Analysis of AgoshRNA maturation and loading into Ago2

The RNA interference (RNAi) pathway was recently expanded by the discovery of multiple alternative pathways for processing of natural microRNA (miRNA) and man-made short hairpin RNA (shRNA) molecules. One non-canonical pathway bypasses Dicer cleavage and requires instead processing by Argonaute2 (Ago2), which also executes the subsequent silencing step. We named these molecules AgoshRNA, which generate only a single active RNA strand and thus avoid off-target effects that can be induced by the passenger strand of a regular shRNA. Previously, we characterized AgoshRNA processing by deep sequencing and demonstrated that—after Ago2 cleavage—AgoshRNAs acquire a short 3’ tail of 1–3 A-nucleotides and are subsequently trimmed, likely by the poly(A)-specific ribonuclease (PARN). As a result, the mature single-stranded AgoshRNA may dock more stably into Ago2. Here we set out to analyze the activity of different synthetic AgoshRNA processing intermediates. Ago2 was found to bind preferentially to partially single-stranded AgoshRNA in vitro. In contrast, only the double-stranded AgoshRNA precursor associated with Ago2 in cells, correlating with efficient intracellular processing and reporter knockdown activity. These results suggest the presence of a cellular co-factor involved in AgoshRNA loading into Ago2 in vivo. We also demonstrate specific AgoshRNA loading in Ago2, but not Ago1/3/4, thus further reducing unwanted side effects.

Structural and mechanistic insights into an archaeal DNA-guided Argonaute protein

Argonaute (Ago) proteins in eukaryotes are known as key players in post-transcriptional gene silencing¹, while recent studies on prokaryotic Agos hint at their role in the protection against invading DNA^2,3. Here, we present crystal structures of the apo enzyme and a binary Ago-guide complex of the archaeal Methanocaldococcus jannaschii (Mj) Ago. Binding of a guide DNA leads to large structural rearrangements. This includes the structural transformation of a hinge region containing a switch helix, which has been shown for human Ago2 to be critical for the dynamic target search process^4-6. To identify key residues crucial for MjAgo function, we analysed the effect of several MjAgo mutants. We observe that the nature of the 3' and 5' nucleotides in particular, as well as the switch helix, appear to impact MjAgo cleavage activity. In summary, we provide insights into the molecular mechanisms that drive DNA-guided DNA silencing by an archaeal Ago.

Mechanistic Insights into Archaeal and Human Argonaute Substrate Binding and Cleavage Properties

Argonaute (Ago) proteins from all three domains of life are key players in processes that specifically regulate cellular nucleic acid levels. Some of these Ago proteins, among them human Argonaute2 (hAgo2) and Ago from the archaeal organism Methanocaldococcus jannaschii (MjAgo), are able to cleave nucleic acid target strands that are recognised via an Ago-associated complementary guide strand. Here we present an in-depth kinetic side-by-side analysis of hAgo2 and MjAgo guide and target substrate binding as well as target strand cleavage, which enabled us to disclose similarities and differences in the mechanistic pathways as a function of the chemical nature of the substrate. Testing all possible guide-target combinations (i.e. RNA/RNA, RNA/DNA, DNA/RNA and DNA/DNA) with both Ago variants we demonstrate that the molecular mechanism of substrate association is highly conserved among archaeal-eukaryotic Argonautes. Furthermore, we show that hAgo2 binds RNA and DNA guide strands in the same fashion. On the other hand, despite striking homology between the two Ago variants, MjAgo cannot orientate guide RNA substrates in a way that allows interaction with the target DNA in a cleavage-compatible orientation.

Dissecting genetics of cutaneous miRNA in a mouse model of an autoimmune blistering disease

BACKGROUND

MicroRNAs (miRNAs) are small endogenous non-coding RNAs that control genes at post-transcriptional level. They are essential for development and tissue differentiation, and such altered miRNA expression patterns are linked to the pathogenesis of inflammation and cancer. There is evidence that miRNA expression is genetically controlled similar to the transcription of protein-coding genes and previous studies identified quantitative trait loci (QTL) for miRNA expression in the liver. So far, little attention has been paid to miRNA expression in the skin. Moreover, epistatic control of miRNA expression remains unknown. In this study, we characterize genetic regulation of cutaneous miRNA and their correlation with skin inflammation using a previously established murine autoimmune-prone advanced intercross line.

RESULTS

We identified in silico 42 eQTL controlling the expression of 38 cutaneous miRNAs and furthermore found two chromosomal hot-spots on chromosomes 2 and 8 that control the expression of multiple miRNAs. Moreover, for 8 miRNAs an interacting effect from pairs of SNPs was observed. Combining the constraints on genes from the statistical interaction of their loci and further using curated protein interaction networks, the number of candidate genes for association of miRNAs was reduced to a set of several genes. A cluster analysis identified miR-379 and miR-223 to be associated with EBA severity/onset, where miR-379 was observed to be associated to loci on chromosome 6.

CONCLUSION

The murine advanced intercross line allowed us to identify the genetic loci regulating multiple miRNA in skin. The recurrence of trans-eQTL and epistasis suggest that cutaneous miRNAs are regulated by yet an unexplored complex gene networks. Further, using co-expression analysis of miRNA expression levels we showed that multiple miRNA contribute to multiple pathways that might be involved in pathogenesis of autoimmune skin blistering disease. Specifically, we provide evidence that miRNA such as miR-223 and miR-379 may play critical role in disease progression and severity.

