Characterization of the dimerization process of HIV-1 reverse transcriptase heterodimer using intrinsic protein fluorescence

Peptides Mimicking the β7/β8 Loop of HIV-1 Reverse Transcriptase p51 as "Hotspot-Targeted" Dimerization Inhibitors

A conformationally constrained short peptide designed to target a protein-protein interaction hotspot in HIV-1 reverse transcriptase (RT) disrupts p66-p51 interactions and paves the way to the development of novel RT dimerization inhibitors.

Structural Maturation of HIV-1 Reverse Transcriptase-A Metamorphic Solution to Genomic Instability

Human immunodeficiency virus 1 (HIV-1) reverse transcriptase (RT)—a critical enzyme of the viral life cycle—undergoes a complex maturation process, required so that a pair of p66 precursor proteins can develop conformationally along different pathways, one evolving to form active polymerase and ribonuclease H (RH) domains, while the second forms a non-functional polymerase and a proteolyzed RH domain. These parallel maturation pathways rely on the structural ambiguity of a metamorphic polymerase domain, for which the sequence–structure relationship is not unique. Recent nuclear magnetic resonance (NMR) studies utilizing selective labeling techniques, and structural characterization of the p66 monomer precursor have provided important insights into the details of this maturation pathway, revealing many aspects of the three major steps involved: (1) domain rearrangement; (2) dimerization; and (3) subunit-selective RH domain proteolysis. This review summarizes the major structural changes that occur during the maturation process. We also highlight how mutations, often viewed within the context of the mature RT heterodimer, can exert a major influence on maturation and dimerization. It is further suggested that several steps in the RT maturation pathway may provide attractive targets for drug development.

TSAO Derivatives the First Non-Peptide Inhibitors of HIV-1 RT Dimerization

The combination of different anti-HIV agents has become the standard of care for AIDS or HIV-infected individuals. Important progress has been made in the development of drugs for the clinical treatment of HIV infection. To date, 20 drugs have been approved for the treatment of AIDS. However, viral rebound during therapy, the emergence of HIV drug resistance and the need for long-term treatment modalities are the main causes for the failure of current antiretroviral therapy. There is still a need for the development of new drugs that are either less toxic, active against the growing number of drug-resistant HIV strains or directed to novel targets in the viral life cycle. Eleven of the approved anti-HIV drugs target the reverse transcriptase (RT). Among the so-called non-nucleoside RT inhibitors (NNRTIs) TSAO derivatives are an unusual class of compounds that exert their unique selectivity for HIV-1 through a specific interaction with the p51 subunit of HIV-1 RT. They are the only NNRTIs for which amino acids at both subunits (p66 and p51) of HIV-1 RT are needed for optimal interaction with the enzyme. Moreover, the TSAO compounds are the first non-peptide molecules that interfere with the dimerization of the enzyme.

Biophysical Insights into the Inhibitory Mechanism of Non-Nucleoside HIV-1 Reverse Transcriptase Inhibitors

HIV-1 reverse transcriptase (RT) plays a central role in HIV infection. Current United States Federal Drug Administration (USFDA)-approved antiretroviral therapies can include one of five approved non-nucleoside RT inhibitors (NNRTIs), which are potent inhibitors of RT activity. Despite their crucial clinical role in treating and preventing HIV-1 infection, their mechanism of action remains elusive. In this review, we introduce RT and highlight major advances from experimental and computational biophysical experiments toward an understanding of RT function and the inhibitory mechanism(s) of NNRTIs.

Gag-Pol processing during HIV-1 virion maturation: a systems biology approach

Proteolytic processing of Gag and Gag-Pol polyproteins by the viral protease (PR) is crucial for the production of infectious HIV-1, and inhibitors of the viral PR are an integral part of current antiretroviral therapy. The process has several layers of complexity (multiple cleavage sites and substrates; multiple enzyme forms; PR auto-processing), which calls for a systems level approach to identify key vulnerabilities and optimal treatment strategies. Here we present the first full reaction kinetics model of proteolytic processing by HIV-1 PR, taking into account all canonical cleavage sites within Gag and Gag-Pol, intermediate products and enzyme forms, enzyme dimerization, the initial auto-cleavage of full-length Gag-Pol as well as self-cleavage of PR. The model allows us to identify the rate limiting step of virion maturation and the parameters with the strongest effect on maturation kinetics. Using the modelling framework, we predict interactions and compensatory potential between individual cleavage rates and drugs, characterize the time course of the process, explain the steep dose response curves associated with PR inhibitors and gain new insights into drug action. While the results of the model are subject to limitations arising from the simplifying assumptions used and from the uncertainties in the parameter estimates, the developed framework provides an extendable open-access platform to incorporate new data and hypotheses in the future.

Features of protein-protein interactions that translate into potent inhibitors: topology, surface area and affinity

Protein-protein interactions (PPIs) control the assembly of multi-protein complexes and, thus, these contacts have enormous potential as drug targets. However, the field has produced a mix of both exciting success stories and frustrating challenges. Here, we review known examples and explore how the physical features of a PPI, such as its affinity, hotspots, off-rates, buried surface area and topology, might influence the chances of success in finding inhibitors. This analysis suggests that concise, tight binding PPIs are most amenable to inhibition. However, it is also clear that emerging technical methods are expanding the repertoire of 'druggable' protein contacts and increasing the odds against difficult targets. In particular, natural product-like compound libraries, high throughput screens specifically designed for PPIs and approaches that favour discovery of allosteric inhibitors appear to be attractive routes. The first group of PPI inhibitors has entered clinical trials, further motivating the need to understand the challenges and opportunities in pursuing these types of targets.

