminal domain in the avian sarcoma-leukosis virus pol gene product is not essential for viral replication

The virion proteins encoded by the avian retroviral pol gene (reverse transcriptase and endonuclease) are formed by the proteolytic processing of a gag-pol fusion protein precursor. Recent studies have predicted that the avian sarcoma-leukosis virus pol precursor protein undergoes a previously undetected processing event resulting in the formation of common C termini for the endonuclease (pp32) and the beta subunit of reverse transcriptase (F. Alexander, J. Leis, D. A. Soltis, R. M. Crowl, W. Danho, M. S. Poonian, Y.-C. E. Pan, and A. M. Skalka, J. Virol. 61:534-542, 1987; D. Grandgenett, T. Quinn, P. J. Hippenmeyer, and S. Oroszlan, J. Biol. Chem. 260:8243-8249, 1985). This processing event removes 37 amino acids, thus defining a new pol domain. In this report, we present evidence that this C-terminal domain is translated as part of the gag-pol precursor but is not required for replication of the virus in tissue culture cells.

Avian sarcoma-leukosis virus pol-endo proteins expressed independently in mammalian cells accumulate in the nucleus but can be directed to other cellular compartments

Eucaryotic expression vectors have been used to study transient expression of the avian sarcoma-leukosis retrovirus pol-endo protein in COS cells. The constructs encode proteins with N termini identical to that of authentic viral pp32 endonuclease with the exception of a single met residue encoded by the initiator AUG. The C termini correspond to unprocessed viral pol protein, authentic processed pp32, or a derivative which includes eight amino acids from the unprocessed portion. All three proteins localize to the nucleus. However, when the pol-endo domain is fused to a secretory signal peptide, the protein is found in medium and appears also to localize in the Golgi bodies and the cell membrane. These and derivative vectors will make it possible to assess the consequence of retroviral pol gene expression in eucaryotic cells.

Avian sarcoma and leukosis virus pol-endonuclease recognition of the tandem long terminal repeat junction: minimum site required for cleavage is also required for viral growth

Integration of retroviral DNA is a site-specific reaction involving an endonuclease encoded by the viral pol gene (pol-endo). In vitro the pol-endo from avian sarcoma and leukosis viruses (ASLVs) cleaves both DNA strands near the U5-U3 junction of tandem long terminal repeats (LTR-LTR junction) in single-stranded and replicative form (RF)-I substrates. We have reported previously that the sequences that are required for cleavage of single-stranded substrates by the alpha beta form of the pol-endo differ for the plus and minus strands (G. Duyk, M. Longiaru, D. Cobrinik, R. Kowal, P. deHaseth, A. M. Skalka, and J. Leis, J. Virol. 56:589-599, 1985). This is not the case with RF-I substrates, in which a maximum of 22 base pairs of U5 and 8 base pairs of U3 were required for alpha beta pol-endo cleavage in each strand. Insertion of a palindromic octanucleotide (CATCGATG) at the LTR-LTR junction abolished cleavage in RF-I but not in single-stranded DNA substrates. Deletion of the four nucleotides (TTAA) at the junction prevented cleavage in the plus strand of RF-I DNA, but did not affect cleavage of single-stranded DNA. Furthermore, the alpha beta form of ASLV pol-endo did not recognize heterologous LTR-LTR junction sequences from the reticuloendotheliosis virus or Moloney murine leukemia virus in either substrate form, despite their sequence and structural similarities to the ASLV junction. These results support a role for a sequence-specific interaction between the ASLV pol-endo and the LTR-LTR junction domains that are required for cleavage. By using the infectious Rous sarcoma virus clone pATV8-K, we introduced a set of deletions into the U5 region that would be incorporated into the LTR-LTR junction on viral replication. In the unintegrated provirus, the deletions started 43 base pairs from the LTR-LTR junction and extended various lengths toward the junction. Results of transfection studies with these clones indicated that the U5 sequences that are required for virus production in vivo correspond to those that are required for cleavage of RF-I DNA in vitro.