FRET-based assay to screen inhibitors of HIV-1 reverse transcriptase and nucleocapsid protein

During HIV-1 reverse transcription, the single-stranded RNA genome is converted into proviral double stranded DNA by Reverse Transcriptase (RT) within a reverse transcription complex composed of the genomic RNA and a number of HIV-1 encoded proteins, including the nucleocapsid protein NCp7. Here, we developed a one-step and one-pot RT polymerization assay. In this in vitro assay, RT polymerization is monitored in real-time by Förster resonance energy transfer (FRET) using a commercially available doubly-labeled primer/template DNA. The assay can monitor and quantify RT polymerization activity as well as its promotion by NCp7. Z-factor values as high as 0.89 were obtained, indicating that the assay is suitable for high-throughput drug screening. Using Nevirapine and AZT as prototypical RT inhibitors, reliable IC50 values were obtained from the changes in the RT polymerization kinetics. Interestingly, the assay can also detect NCp7 inhibitors, making it suitable for high-throughput screening of drugs targeting RT, NCp7 or simultaneously, both proteins.

Novel Insights into Guide RNA 5'-Nucleoside/Tide Binding by Human Argonaute 2

The human Argonaute 2 (hAgo2) protein is a key player of RNA interference (RNAi). Upon complex formation with small non-coding RNAs, the protein initially interacts with the 5'-end of a given guide RNA through multiple interactions within the MID domain. This interaction has been reported to show a strong bias for U and A over C and G at the 5'-position. Performing molecular dynamics simulations of binary hAgo2/OH-guide-RNA complexes, we show that hAgo2 is a highly flexible protein capable of binding to guide strands with all four possible 5'-bases. Especially, in the case of C and G this is associated with rather large individual conformational rearrangements affecting the MID, PAZ and even the N-terminal domains to different degrees. Moreover, a 5'-G induces domain motions in the protein, which trigger a previously unreported interaction between the 5'-base and the L2 linker domain. Combining our in silico analyses with biochemical studies of recombinant hAgo2, we find that, contrary to previous observations, hAgo2 is capable of functionally accommodating guide strands regardless of the 5'-base.

RNAi revised--target mRNA-dependent enhancement of gene silencing

The discovery of RNA interference (RNAi) gave rise to the development of new nucleic acid-based technologies as powerful investigational tools and potential therapeutics. Mechanistic key details of RNAi in humans need to be deciphered yet, before such approaches take root in biomedicine and molecular therapy.

We developed and validated an in silico-based model of siRNA-mediated RNAi in human cells in order to link in vitro-derived pre-steady state kinetic data with a quantitative and time-resolved understanding of RNAi on the cellular level. The observation that product release by Argonaute 2 is accelerated in the presence of an excess of target RNA in vitro inspired us to suggest an associative mechanism for the RNA slicer reaction where incoming target mRNAs actively promote dissociation of cleaved mRNA fragments. This novel associative model is compatible with high multiple turnover rates of RNAi-based gene silencing in living cells and accounts for target mRNA concentration-dependent enhancement of the RNAi machinery.

Reverse Transcriptase in Action: FRET-Based Assay for Monitoring Flipping and Polymerase Activity in Real Time

Reverse transcriptase (RT) of human immunodeficiency virus-1 (HIV-1) is a multifunctional enzyme that catalyzes the conversion of the single stranded viral RNA genome into double-stranded DNA, competent for host-cell integration. RT is endowed with RNA- and DNA-dependent DNA polymerase activity and DNA-directed RNA hydrolysis (RNase H activity). As a key enzyme of reverse transcription, RT is a key target of currently used highly active antiretroviral therapy (HAART), though RT inhibitors offer generally a poor resistance profile, urging new RT inhibitors to be developed. Using single molecule fluorescence approaches, it has been recently shown that RT binding orientation and dynamics on its substrate play a critical role in its activity. Currently, most in vitro RT activity assays, inherently end-point measurements, are based on the detection of reaction products by using radio-labeled or chemically modified nucleotides. Here, we propose a simple and continuous real-time Förster resonance energy transfer (FRET) based-assay for the direct measurement of RT's binding orientation and polymerase activity, with the use of conventional steady-state fluorescence spectroscopy. Under our working conditions, the change in binding orientation and the primer elongation step can be visualized separately on the basis of their opposite fluorescence changes and their different kinetics. The assay presented can easily discriminate non-nucleoside RT inhibitors from nucleoside RT inhibitors and determine reliably their potency. This one-step and one-pot assay constitutes an improved alternative to the currently used screening assays to disclose new anti-RT drugs and identify at the same time the class to which they belong.

ptRNApred: computational identification and classification of post-transcriptional RNA

Non-coding RNAs (ncRNAs) are known to play important functional roles in the cell. However, their identification and recognition in genomic sequences remains challenging. In silico methods, such as classification tools, offer a fast and reliable way for such screening and multiple classifiers have already been developed to predict well-defined subfamilies of RNA. So far, however, out of all the ncRNAs, only tRNA, miRNA and snoRNA can be predicted with a satisfying sensitivity and specificity. We here present ptRNApred, a tool to detect and classify subclasses of non-coding RNA that are involved in the regulation of post-transcriptional modifications or DNA replication, which we here call post-transcriptional RNA (ptRNA). It (i) detects RNA sequences coding for post-transcriptional RNA from the genomic sequence with an overall sensitivity of 91% and a specificity of 94% and (ii) predicts ptRNA-subclasses that exist in eukaryotes: snRNA, snoRNA, RNase P, RNase MRP, Y RNA or telomerase RNA.

AVAILABILITY

The ptRNApred software is open for public use on http://www.ptrnapred.org/.

A toolkit and benchmark study for FRET-restrained high-precision structural modeling

We present a comprehensive toolkit for Förster resonance energy transfer (FRET)-restrained modeling of biomolecules and their complexes for quantitative applications in structural biology. A dramatic improvement in the precision of FRET-derived structures is achieved by explicitly considering spatial distributions of dye positions, which greatly reduces uncertainties due to flexible dye linkers. The precision and confidence levels of the models are calculated by rigorous error estimation. The accuracy of this approach is demonstrated by docking a DNA primer-template to HIV-1 reverse transcriptase. The derived model agrees with the known X-ray structure with an r.m.s. deviation of 0.5 Å. Furthermore, we introduce FRET-guided 'screening' of a large structural ensemble created by molecular dynamics simulations. We used this hybrid approach to determine the formerly unknown configuration of the flexible single-strand template overhang.