Nucleocapsid protein annealing of a primer-template enhances (+)-strand DNA synthesis and fidelity by HIV-1 reverse transcriptase

Human immunodeficiency virus type 1 (HIV-1) requires reverse transcriptase (RT) and HIV-1 nucleocapsid protein (NCp7) for proper viral replication. HIV-1 NCp7 has been shown to enhance various steps in reverse transcription including tRNA initiation and strand transfer, which may be mediated through interactions with RT as well as RNA and DNA oligonucleotides. With the use of DNA oligonucleotides, we have examined the interaction of NCp7 with RT and the kinetics of reverse transcription during (+)-strand synthesis with an NCp7-facilitated annealed primer-template. Through the use of a pre-steady-state kinetics approach, the NCp7-annealed primer-template has a substantial increase (3- to 7-fold) in the rate of incorporation (k(pol)) by RT as compared to heat-annealed primer-template with single-nucleotide incorporation. There was also a 2-fold increase in the binding affinity constant (K(d)) of the nucleotide. These differences in k(pol) and K(d) were not through direct interactions between HIV-1 RT and NCp7. When extension by RT was examined, the data suggest that the NCp7-annealed primer-template facilitates the formation of a longer product more quickly compared to the heat-annealed primer-template. This enhancement in rate is mediated through interactions with NCp7's zinc fingers and N-terminal domain and nucleic acids. The NCp7-annealed primer-template also enhances the fidelity of RT (3-fold) by slowing the rate of incorporation of an incorrect nucleotide. Taken together, this study elucidates a new role of NCp7 by facilitating DNA-directed DNA synthesis during reverse transcription by HIV-1 RT that may translate into enhanced viral fitness and offers an avenue to exploit for targeted therapeutic intervention against HIV.

Dithiothreitol causes HIV-1 integrase dimer dissociation while agents interacting with the integrase dimer interface promote dimer formation

We have developed a homogeneous time-resolved fluorescence resonance energy transfer (FRET)-based assay that detects the formation of HIV-1 integrase (IN) dimers. The assay utilizes IN monomers that express two different epitope tags that are recognized by their respective antibodies, coupled to distinct fluorophores. Surprisingly, we found that dithiothreitol (DTT), a reducing agent essential for in vitro enzymatic activity of IN, weakened the interaction between IN monomers. This effect of DTT on IN is dependent on its thiol groups, since the related chemical threitol, which contains hydroxyls in place of thiols, had no effect on IN dimer formation. By studying mutants of IN, we determined that cysteines in IN appear to be dispensable for the dimer dissociation effect of DTT. Peptides derived from the IN binding domain (IBD) of lens epithelium derived growth factor/transcriptional coactivator p75 (LEDGF), a cellular cofactor that interacts with the IN dimer interface, were tested in this IN dimerization assay. These peptides, which compete with LEDGF for binding to IN, displayed an intriguing equilibrium binding dose-response curve characterized by a plateau rising to a peak, then descending to a second plateau. Mathematical modeling of this binding system revealed that these LEDGF-derived peptides promote IN dimerization and block subunit exchange between IN dimers. This dose-response behavior was also observed with a small molecule that interacts with the IN dimer interface and inhibits LEDGF binding to IN. In conclusion, this novel IN dimerization assay revealed that peptide and small molecule inhibitors of the IN-LEDGF interaction also stabilize IN dimers and promote their formation.

Homodimerization of the p51 subunit of HIV-1 reverse transcriptase

The dimerization of HIV reverse transcriptase (RT), required to obtain the active form of the enzyme, is influenced by mutations, non-nucleoside reverse transcriptase inhibitors (NNRTIs), nucleotide substrates, Mg ions, temperature, and specifically designed dimerization inhibitors. In this study, we have utilized nuclear magnetic resonance (NMR) spectroscopy of the [methyl-(13)C]methionine-labeled enzyme and small-angle X-ray scattering (SAXS) to investigate how several of these factors influence the dimerization behavior of the p51 subunit. The (1)H-(13)C HSQC spectrum of p51 obtained at micromolar concentrations indicates that a significant fraction of the p51 adopts a "p66-like" conformation. SAXS data obtained for p51 samples were used to determine the fractions of monomer and dimer in the sample and to evaluate the conformation of the fingers/thumb subdomain. All of the p51 monomer observed was found to adopt the compact, "p51C" conformation observed for the p51 subunit in the RT heterodimer. The NMR and SAXS data indicate that the p51 homodimer adopts a structure that is similar to the p66/p51 heterodimer, with one p51C subunit and a second p51 subunit in an extended, "p51E" conformation that resembles the p66 subunit of the heterodimer. The fractional dimer concentration and the fingers/thumb orientation are found to depend strongly on the experimental conditions and exhibit a qualitative dependence on nevirapine and ionic strength (KCl) that is similar to the behavior reported for the heterodimer and the p66 homodimer. The L289K mutation interferes with p51 homodimer formation as it does with formation of the heterodimer, despite its location far from the dimer interface. This effect is readily interpreted in terms of a conformational selection model, in which p51(L289K) has a much greater preference for the compact, p51C conformation. A reduced level of dimer formation then results from the reduced ratio of the p51E(L289K) to p51C(L289K) monomers.