A protein ballet around the viral genome orchestrated by HIV-1 reverse transcriptase leads to an architectural switch: from nucleocapsid-condensed RNA to Vpr-bridged DNA

HIV-1 reverse transcription is achieved in the newly infected cell before viral DNA (vDNA) nuclear import. Reverse transcriptase (RT) has previously been shown to function as a molecular motor, dismantling the nucleocapsid complex that binds the viral genome as soon as plus-strand DNA synthesis initiates. We first propose a detailed model of this dismantling in close relationship with the sequential conversion from RNA to double-stranded (ds) DNA, focusing on the nucleocapsid protein (NCp7). The HIV-1 DNA-containing pre-integration complex (PIC) resulting from completion of reverse transcription is translocated through the nuclear pore. The PIC nucleoprotein architecture is poorly understood but contains at least two HIV-1 proteins initially from the virion core, namely integrase (IN) and the viral protein r (Vpr). We next present a set of electron micrographs supporting that Vpr behaves as a DNA architectural protein, initiating multiple DNA bridges over more than 500 base pairs (bp). These complexes are shown to interact with NCp7 bound to single-stranded nucleic acid regions that are thought to maintain IN binding during dsDNA synthesis, concurrently with nucleocapsid complex dismantling. This unexpected binding of Vpr conveniently leads to a compacted but filamentous folding of the vDNA that should favor its nuclear import. Finally, nucleocapsid-like aggregates engaged in dsDNA synthesis appear to efficiently bind to F-actin filaments, a property that may be involved in targeting complexes to the nuclear envelope. More generally, this article highlights unique possibilities offered by in vitro reconstitution approaches combined with macromolecular imaging to gain insights into the mechanisms that alter the nucleoprotein architecture of the HIV-1 genome, ultimately enabling its insertion into the nuclear chromatin.

Noncovalent peptide-mediated delivery of chemically modified steric block oligonucleotides promotes splice correction: quantitative analysis of uptake and biological effect

Despite numerous encouraging reports in the literature, the efficiency of cell penetrating peptides (CPPs) in promoting cellular delivery of bioactive cargos is still limited. To extend our current understanding of the underlying limitations of such approaches, we performed quantitative uptake studies of different chemically modified (2'-O-methyl, LNA and PNA) steric block oligonucleotides, targeted against a mutated splice site inserted in a firefly luciferase reporter gene construct, applying the peptide carrier MPGalpha as a model system. The peptide formed stable noncovalent complexes with phosphorothioate oligonucleotide (PTO) and locked nucleic acid (LNA) modified oligonucleotides, whereas the neutral peptide nucleic acid (PNA) had to be hybridized to an unmodified DNA to allow for complex formation. Detailed quantitative uptake studies revealed comparable numbers of intracellular PTO and LNA oligonucleotides after peptide-mediated delivery. Surprisingly, the PTO derivative showed the strongest upregulation of reporter gene activity of about 100-fold followed by the PNA (40-fold) and LNA (10-fold). Electroporation and microinjection studies proved that delivery itself was not the limiting factor for the low activity of the LNA derivative. Maximal achievable reporter gene activity could be observed only after addition of chloroquine (CQ), indicative of an endosomal pathway involved. This is in line with nuclear microinjection experiments, which show that the minimal number of steric block molecules needed to trigger the observed reporter upregulation is about two orders of magnitude lower than determined after peptide or cationic lipid delivery.

Peptide-mediated cellular delivery of oligonucleotide-based therapeutics in vitro: quantitative evaluation of overall efficacy employing easy to handle reporter systems

Cellular uptake of therapeutic oligonucleotides and subsequent intracellular trafficking to their target sites represents the major technical hurdle for the biological effectiveness of these potential drugs. Accordingly, laboratories worldwide focus on the development of suitable delivery systems. Among the different available non-viral systems like cationic polymers, cationic liposomes and polymeric nanoparticles, cell-penetrating peptides (CPPs) represent an attractive concept to bypass the problem of poor membrane permeability of these charged macromolecules. While uptake per se in most cases does not represent the main obstacle of nucleic acid delivery in vitro, it becomes increasingly apparent that intracellular trafficking is the bottleneck. As a consequence, in order to optimize a given delivery system, a side-by-side analysis of nucleic acid cargo internalized and the corresponding biological effect is required to determine the overall efficacy. In this review, we will concentrate on peptide-mediated delivery of siRNAs and steric block oligonucleotides and discuss different methods for quantitative assessment of the amount of cargo taken up and how to correlate those numbers with biological effects by applying easy to handle reporter systems. To illustrate current limitations of non-viral nucleic acid delivery systems, we present own data as an example and discuss options of how to enhance trafficking of molecules entrapped in cellular compartments.

HIV-1 nucleocapsid traps reverse transcriptase on nucleic acid substrates

Conversion of the genomic RNA of human immunodeficiency virus (HIV) into full-length viral DNA is a complex multistep reaction catalyzed by the reverse transcriptase (RT). Numerous studies have shown that the viral nucleocapsid (NC) protein has a vital impact on various steps during reverse transcription, which is crucial for virus infection. However, the exact molecular details are poorly defined. Here, we analyzed the effect of NC on RT-catalyzed single-turnover, single-nucleotide incorporation using different nucleic acid substrates. In the presence of NC, we observed an increase in the amplitude of primer extension of up to 3-fold, whereas the transient rate of nucleotide incorporation ( k pol) dropped by up to 50-fold. To unravel the underlying molecular mechanism, we carefully analyzed the effect of NC on RT-nucleic acid substrate dissociation. The studies revealed that NC considerably enhances the stability of RT-substrate complexes by reducing the observed dissociation rate constants, which more than compensates for the observed drop in k pol. In conclusion, our data strongly support the concept that NC not only indirectly assists the reverse transcription process by its nucleic acid chaperoning activity but also positively affects the RT-catalyzed nucleotide incorporation reaction by increasing polymerase processivity presumably via a physical interaction of the two viral proteins.