Efavirenz binding to HIV-1 reverse transcriptase monomers and dimers

Efavirenz (EFV) is a nonnucleoside reverse transcriptase inhibitor (NNRTI) of HIV-1 reverse transcriptase (RT) used for the treatment of AIDS. RT is a heterodimer composed of p66 and p51 subunits; p51 is produced from p66 by C-terminal truncation by HIV protease. The monomers can form p66/p66 and p51/p51 homodimers as well as the p66/p51 heterodimer. Dimerization and efavirenz binding are coupled processes. In the crystal structure of the p66/p51-EFV complex, the drug is bound to the p66 subunit. The binding of efavirenz to wild-type and dimerization-defective RT proteins was studied by equilibrium dialysis, tryptophan fluorescence, and native gel electrophoresis. A 1:1 binding stoichiometry was determined for both monomers and homodimers. Equilibrium dissociation constants are approximately 2.5 microM for both p66- and p51-EFV complexes, 250 nM for the p66/p66-EFV complex, and 7 nM for the p51/p51-EFV complex. An equilibrium dissociation constant of 92 nM for the p66/p51-EFV complex was calculated from the thermodynamic linkage between dimerization and inhibitor binding. Binding and unbinding kinetics monitored by fluorescence were slow. Progress curve analyses revealed a one-step, direct binding mechanism with association rate constants k(1) of approximately 13.5 M(-1) s(-1) for monomers and heterodimer and dissociation rate constants k(-1) of approximately 9 x 10(-5) s(-1) for monomers. A conformational selection mechanism is proposed to account for the slow association rate. These results show that efavirenz is a slow, tight-binding inhibitor capable of binding all forms of RT and suggest that the NNRTI binding site in monomers and dimers is similar.

Kinetics of association and dissociation of HIV-1 reverse transcriptase subunits

The biologically active form of HIV-1 reverse transcriptase (RT) is the p66/p51 heterodimer. The process of maturation of the heterodimer from precursor proteins is poorly understood. Previous studies indicated that association of p66 and p51 is very slow. Three techniques, a pre-steady-state activity assay, intrinsic tryptophan fluorescence, and a FRET assay, were used to monitor the dimerization kinetics of RT. Kinetic experiments were conducted with purified p66 and p51 proteins in aqueous buffer. All three techniques gave essentially the same results. The dissociation kinetics of p66/p51 were first-order with rate constants (k(diss)) of approximately 4 x 10(-6) s(-1) (t(1/2) = 48 h). The association kinetics of p66 and p51 were concentration-dependent with second-order rate constants (k(ass)) of approximately 1.7 M(-1) s(-1) for the simple bimolecular association reaction. The implications of slow dimerization of p66/p51 for the maturation process are discussed. A reaction-controlled model invoking conformational selection is proposed to explain the slow protein-protein association kinetics.

Affinities between the binding partners of the HIV-1 integrase dimer-lens epithelium-derived growth factor (IN dimer-LEDGF) complex

The interaction between lens epithelium-derived growth factor/transcriptional co-activator p75 (LEDGF) and human immunodeficiency virus type 1 (HIV-1) integrase (IN) is essential for HIV-1 replication. Homogeneous time-resolved fluorescence resonance energy transfer assays were developed to characterize HIV-1 integrase dimerization and the interaction between LEDGF and IN dimers. Using these assays in an equilibrium end point dose-response format with mathematical modeling, we determined the dissociation constants of IN dimers (K(dimer) = 67.8 pm) and of LEDGF from IN dimers (K(d) = 10.9 nm). When used in a kinetic format, the assays allowed the determination of the on- and off-rate constants for these same interactions. Integrase dimerization had a k(on) of 0.1247 nm(-1) x min(-1) and a k(off) of 0.0080 min(-1) resulting in a K(dimer) of 64.5 pm. LEDGF binding to IN dimers had a k(on) of 0.0285 nm(-1).min(-1) and a k(off) of 0.2340 min(-1) resulting in a K(d) of 8.2 nm. These binding assays can also be used in an equilibrium end point competition format. In this format, the IN catalytic core domain produced a K(i) of 15.2 nm while competing for integrase dimerization, confirming the very tight interaction of IN with itself. In the same format, LEDGF produced a K(i) value of 35 nm when competing for LEDGF binding to IN dimers. In summary, this study describes a methodology combining homogeneous time-resolved fluorescence resonance energy transfer and mathematical modeling to derive the affinities between IN monomers and between LEDGF and IN dimers. This study revealed the significantly tighter nature of the IN-IN dimer compared with the IN-LEDGF interaction.

Small molecule inhibitors targeting HIV-1 reverse transcriptase dimerization

The enzymatic activities of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) are strictly correlated with the dimeric forms of this vital retroviral enzyme. Accordingly, the development of inhibitors targeting the dimerization of RT represents a promising alternative antiviral strategy. Based on mutational studies, we applied a structure-based ligand design approach generating pharmacophoric models of the large subunit connection subdomain to possibly identify small molecules from the ASINEX database, which might interfere with the RT subunit interaction. Docking studies of the selected compounds identified several candidates, which were initially tested in an in vitro subunit association assay. One of these molecules (MAS0) strongly reduced the association of the two RT subunits p51 and p66. Most notably, the compound simultaneously inhibited both the polymerase as well as the RNase H activity of the retroviral enzyme, following preincubation with t(1/2) of about 2 h, indicative of a slow isomerization step. This step most probably represents a shift of the RT dimer equilibrium from an active to an inactive conformation. Taken together, to the best of our knowledge, this study represents the first successful rational screen for a small molecule HIV RT dimerization inhibitor, which may serve as attractive hit compound for the development of novel therapeutic agents.