Varied active-site constraints in the klenow fragment of E. coli DNA polymerase I and the lesion-bypass Dbh DNA polymerase

We report on comparative pre-steady-state kinetic analyses of exonuclease-deficient Escherichia coli DNA polymerase I (Klenow fragment, KF-) and the archaeal Y-family DinB homologue (Dbh) of Sulfolobus solfataricus. We used size-augmented sugar-modified thymidine-5'-triphosphate (T(R)TP) analogues to test the effects of steric constraints in the active sites of the polymerases. These nucleotides serve as models for study of DNA polymerases exhibiting both relatively high and low intrinsic selectivity. Substitution of a hydrogen atom at the 4'-position in the nucleotide analogue by a methyl group reduces the maximum rate of nucleotide incorporation by about 40-fold for KF- and about twelve fold for Dbh. Increasing the size to an ethyl group leads to a further twofold reduction in the rates of incorporation for both enzymes. Interestingly, the affinity of KF- for the modified nucleotides is only marginally affected, which would indicate no discrimination during the binding step. Dbh even has a higher affinity for the modified analogues than it does for the natural substrate. Misincorporation of either TTP or T(Me)TP opposite a G template causes a drastic decline in incorporation rates for both enzymes. At the same time, the binding affinities of KF- for these nucleotides drop by about 16- and fourfold, respectively, whereas Dbh shows only a twofold reduction. Available structural data for ternary complexes of relevant DNA polymerases indicate that both enzymes make close contacts with the sugar moiety of the dNTP. Thus, the varied proficiencies of the two enzymes in processing the size-augmented probes indicate varied flexibility of the enzymes' active sites and support the notion of active site tightness being a criterion for DNA polymerase selectivity.

Opposed steric constraints in human DNA polymerase beta and E. coli DNA polymerase I

DNA polymerase selectivity is crucial for the survival of any living species, yet varies significantly among different DNA polymerases. Errors within DNA polymerase-catalyzed DNA synthesis result from the insertion of noncanonical nucleotides and extension of misaligned DNA substrates. The substrate binding characteristics among DNA polymerases are believed to vary in properties such as shape and tightness of the binding pocket, which might account for the observed differences in fidelity. Here, we employed 4'-alkylated nucleotides and primer strands bearing 4'-alkylated nucleotides at the 3'-terminal position as steric probes to investigate differential active site properties of human DNA polymerase beta (Pol beta) and the 3'-->5'-exonuclease-deficient Klenow fragment of E. coli DNA polymerase I (KF(exo-)). Transient kinetic measurements indicate that both enzymes vary significantly in active site tightness at both positions. While small 4'-methyl and -ethyl modifications of the nucleoside triphosphate perturb Pol beta catalysis, extension of modified primer strands is only marginally affected. Just the opposite was observed for KF(exo-). Here, incorporation of the modified nucleotides is only slightly reduced, whereas size augmentation of the 3'-terminal nucleotide in the primer reduces the catalytic efficiency by more than 7000- and 260,000-fold, respectively. NMR studies support the notion that the observed effects derive from enzyme substrate interactions rather than inherent properties of the modified substrates. These findings are consistent with the observed differential capability of the investigated DNA polymerases in fidelity such as processing misaligned DNA substrates. The results presented provide direct evidence for the involvement of varied steric effects among different DNA polymerases on their fidelity.

Recent developments in peptide-based nucleic acid delivery

Despite the fact that non-viral nucleic acid delivery systems are generally considered to be less efficient than viral vectors, they have gained much interest in recent years due to their superior safety profile compared to their viral counterpart. Among these synthetic vectors are cationic polymers, branched dendrimers, cationic liposomes and cell-penetrating peptides (CPPs). The latter represent an assortment of fairly unrelated sequences essentially characterised by a high content of basic amino acids and a length of 10–30 residues. CPPs are capable of mediating the cellular uptake of hydrophilic macromolecules like peptides and nucleic acids (e.g. siRNAs, aptamers and antisense-oligonucleotides), which are internalised by cells at a very low rate when applied alone. Up to now, numerous sequences have been reported to show cell-penetrating properties and many of them have been used to successfully transport a variety of different cargos into mammalian cells. In recent years, it has become apparent that endocytosis is a major route of internalisation even though the mechanisms underlying the cellular translocation of CPPs are poorly understood and still subject to controversial discussions. In this review, we will summarise the latest developments in peptide-based cellular delivery of nucleic acid cargos. We will discuss different mechanisms of entry, the intracellular fate of the cargo, correlation studies of uptake versus biological activity of the cargo as well as technical problems and pitfalls.

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.

Aptamer displacement identifies alternative small-molecule target sites that escape viral resistance

Aptamers targeting reverse transcriptase (RT) from HIV-1 inhibit viral replication in vitro, presumably by competing with binding of the primer/template complex. This site is not targeted by the currently available small-molecule anti-HIV-1 RT inhibitors. We have identified SY-3E4, a small-molecule inhibitor of HIV-1 RT, by applying a screening assay that utilizes a reporter-ribozyme regulated by the anti-HIV-1 RT aptamer. SY-3E4 displaces the aptamer from the protein, selectively inhibits DNA-dependent, but not RNA-dependent, polymerase activity, and inhibits the replication of both the wild-type virus and a multidrug-resistant strain. Analysis of available structural data of HIV-1 and HIV-2 RTs rationalizes many of the observed characteristics of the inhibitory profiles of SY-3E4 and the aptamer and suggests a previously not considered region in these RTs as a target for antiviral therapy. Our study reveals unexplored ways for rapidly identifying alternative small-molecule target sites in proteins and illustrates strategies for overcoming resistance-conferring mutations with small molecules.

HIV-1 protease and reverse transcriptase control the architecture of their nucleocapsid partner

The HIV-1 nucleocapsid is formed during protease (PR)-directed viral maturation, and is transformed into pre-integration complexes following reverse transcription in the cytoplasm of the infected cell. Here, we report a detailed transmission electron microscopy analysis of the impact of HIV-1 PR and reverse transcriptase (RT) on nucleocapsid plasticity, using in vitro reconstitutions. After binding to nucleic acids, NCp15, a proteolytic intermediate of nucleocapsid protein (NC), was processed at its C-terminus by PR, yielding premature NC (NCp9) followed by mature NC (NCp7), through the consecutive removal of p6 and p1. This allowed NC co-aggregation with its single-stranded nucleic-acid substrate. Examination of these co-aggregates for the ability of RT to catalyse reverse transcription showed an effective synthesis of double-stranded DNA that, remarkably, escaped from the aggregates more efficiently with NCp7 than with NCp9. These data offer a compelling explanation for results from previous virological studies that focused on i) Gag processing leading to nucleocapsid condensation, and ii) the disappearance of NCp7 from the HIV-1 pre-integration complexes. We propose that HIV-1 PR and RT, by controlling the nucleocapsid architecture during the steps of condensation and dismantling, engage in a successive nucleoprotein-remodelling process that spatiotemporally coordinates the pre-integration steps of HIV-1. Finally we suggest that nucleoprotein remodelling mechanisms are common features developed by mobile genetic elements to ensure successful replication.

Cellular delivery of small interfering RNA by a non-covalently attached cell-penetrating peptide: quantitative analysis of uptake and biological effect

Cell-penetrating peptides (CPPs) have evolved as promising new tools to deliver nucleic acids into cells. So far, the majority of these delivery systems require a covalent linkage between carrier and cargo. To exploit the higher flexibility of a non-covalent strategy, we focused on the characterisation of a novel carrier peptide termed MPGα, which spontaneously forms complexes with nucleic acids. Using a luciferase-targeted small interfering RNA (siRNA) as cargo, we optimised the conditions for MPGα-mediated transfection of mammalian cells. In this system, reporter gene activity could be inhibited up to 90% with an IC₅₀ value in the sub-nanomolar range. As a key issue, we addressed the cellular uptake mechanism of MPGα/siRNA complexes applying various approaches. First, transfection of HeLa cells with MPGα/siRNA complexes in the presence of several inhibitors of endocytosis showed a significant reduction of the RNA interference (RNAi) effect. Second, confocal laser microscopy revealed a punctual intracellular pattern rather than a diffuse distribution of fluorescently labelled RNA-cargo. These data provide strong evidence of an endocytotic pathway contributing significantly to the uptake of MPGα/siRNA complexes. Finally, we quantified the intracellular number of siRNA molecules after MPGα-mediated transfection. The amount of siRNA required to induce half maximal RNAi was 10 000 molecules per cell. Together, the combination of methods provided allows for a detailed side by side quantitative analysis of cargo internalisation and related biological effects. Thus, the overall efficiency of a given delivery technique as well as the mechanism of uptake can be assessed.

Specific binding of a hexanucleotide to HIV-1 reverse transcriptase: a novel class of bioactive molecules

Short oligonucleotides below 8–10 nt in length adopt relatively simple structures. Accordingly, they represent interesting and so far unexplored lead compounds as molecular tools and, potentially, for drug development as a rational improvement of efficacy seem to be less complex than for other classes of longer oligomeric nucleic acid. As a ‘proof of concept’, we describe the highly specific binding of the hexanucleotide UCGUGU (Hex-S3) to human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) as a model target. Ultraviolet (UV) cross-linking studies and competition experiments with primer/template substrates and a RT-directed aptamer suggest site-specific binding of Hex-S3 to the large subunit (p66) of the viral enzyme. The affinity of 5.3 μM is related to hexanucleotide-specific suppression of HIV-1 replication in human cells by up to three orders of magnitude indicating that Hex-S3 exerts specific and biologically relevant activity. Experimental evidence described here further suggests a systematic hexamer array-based search for new tools for molecular biology and novel lead compounds in nucleic acid-based drug development.

Biochemical and pre-steady-state kinetic characterization of the hepatitis C virus RNA polymerase (NS5BDelta21, HC-J4)

Here we report a detailed characterization of the biochemical and kinetic properties of the hepatitis C virus (HCV, genotype-1b, J4 consensus) RNA-dependent RNA polymerase NS5B, by performing comprehensive RNA binding, nucleotide incorporation, and protein/protein oligomerization studies. By applying equilibrium fluorescence titrations, we determined a surprisingly high dissociation constant (K(d)) of approximately 250 nM for single-stranded as well as for partially double-stranded RNA. A detailed analysis of the nucleic acid binding mechanism using pre-steady-state techniques revealed the association reaction to be nearly diffusion controlled. It occurs in a single step with a second-order rate constant (k(on)) of 0.273 nM(-)(1) s(-)(1). The dissociation of the nucleic acid-polymerase complex is fast with a dissociation rate constant (k(off)) of 59.3 s(-)(1). With short, partially double-stranded RNAs, no nucleotide incorporation could be observed, while de novo RNA synthesis with short RNA templates showed nucleotide incorporation and end-to-end template switching events. Single-turnover, single-nucleotide incorporation studies (representing here the initiation and not processive polymerization) using dinucleotide primers revealed a very slow incorporation rate (k(pol)) of 0.0007 s(-)(1) and a K(d) of the binary enzyme-nucleic acid complex for the incoming ATP of 27.7 microM. Using dynamic laser light scattering, it could be shown for the first time that oligomerization of HCV NS5B is a dynamic and monovalent salt concentration dependent process. While NS5B is highly oligomeric at low salt concentrations, monomers were only observed at NaCl concentrations above 300 mM. Binding of short RNA substrates led to a further increase in oligomerization, whereas GTP did not show any effect on protein/protein interactions. Furthermore, nucleotide incorporation studies indicate the oligomerization state does not correlate with enzymatic activities as previously proposed.