Dimerization inhibitors of HIV-1 reverse transcriptase, protease and integrase: A single mode of inhibition for the three HIV enzymes?

The genome of human immunodeficiency virus type 1 (HIV-1) encodes 15 distinct proteins, three of which provide essential enzymatic functions: a reverse transcriptase (RT), an integrase (IN), and a protease (PR). Since these enzymes are all homodimers, pseudohomodimers or multimers, disruption of protein-protein interactions in these retroviral enzymes may constitute an alternative way to achieve HIV-1 inhibition. A growing number of dimerization inhibitors for these enzymes is being reported. This mini review summarizes some approaches that have been followed for the development of compounds that inhibit those three enzymes by interfering with the dimerization interfaces between the enzyme subunits.

Structure−Activity Relationships of [2‘,5‘-Bis-O-(tert-butyldimethylsilyl)-β-d-ribofuranosyl]- 3‘-spiro-5‘ ‘-(4‘ ‘-amino-1‘ ‘,2‘ ‘-oxathiole-2‘ ‘,2‘ ‘-dioxide)thymine Derivatives as Inhibitors of HIV-1 Reverse Transcriptase Dimerization

The polymerase activity of HIV-1 reverse transcriptase (RT) is entirely dependent on the heterodimeric structure of the enzyme. Accordingly, RT dimerization represents a target for the development of a new therapeutic class of HIV inhibitors. We previously demonstrated that the N-3-ethyl derivative of 2',5'-bis-O-(tert-butyldimethylsilyl)-beta-D-ribofuranosyl]-3'-spiro-5' '-(4' '-amino-1' ',2' '-oxathiole-2' ',2' '-dioxide)thymine (TSAO-T) destabilizes the inter-subunit interactions of HIV-1 RT [Sluis-Cremer, N.; Dmietrinko, G. I.; Balzarini, J.; Camarasa, M.-J.; Parniak, M. A. Biochemistry 2000, 39, 1427-1433]. In the current study, we evaluated the ability of 64 TSAO-T derivatives to inhibit RT dimerization using a novel screening assay. Five derivatives were identified with improved activity compared to TSAO-T. Four of these harbored hydrophilic or aromatic substituents at the N3 position. Furthermore, a good correlation between the ability of the TSAO-T derivatives to inhibit RT dimerization and the enzyme's polymerase activity was also observed. This study provides an important framework for the rational design of more potent inhibitors of RT dimerization.

Mutations that abrogate human immunodeficiency virus type 1 reverse transcriptase dimerization affect maturation of the reverse transcriptase heterodimer

The specific impact of mutations that abrogate human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) dimerization on virus replication is not known, as mutations shown previously to inhibit RT dimerization also impact Gag-Pol stability, resulting in pleiotropic effects on HIV-1 replication. We have previously characterized mutations at codon 401 in the HIV-1 RT tryptophan repeat motif that abrogate RT dimerization in vitro, leading to a loss in polymerase activity. The introduction of the RT dimerization-inhibiting mutations W401L and W401A into HIV-1 resulted in the formation of noninfectious viruses with reduced levels of both virion-associated and intracellular RT activity compared to the wild-type virus and the W401F mutant, which does not inhibit RT dimerization in vitro. Steady-state levels of the p66 and p51 RT subunits in viral lysates of the W401L and W401A mutants were reduced, but no significant decrease in Gag-Pol was observed compared to the wild type. In contrast, there was a decrease in processing of p66 to p51 in cell lysates for the dimerization-defective mutants compared to the wild type. The treatment of transfected cells with indinavir suggested that the HIV-1 protease contributed to the degradation of virion-associated RT subunits. These data demonstrate that mutations near the RT dimer interface that abrogate RT dimerization in vitro result in the production of replication-impaired viruses without detectable effects on Gag-Pol stability or virion incorporation. The inhibition of RT activity is most likely due to a defect in RT maturation, suggesting that RT dimerization represents a valid drug target for chemotherapeutic intervention.

Role of residues in the tryptophan repeat motif for HIV-1 reverse transcriptase dimerization

The tryptophan repeat motif of the human immunodeficiency virus type-1 (HIV-1) reverse transcriptase (RT) is comprised of a cluster of six tryptophan residues at codons 398, 401, 402, 406, 410 and 414 that are highly conserved amongst primate lentiviral RTs. To determine the contributions of each of these residues for HIV-1 RT dimerization, we introduced changes into cloned DNA and tested the mutant subunits for their capacity to mediate heterodimerization in the yeast two-hybrid system. Changes of residue 401 to either leucine or alanine (but not phenylalanine) and residue 414 to leucine resulted in major reductions in beta-galactosidase activity produced from the reporter gene as compared to yeast expressing wild-type p66 bait and p51 prey fusions. Subunit selective mutagenesis revealed that the effect of these mutations was mediated mainly through the p66 subunit. Introduction of tryptophan mutants into the bacterial expression vector pRT6H/NB-PROT showed that RTs containing W401A or W401L substitutions (but not W401F) and W414L were defective for dimerization in vitro. Consistent with their dimerization defect, the W401A, W401L and W414L mutants were devoid of RT activity. Using the yeast two-hybrid system, we identified several second-site suppressors in p66 that restored interaction of the p66W401A bait to the p51W401A prey. The suppressors (T409I, D110G, V372A and I393M) also restored heterodimerization of bacterially expressed W401A subunits. When introduced into the W401A mutant, T409I was able to restore RT activity to 50% of the wild-type level. Examination of the RT structures revealed that K331 in p51 makes multiple hydrogen bond contacts with residues in the p66 loop spanned by W401 and W414. Consistent with this observation, the K331A RT mutant was dimerization-defective. We conclude that mutations at codons 401 and 414 in p66 impair dimerization by altering the proper positioning of structural elements in between these residues that make important contacts with p51.

Destabilization of the HIV-1 reverse transcriptase dimer upon interaction with N-acyl hydrazone inhibitors

N-(4-tert-butylbenzoyl)-2-hydroxy-1-naphthaldehyde hydrazone (BBNH) inhibits both the DNA polymerase and ribonuclease H (RNase H) activities of the human immunodeficiency virus type 1 reverse transcriptase. In this study, we show that BBNH binding impacts on the stability of the human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) heterodimer. The Gibbs free energy of dimer dissociation of HIV-1 RT is decreased in the presence of increasing concentrations of BBNH, resulting in a loss in stability of 3.8 kcal mol(-1). To evaluate whether this observed phenomenon was mediated by BBNH binding to one or more sites in RT, we synthesized a variety of BBNH analogs and identified (4-t-butylbenzoyl)-2-hydroxy-1-salicylyl hydrazone (BBSH) and (4,N,N-dimethylaminobenzoyl)-2-hydroxy-1-naphthyl hydrazone as specific inhibitors of RT DNA polymerase or RT RNase H activity, respectively. Interestingly, only BBSH provided significant destabilization of the HIV-1 RT dimer. The identification of these specific inhibitors, in combination with other biochemical data, suggests a model in which two molecules of BBNH bind per RT heterodimer. In this regard, only the binding of hydrazone molecules in the DNA polymerase domain activity elicits the observed destabilization of the HIV-1 RT heterodimer.

Insertion of a peptide from MuLV RT into the connection subdomain of HIV-1 RT results in a functionally active chimeric enzyme in monomeric conformation

The natural form of the human immunodeficiency virus type one reverse transcriptase (HIV-1 RT) found in virion particles is a heterodimer composed of the p66 and p51 subunits. The catalytic activity resides in the larger subunit in the heterodimeric (p66/p51) enzyme while in the monomeric form it is inactive. In contrast, Murine leukemia virus RT (MuLV RT) is functionally active in the monomeric form. In the primary amino acid sequence alignment of MuLV RT and HIV-1 RT, we have identified three specific regions in MuLV RT, that were missing in HIV-1 RT. In a separate study, we have shown that a chimeric RT construct comprising of the polymerase domain of HIV-1 RT and RNase-H domain of MuLV RT is functionally active as monomer [20]. In this communication, we demonstrate that insertion of a peptide (corresponding to amino acid residues 480-506) from the connection subdomain of MuLV RT into the connection subdomain of HIV-1 RT (between residues 429 and 430) results in a functionally active monomeric chimeric RT. Furthermore, this chimeric enzyme does not dimerize with exogenously added p51 subunit of HIV-1RT. Functional analysis of the chimeric RT revealed template specific variations in its catalytic activity. The chimeric enzyme catalyzes DNA synthesis on both heteropolymeric DNA and homopolymeric RNA (poly rA) template but curiously lacks reverse transcriptase ability on heteropolymeric RNA template. Similar to MuLV RT, the polymerase activity of the chimeric enzyme is not affected by acetonitrile, a reagent which dissociates dimeric HIV-1 RT into inactive monomers. These results together with a proposed 3-D molecular model of the chimeric enzyme suggests that the insertion of the missing region may induce a change in the spatial position of RNase H domain such that it is functionally active in monomeric conformation.

Identification of a putative binding site for [2',5'-bis-O-(tert-butyldimethylsilyl)-beta-D-ribofuranosyl]-3'-spiro-5''-(4''-amino-1'',2''-oxathiole-2'',2''-dioxide)thymine (TSAO) derivatives at the p51-p66 interface of HIV-1 reverse transcriptase

A binding site for TSAO-m(3)T at the interface between the p66 and p51 subunits of HIV-1 reverse transcriptase (RT) and distinct from that of "classical" HIV-1 non-nucleoside inhibitors is proposed. The feasibility of the binding mode was assessed by carrying out nanosecond molecular dynamics simulations for the complexes of TSAO-m(3)T with reduced models of both the wild-type enzyme and a more sensitive R172A mutant. The molecular model is in agreement with a previous proposal, with known structure-activity and mutagenesis data for this unique class of inhibitors, and also with recent biochemical evidence indicating that TSAO analogues can affect enzyme dimerization. The relative importance of residues involved in dimer formation and TSAO-RT complex stabilization was assessed by a combination of surface area accessibility, molecular mechanics, and continuum electrostatics calculations. A structure-based modification introduced into the lead compound yielded a new derivative with improved antiviral activity.