Pre-steady-state kinetic characterization of the DinB homologue DNA polymerase of Sulfolobus solfataricus

Equilibrium as well as pre-steady-state measurements were performed to characterize the molecular basis of DNA binding and nucleotide incorporation by the thermostable archaeal DinB homologue (Dbh) DNA polymerase of Sulfolobus solfataricus. Equilibrium titrations show a DNA binding affinity of about 60 nm, which is approximately 10-fold lower compared with other DNA polymerases. Investigations of the binding kinetics applying stopped-flow and pressure jump techniques confirm this weak binding affinity. Furthermore, these measurements suggest that the DNA binding occurs in a single step, diffusion-controlled manner. Single-turnover, single dNTP incorporation studies reveal maximal pre-steady-state burst rates of 0.64, 2.5, 3.7, and 5.6 s(-1) for dTTP, dATP, dGTP, and dCTP (at 25 degrees C), which is 10-100-fold slower than the corresponding rates of classical DNA polymerases. Another unique feature of the Dbh is the very low nucleotide binding affinity (K(d) approximately 600 mum), which again is 10-20-fold lower compared with classical DNA polymerases as well as other Y-family polymerases. Surprisingly, the rate-limiting step of nucleotide incorporation (correct and incorrect) is the chemical step (phosphoryl transfer) and not a conformational change of the enzyme. Thus, unlike replicative polymerases, an "induced fit" mechanism to select and incorporate nucleotides during DNA polymerization could not be detected for Dbh.

Insight into the Mechanism of a Peptide Inhibitor of HIV Reverse Transcriptase Dimerization

The biologically active forms of human immunodeficiency viruses type 1 and 2 reverse transcriptase (RT) found in infectious virions are heterodimers. We have previously shown that the dimeric nature of reverse transcriptase represents an important target for the design of a new class of antiviral agents and have designed a short peptide (Pep-7) derived from the tryptophan-rich motif of the connection subdomain that blocks dimerization of reverse transcriptase in vitro and abolishes viral infection. In the present work, we have investigated the mechanism through which this peptide inhibits RT dimerization and consequently viral propagation. We demonstrate that Pep-7 interacts preferentially with the p51 subunit within the heterodimeric reverse transcriptase, which destabilizes reverse transcriptase dimer conformation, thereby triggering dissociation. We have identified two residues Trp(24) and Phe(61), located on the fingers subdomain of p51, required for Pep-7 binding. Selective mutation of these residues on p51 to a glycine dramatically alters the stability of the RT-heterodimer suggesting that the fingers subdomain of p51 is also involved in stabilization of reverse transcriptase. We propose that the binding site of Pep-7 is located in a cleft between the fingers and the connection subdomains of p51 that contains the two highly conserved residues Phe(61) and Trp(24).

DafA Cycles Between the DnaK Chaperone System and Translational Machinery

DafA is encoded by the dnaK operon of Thermus thermophilus and mediates the formation of a highly stable complex between the chaperone DnaK and its co-chaperone DnaJ under normal growth conditions. DafA(Tth) contains 87 amino acid residues and is the only member of the DnaK(Tth) chaperone system for which no corresponding protein has yet been identified in other organisms and whose particular function has remained elusive. Here, we show directly that the DnaK(Tth)-DnaJ(Tth)-DafA(Tth) complex cannot represent the active chaperone species since DafA(Tth) inhibits renaturation of firefly luciferase by suppressing substrate association. Since DafA(Tth) must be released before the substrate proteins can bind we hypothesized that free DafA(Tth) might have regulatory functions connected to the heat shock response. Here, we present evidence that supports this hypothesis. We identified the 70S ribosome as binding target of free DafA(Tth). Our results show that the association of DafA(Tth) and 70S ribosomes does not require the participation of DnaK(Tth) or DnaJ(Tth). On the contrary, the assembly of DnaK(Tth)-DnaJ(Tth)-DafA(Tth) and ribosome-DafA(Tth) complexes seems to be competitive. These findings strongly suggest the involvement of DafA(Tth) in regulatory processes occurring at a translational level, which could represent a new mechanism of heat shock response as an adaptation to elevated temperature.

Multiparameter single-molecule fluorescence spectroscopy reveals heterogeneity of HIV-1 reverse transcriptase:primer/template complexes

By using single-molecule multiparameter fluorescence detection, fluorescence resonance energy transfer experiments, and newly developed data analysis methods, this study demonstrates directly the existence of three structurally distinct forms of reverse transcriptase (RT):nucleic acid complexes in solution. Single-molecule multiparameter fluorescence detection also provides first information on the structure of a complex not observed by x-ray crystallography. This species did not incorporate nucleotides and is structurally distinct from the other two observed species. We determined that the nucleic acid substrate is bound at a site far removed from the nucleic acid-binding tract observed by crystallography. In contrast, the other two states are identified as being similar to the x-ray crystal structure and represent distinct enzymatically productive stages in DNA polymerization. These species differ by only a 5-A shift in the position of the nucleic acid. Addition of nucleoside triphosphate or of inorganic pyrophosphate allowed us to assign them as the educt and product state in the polymerization reaction cycle; i.e., the educt state is a complex in which the nucleic acid is positioned to allow nucleotide incorporation. The second RT:nucleic acid complex is the product state, which is formed immediately after nucleotide incorporation, but before RT translates to the next nucleotide.