Functional characterization of chimeric reverse transcriptases with polypeptide subunits of highly divergent HIV-1 group M and O strains

Human immunodeficiency virus (HIV)-1 strains have been divided into three groups: main (M), outlier (O), and non-M non-O (N). Biochemical analyses of HIV-1 reverse transcriptase (RT) have been performed predominantly with enzymes derived from HIV-1 group M:subtype B laboratory strains. This study was designed to optimize the expression and to characterize the enzymatic properties of HIV-1 group O RTs as well as chimeric RTs composed of group M and O p66 and p51 subunits. The DNA-dependent DNA polymerase activity on a short heteropolymeric template-primer was similar with all enzymes, i.e. the HIV-1 group O and M and chimeric RTs. Our data revealed that the 51-kDa subunit in the chimeric heterodimer p66(M:B)/p51(O) confers increased heterodimer stability and partial resistance to non-nucleoside RT inhibitors. Chimeric RTs (p66(M:B)/p51(O) and p66(O)/p51(M:B)) were unable to initiate reverse transcription from tRNA(3)(Lys) using HIV-1 group O or group M:subtype B RNA templates. In contrast, HIV-1 group O and M RTs supported (-)-strand DNA synthesis from tRNA(3)(Lys) hybridized to any of their corresponding HIV-1 RNA templates. HIV-2 RT could not initiate reverse transcription on tRNA(3)(Lys)-primed HIV-1 genomic RNA. These findings suggest that the initiation event is conserved between HIV-1 groups, but not HIV types.

An integrated system to study multiply substituted human immunodeficiency virus type 1 reverse transcriptase

We describe a gene system allowing the facile production of multiply substituted reverse transcriptases (RTs), the enzymatic characterization of these purified RTs, and the study of these mutations in the defined genetic background of the macrophagetropic, non-laboratory-adapted human immunodeficiency virus type 1 (HIV-1) AD8 strain. Thirteen unique silent restriction sites were introduced in the pol gene encoding HIV-1 RT, allowing easy introduction of mutations. To simplify genetic manipulation and generate p66/p51 heterodimers in Escherichia coli, a gene construct of the viral protease alone was optimized for expression from a separate vector carrying a p15A origin of replication. Active-site titration experiments using pre-steady-state kinetics showed that our system yields a higher proportion of active enzyme than that obtained by alternate methods. To facilitate phenotype/genotype correlations, the modified RT gene was designed to be easily reintroduced into a recombinant proviral AD8 HIV-1 DNA. Infectious viruses made from this vector were undistinguishable from wild-type AD8 HIV-1, an isolate able to infect peripheral blood mononuclear cells and macrophages. Thus, the pol gene can tolerate many silent mutations in the polymerase domain without affecting the functionality of the HIV-1 genome. The system was validated biochemically and virologically using the V75T substitution associated with stavudine resistance.

Factors affecting the dimerization of the p66 form of HIV-1 reverse transcriptase

The association and dissociation of the homodimeric p66/p66 form of HIV-1 reverse transcriptase were investigated. The effects on the dimerization process of different salt concentrations, pH and the presence of a template/primer and nucleotide substrates were monitored by measuring polymerase activity and analytical size-exclusion HPLC. At submicromolar concentrations of enzyme and physiological salt concentrations, most of the enzyme exists in the inactive monomeric form. Increasing NaCl concentration from 0.05 to 1 M decreased the equilibrium dissociation constant from 2.0 to 0.34 microM. Analysis of the kinetics of the dimerization process indicated it followed a two-step mechanism, with rapid initial association of the two subunits to form an inactive homodimer followed by a slow isomerization step rendering the active enzyme form. The presence of poly(rA)/dT(20) decreased the equilibrium dissociation constant of the homodimer about 30-fold, while the addition of 5 microM dTTP had no effect. The kinetics of the process showed that the template/primer favored dimerization by binding to the inactive homodimer and promoting its isomerization to the active form. These results were confirmed by analyzing the reverse reaction, i.e. the dissociation of the enzyme, by dilution in a low-ionic-strength buffer. The results suggest that binding of immature HIV-1 reverse transcriptase to its natural template/primer may be relevant in both the dimerization process and the selection of its natural primer.

Analysis of mutations and suppressors affecting interactions between the subunits of the HIV type 1 reverse transcriptase

HIV-1 reverse transcriptase (RT) catalyzes the conversion of genomic RNA into cDNA. The enzyme is a heterodimer of p66 and p51 subunits, and the dimerization of these subunits is required for optimal enzyme activity. To analyze this process at the genetic level, we developed constructs that permit the detection of the interaction between these subunits in the yeast two-hybrid system. Genetic analysis of RT subdomains required for heterodimerization revealed that the fingers and palm of p66 were dispensable for p51 interaction. However, as little as a 26-amino acid deletion at the C terminus of p51 prevented dimerization with p66. A primer grip mutation, L234A, previously shown to inhibit RT dimerization by biochemical assays, also prevented RT dimerization in the yeast two-hybrid system. Second-site mutations that restored RT dimerization in yeast to the L234A parent were recovered in the tryptophan repeat region at the dimer interface and at the polymerase active site, suggesting the involvement of these sites in RT dimerization. In vitro binding experiments confirmed the effects of the L234A mutation and the suppressor mutations on the interaction of the two subunits. The RT two-hybrid assay should facilitate the extensive genetic analysis of RT dimerization and should make possible the rapid screening of potential inhibitors of this essential process.

Mixed reconstitution of mutated subunits of HIV-1 reverse transcriptase coexpressed in Escherichia coli - two tags tie it up

The active form of HIV-1 reverse transcriptase (RT) is a p66/p51 heterodimer, in which the p51 subunit is generated by C-terminal proteolytic cleavage of p66. A well-known problem of p66 recombinant expression is partial cleavage of a 15-kDa peptide from the C-terminus by host proteases that can not be completely suppressed. In order to analyse the contribution of specific residues to a particular function in one distinct subunit, an expression and purification system is required that selects for the combination of the two individual subunits with the desired substitutions. We reconstituted the p66/p51 heterodimer from subunits coexpressed in Escherichia coli as an N-terminal fusion protein of glutathione S-transferase (GST) with p51 and a C-terminally His-tagged p66, respectively. The two-plasmid coexpression system ensures convenience for gene manipulation while degradation is reduced to a minimum, as dimerization protects the protein from further proteolysis. The combination of glutathione-agarose, phenyl-superose and Ni/nitrilotriacetate affinity chromatography allows rapid and selective purification of the desired subunit combination. Truncated forms of p51 are efficiently removed. Mobility-shift assay revealed that the preparations are free of p66 homodimer. In a successful test of the novel expression system, mixed reconstituted RTs with p51 selectively mutated in a putative nucleic acid binding motif (the so called helix clamp) show reduced binding of dsDNA in mobility-shift assays. This indicates the p51 subunit has an active role in DNA binding

Analysis of the polymerization kinetics of homodimeric EIAV p51/51 reverse transcriptase implies the formation of a polymerase active site identical to heterodimeric EIAV p66/51 reverse transcriptase

Homodimeric EIAV p51/51 and heterodimeric EIAV p66/51 reverse transcriptase were purified in order to compare the different modes of DNA synthesis supported by the enzymes. Analysis of the dimerization behavior of the EIAV enzymes indicates that the dimer stability of EIAV reverse transcriptase enzymes is higher than that of their HIV-1 reverse transcriptase counterparts. EIAV p51/51 polymerizes DNA distributively whereas DNA synthesis by EIAV p66/51 is processive. Steady-state and pre-steady-state kinetic analyses of primer/template binding and nucleotide incorporation were performed with both enzymes to determine the reasons for the different polymerization behavior. Equilibrium fluorescence titrations demonstrated that the Kd values of EIAV p51/51 for binding of DNA/DNA and DNA/RNA substrates are increased 10-fold and 28-fold, respectively, as compared to EIAV p66/51. Stopped-flow measurements with DNA/DNA show that the increase in the Kd is in part due to a 17. 4-fold higher dissociation rate constant (k-1) for EIAV p51/51. Additionally, with EIAV p51/51, kdiss is increased 7-fold for DNA/DNA and 14-fold for DNA/RNA primer/template substrates, respectively. The lack of the RNase H domain in EIAV p51/51 leads to differences in the pre-steady-state kinetics of nucleotide incorporation on DNA/DNA and DNA/RNA templates. The burst of both enzymes is composed of two phases for both substrates, and the values for the corresponding pre-steady-state burst rates, kpol1 and kpol2, are similar for both enzymes, implying the formation of identical polymerase active sites. However, the amplitudes of the two phases differ with DNA/DNA templates, indicating a different distribution between two states varying greatly in their kinetic competence.

The p51 subunit of human immunodeficiency virus type 1 reverse transcriptase is essential in loading the p66 subunit on the template primer

Human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) is a dimeric enzyme consisting of p66 and p51 subunits. The functional role of the p51 subunit remains elusive since all the catalytic functions appear to be executed through the p66 subunit. We report here that the p51 subunit, in addition to providing structural support to the p66 subunit, may be involved in facilitating the loading of the p66 subunit on to the template-primer (TP). This possibility is supported by following observations: (i) Upon binding to the TP, the p51 subunit can be dissociated by acetonitrile treatment and the template-primer-bound p66 monomer alone is capable of catalyzing DNA synthesis. (ii) Photo-cross-linking of template-primer to HIV-1 RT is abolished by dissociation of the p51 subunit prior to the TP binding but remains unaffected after the TP binding step. (iii) The p66-TP covalent complex selectively generated by UV irradiation and separated by gel electrophoresis can incorporate a single nucleotide in situ upon its renaturation in the gel. (iv) Treatment of HIV-1 RT with (tert-butyldimethylsilyl)spiroaminooxathioledioside (TSAO), an inhibitor that specifically binds to the beta7 beta8 loop of p51, destabilizes the heterodimeric enzyme, resulting in the subsequent loss of DNA binding.

Cystatins in health and disease

Proteolytic enzymes have many physiological functions in plants, bacteria, viruses, protozoa and mammals. They play a role in processes such as food digestion, complement activation or blood coagulation. The action of proteolytic enzymes is biologically controlled by proteinase inhibitors and increasing attention is being paid to the physiological significance of these natural inhibitors in pathological processes. The reason for this growing interest is that uncontrolled proteolysis can lead to irreversible damage e.g. in chronic inflammation or tumor metastasis. This review focusses on the possible role of the cystatins, natural and specific inhibitors of the cysteine proteinases, in pathological processes.

Recombinant human immunodeficiency virus type 1 reverse transcriptase is heterogeneous

Recombinant wild type (wt) and T215Y HIV-1 reverse transcriptase (RT) were isolated using three methods designated A, B, and C. The three samples of wt RT were kinetically indistinguishable with respect to dTTP turnover on poly(rA).p(dT)10. However, whereas the kinetic constants for dTTP and AZTTP for both T215Y B and T215Y C were similar to those of wt protein, T215Y A exhibited a twofold increase in Km value for dTTP and a 13-fold increase in Ki value for AZTTP with respect to wt protein purified in the same manner. We further investigated this observation by studying the denaturation of wt RT by urea. The urea denaturation curves monitored by fluorescence and circular dichroism spectroscopy were not coincident with the denaturation curve monitored by enzyme activity and yielded Cm values (the concentration of urea at which 50% of the protein is denatured) of 4.1 and 2.0 M urea, respectively. The noncoincidence of the transition curves reflects two separable, sequential, noncooperative conformational changes in the molecule: (a) from a catalytically active to an inactive conformation, and (b) from a catalytically inactive to a denatured, unfolded conformation. We therefore used denaturation as detected by changes in enzyme activity to compare the conformational stability of the three samples of wt and T215Y RT A, B, and C. The Cm values for T215Y RT did not differ from those of the respective wt; however, differences in Cm values were noted depending on how the protein was isolated. This suggested that the heterogeneity of the recombinant RT was due to small differences in conformation at or near the active site.