Exploring the effects of active site constraints on HIV-1 reverse transcriptase DNA polymerase fidelity

To examine the concept of polymerase active site tightness as a criteria for DNA polymerase fidelity, we performed pre-steady-state single nucleotide incorporation kinetic analyses with sugar modified thymidine 5'-triphosphate (TTP) analogues and human immunodeficiency virus (HIV-1) reverse transcriptase (RT). The employed TTP analogues (T(R)TP) are modified at the 4'-position of the sugar moiety with alkyl groups, gradually expanding their steric demand. Introduction of a methyl group reduces the maximum rate of nucleotide incorporation by about 200-fold for RT(WT) and about 400-fold for RT(M184V). Interestingly, the affinity of RT for the modified nucleotide is only marginally affected. Increasing the size to an ethyl group leads to further reduction of the rate of incorporation and first effects on binding affinities are observed. Finally, substitution for an isopropyl group results not only in a further reduction of incorporation rates but also in a dramatic loss of binding affinity for the nucleotide analogue. By increasing the steric demand the effects on RT(M184V) in comparison with RT(WT) become progressively more pronounced. Misincorporation of either TTP or T(Me)TP opposite a template G causes additional decline in incorporation rates accompanied by a drastic decrease in binding affinities. This results in relative incorporation efficiencies [(k(pol)/K(d))(incorrect)/(k(pol)/K(d))(TTPcorrect)] of 4.1 x 10(-5) for TTP and 3.4 x 10(-6) for T(Me)TP in case of RT(WT) and 1.4 x 10(-5) for TTP and 2.9 x 10(-8) for T(Me)TP in case of RT(M184V).

Implications of active site constraints on varied DNA polymerase selectivity

DNA polymerase selectivity often varies significantly depending on the DNA polymerase. The origin of this varying error propensity is elusive. It is assumed that DNA polymerases form nucleotide binding pockets that differ in properties such as shape and tightness. We tested this prediction and studied HIV-1 RT by employment of size-augmented nucleotides and site-directed mutagenesis of the enzyme. New valuable insights into the mechanism of DNA polymerase fidelity were obtained. The presented study provides experimental evidence that variations of steric constraints within the nucleotide binding pocket of at least two DNA polymerases cause variations in nucleotide incorporation selectivity. Thus, our results support the concept of active site tightness as a causative in differential fidelity among DNA polymerases.

Endogenous expression of a high-affinity pseudoknot RNA aptamer suppresses replication of HIV-1

Aptamers, small oligonucleotides derived from an in vitro evolution process called SELEX, are promising therapeutic and diagnostic agents. Although very effective in vitro, only a few examples are available showing their potential in vivo. We have analyzed the effect of a well characterized pseudoknot RNA aptamer selected for tight binding to human immunodeficiency virus (HIV) type 1 reverse transcriptase on HIV replication. Transient intracellular expression of a chimeric RNA consisting of the human initiator tRNA(Met) (tRNA(Meti))/aptamer sequence in human 293T cells showed inhibition of HIV particle release by >75% when the cells were co-transfected with proviral HIV-1 DNA. Subsequent virus production of human T-lymphoid C8166 cells, infected with viral particles derived from co-transfected 293T cells, was again reduced by >75% as compared with the control. As the observed effects are additive, in this model for virus spread, the total reduction of HIV particle formation by transient intracellular expression of the pseudoknot RNA aptamer amounts to >95%. Low-dose HIV infection of human T cells stably expressing the aptamer did not show any virus replication over a period of 35 days. This is the first example of an RNA aptamer selected against a viral enzyme target to show powerful antiviral activity in HIV-1-permissive human T-lymphoid cell lines.

RNase H activity of HIV reverse transcriptases is confined exclusively to the dimeric forms

A method for the rapid preparation of a defined substrate to monitor RNase H activity has been developed. Using this substrate, we have investigated the RNase H activities of the different forms of recombinant HIV-1 and HIV-2 reverse transcriptase (RT) in detail. As we report here, RNase H activity is associated only with the dimeric forms (p51/p66 or p66/p66) of the enzymes.

Human immunodeficiency virus type 1 central DNA flap: dynamic terminal product of plus-strand displacement dna synthesis catalyzed by reverse transcriptase assisted by nucleocapsid protein

To terminate the reverse transcription of the human immunodeficiency virus type 1 (HIV-1) genome, a final step occurs within the center of the proviral DNA generating a 99-nucleotide DNA flap (6). This step, catalyzed by reverse transcriptase (RT), is defined as a discrete strand displacement (SD) synthesis between the first nucleotide after the central priming (cPPT) site and the final position of the central termination sequence (CTS) site. Using recombinant HIV-1 RT and a circular single-stranded DNA template harboring the cPPT-CTS sequence, we have developed an SD synthesis-directed in vitro termination assay. Elongation, strand displacement, and complete central flap behavior were analyzed using electrophoresis and electron microscopy approaches. Optimal conditions to obtain complete central flap, which ended at the CTS site, have been defined in using nucleocapsid protein (NCp), the main accessory protein of the reverse transcription complex. A full-length HIV-1 central DNA flap was then carried out in vitro. Its synthesis appears faster in the presence of the HIV-1 NCp or the T4-encoded SSB protein (gp32). Finally, a high frequency of strand transfer was shown during the SD synthesis along the cPPT-CTS site with RT alone. This reveals a local and efficient 3'-5' branch migration which emphasizes some important structural fluctuations within the flap. These fluctuations may be stabilized by the NCp chaperone activity. The biological implications of the RT-directed NCp-assisted flap synthesis are discussed within the context of reverse transcription complexes, assembly of the preintegration complexes, and nuclear import of the HIV-1 proviral DNA to the nucleus toward their chromatin targets.

Temperature-dependent equilibrium between the open and closed conformation of the p66 subunit of HIV-1 reverse transcriptase revealed by site-directed spin labelling

X-ray crystallographic studies of human immunodeficiency virus type 1 reverse transcriptase complexed with or without substrates or inhibitors show that the heterodimeric enzyme adopts distinct conformations that differ in the orientation of the so-called thumb subdomain in the large subunit. Site-directed spin labelling of mutated residue positions W24C and K287C is applied here to determine the distances between the fingers and thumb subdomains of liganded and unliganded RT in solution. The inter-spin distances of a DNA/DNA and a pseudoknot RNA complexed reverse transcriptase in solution was found to agree with the respective crystal data of the open and closed conformations. For the unliganded reverse transcriptase a temperature-dependent equilibrium between these two states was observed. The fraction of the closed conformation decreased from 95% at 313 K to 65% at 273 K. The spectral separation between the two structures was facilitated by the use of a perdeuterated ([15)N]nitroxide methane-thiosulfonate spin label.