Interface peptides as structure-based human immunodeficiency virus reverse transcriptase inhibitors

Reverse transcriptases from both human immunodeficiency viruses type 1 and 2 are obligatory dimers. A tryptophan-rich repeat motif that is highly conserved between these proteins, as well as in the reverse transcriptase from simian immunodeficiency virus, has been postulated to be involved in hydrophobic subunit interactions. A synthetic 19-mer peptide covering part of this tryptophan repeat motif was recently shown to inhibit human immunodeficiency viruses type 1 reverse transcriptase subunit dimerization (Divita, G., Restle, T., Goody, R. S., Chermann, J.-C., and Baillon, J. G. (1994) J. Biol. Chem. 269, 13080-13083). In the present study, we show that the same peptide can also inhibit human immunodeficiency virus type 2 reverse transcriptase subunit dimerization, suggesting that the same inhibitors might be used as agents against both viruses as well as against variants of human immunodeficiency virus type 1 that differ from the variant against which they were developed. Under appropriate experimental conditions, e.g. at acidic pH, this peptide is also able to induce the dissociation of the enzyme from human immunodeficiency virus type 1.

Human immunodeficiency virus-1 reverse transcriptase heterodimer stability

Structural and biochemical evidence strongly supports a heterodimeric (p66p51) active form for human immunodeficiency virus-1 reverse transcriptase (RT). Heterodimer stability was examined by sedimentation analysis as a function of temperature and ionic strength. Using NONLIN regression software, monomer-dimer-trimer and monomer-dimer-tetramer association models gave the best fit to the analytical ultracentrifuge sedimentation equilibrium data. The heterodimer is the predominant form of RT at 5 degrees C, with a dimerization Ka value of 5.2 x 10(5) M-1 for both models. Ka values of 2.1 x 10(5) and 3.8 x 10(5) M-1 were obtained for the respective association models at 20 degrees C. RT in 50 and 100 mM Tris, pH 7.0, completely dissociates at 37 degrees C and behaves as an ideal monomeric species. The dissociation of RT as a function of increasing temperature was also observed by measuring the decrease in sedimentation velocity (sw,20). If the stabilization of the heterodimer was due primarily to hydrophobic interactions we would anticipate an increase in the association from 21 degrees C to 37 degrees C. The opposite temperature dependence for the association of RT suggests that electrostatic and hydrogen bond interactions play an important role in stabilizing heterodimers. To examine the effect of ionic strength on p66p51 association we determined the changes in sw,20 as a function of NaCl concentration. There is a sharp decrease in sw,20 between 0.10 and 0.5 M NaCl, leading to apparent complete dissociation. The above results support a major role for electrostatic interactions in the stabilization of the RT heterodimer.

Site-directed mutagenesis of HIV reverse transcriptase to probe enzyme processivity and drug binding

Site-directed mutagenesis has demonstrated that changes within the human immunodeficiency virus reverse transcriptase coding sequence alone can account for viral resistance to inhibitors. Inhibitor sensitivity of mutant enzymes in vitro correlates with the sensitivity of the virus to non-nucleoside inhibitors observed in vivo, but this is not the case with nucleoside analogs. Recent structural, kinetic, and site-directed mutagenesis studies demonstrate the importance of enzyme-nucleic acid contacts in determining enzyme sensitivity to inhibitors in vitro, as well as how accurately the reverse transcriptase synthesizes DNA.

Structural basis of asymmetry in the human immunodeficiency virus type 1 reverse transcriptase heterodimer

The reverse transcriptase from human immunodeficiency virus type 1 is a heterodimer consisting of one 66-kDa and one 51-kDa subunit. The p66 subunit contains both a polymerase and an RNase H domain; proteolytic cleavage of p66 removes the RNase H domain to yield the p51 subunit. Although the polymerase domain of p66 folds into an open, extended structure containing a large active-site cleft, that of p51 is closed and compact. The connection subdomain, which lies between the polymerase and RNase H active sites in p66, plays a central role in the formation of the reverse transcriptase heterodimer. Extensive and very different intra- and intersubunit contacts are made by the connection subdomains of each of the subunits. Together, contacts between the two connection domains constitute approximately one-third of the total contacts between subunits of the heterodimer. Conversion of an open p66 polymerase domain structure to a closed p51-like structure results in a reduction in solvent-accessible surface area by 1600 A2 and the burying of an extensive hydrophobic surface. Thus, the monomeric forms of both p66 and p51 are proposed to have the same closed structure as seen in the p51 subunit of the heterodimer. The free energy required to convert p66 from a closed p51-like structure to the observed open p66 polymerase domain structure is generated by the burying of a large, predominantly hydrophobic surface area upon formation of the heterodimer. It is likely that the only kind of dimer that can form is an asymmetric one like that seen in the heterodimer structure, since one dimer interaction surface exists only in p51 and the other only in p66. We suggest that both p51 and p66 form asymmetric homodimers that are assembled from one subunit that has assumed the open conformation and one that has the closed structure.