HIV-1 reverse transcriptase-pseudoknot RNA aptamer interaction has a binding affinity in the low picomolar range coupled with high specificity

Systematic evolution of ligands by exponential enrichment (SELEX) is a powerful method for the identification of small oligonucleotides that bind with high affinity and specificity to target proteins. Such DNAs/RNAs are a new class of potential chemotherapeutics that could block the enzymatic activity of pathologically relevant proteins. We have conducted a detailed biochemical study of the interaction of human immunodeficiency virus 1 (HIV-1) reverse transcriptase (RT) with a SELEX-derived pseudoknot RNA aptamer. Electron paramagnetic resonance spectroscopy of site-directed spin-labeled RT mutants revealed that this aptamer was selected for binding to the "closed" conformation of the enzyme. Kinetic analysis showed that the RNA inhibitor bound to HIV RT in a two-step process, with association rates similar to those described for model DNA/DNA and DNA/RNA substrates. However, the dissociation of the pseudoknot RNA from RT was dramatically slower than observed for model substrates. Equilibrium binding studies revealed an extraordinarily low K(d), of about 25 pm, for the enzyme-aptamer interaction, presumably a consequence of the slow off-rates. Additionally, this pseudoknot aptamer is highly specific for HIV-1 RT, with the closely related HIV-2 enzyme showing a binding affinity close to 4 orders of magnitude lower.

Refined model for primer/template binding by HIV-1 reverse transcriptase: pre-steady-state kinetic analyses of primer/template binding and nucleotide incorporation events distinguish between different binding modes depending on the nature of the nucleic acid substrate

The kinetic mechanism of nucleic acid substrate binding and nucleotide incorporation by human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) was analysed using synthetic DNA/DNA and DNA/RNA primer/templates (p/t) without predicted secondary structures in the single-stranded region. Determination of the pre-steady-state kinetics of p/t binding by a combination of stopped-flow and quench flow methods indicate a branched binding mechanism for the HIV-1 RT/nucleic acid interaction. Analysis of p/t-RT association by stopped-flow measurements suggest a three-step binding mode with an initial second-order step followed by two isomerisation steps with rates of about 6 s(-1)and 0.5 s(-1), respectively. Determination of the rate-limiting step of the association process via single turnover, single nucleotide incorporation analysis by quench flow measurements revealed two binding events (the initial second-order step cannot be detected with this experimental set-up) with rates of 4 - 7 s(-1)and 0.4 - 0. 7 s(-1), respectively, indicating that both binding events exist in parallel. Thorough pre-steady-state analysis of single turnover, single nucleotide incorporation kinetics showed that dNTP incorporation occurs with a biphasic exponential burst followed by a linear phase. The exponential burst consists of a fast phase with rates of 20 - 60 s(-1) and a slow phase with rates of 0.5 - 2 s(-1), respectively. The relative distribution of these two burst amplitudes differs significantly depending upon which substrate is used. The DNA/RNA-RT complex shows primarily fast incorporation (>80 %) whereas less than 45 % of the DNA/DNA-RT complex incorporate dNTP rapidly. The same relative distribution of amplitudes concerning the two substrates is also found for the association process of RT and p/t. Analysis of dNTP incorporation of the preformed RT-p/t complex in the presence of a nucleic acid competitor shows no effect on the biphasic burst amplitude, however the linear phase disappears. Here, a refined model of the mechanism of RT-p/t binding is presented which is based on the suggestion that two different RT-p/t complexes are formed, i.e. a productive enzyme/substrate complex which is capable of nucleotide incorporation and a non-productive complex which has to undergo an isomerisation before dNTP incorporation can occur. In addition, binding of RT to its substrate can lead to a dead end complex that is not capable of dNTP incorporation.

Pre-steady-state kinetic characterization of RNA-primed initiation of transcription by HIV-1 reverse transcriptase and analysis of the transition to a processive DNA-primed polymerization mode

Single-turnover and equilibrium measurements were carried out to determine the basis of the apparently slow, nonprocessive polymerization reaction catalyzed by HIV-1 reverse transcriptase (RT) during transcription initiation, when both the primer and template are composed of RNA. Comparison of the binding and kinetic parameters of a 20-mer, all-RNA primer/35-mer template substrate to one identical in sequence but composed of a 20-mer, all-DNA primer/35-mer RNA template reveals striking differences. Equilibrium titrations yielded a dissociation constant (Kd) >200 nM for the RNA/RNA-RT complex which is at least 200-fold higher than that of the DNA/RNA-substrate (Kd approximately 1 nM). The affinity of the RT-RNA/RNA complex for dTTP was found to be at least 500 times lower (Kd approximately 3.4 mM) than that of the RT-DNA/RNA complex (Kd approximately 6.6 microM). The single-turnover dNTP incorporation time course using the RNA-primer substrate, the DNA-primer substrate, or a series of RNA-primer substrates preextended with one to eight deoxynucleotides showed that dNTP incorporation occurs with a biphasic exponential burst of +1 extension product, followed by a linear phase. At least three different RT-bound forms of the p/ts exist: a fast, kinetically competent form (single-turnover rate approximately 10-50 s-1); a slow form (rate approximately 0.3-1 s-1); and a form that is dead-end (no turnover). The studies further revealed that a switch to a fast, kinetically competent p/t occurs after six dNTPs are incorporated into the RNA primer, with the switch being defined as the transition from a minority to a majority of the p/t bound in the optimal manner.

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 structure of HIV-1 reverse transcriptase complexed with an RNA pseudoknot inhibitor

Small RNA pseudoknots, selected to bind human immunodeficiency virus type 1 (HIV-1) reverse transcriptase tightly, are potent inhibitors of reverse transcriptase. The co-crystal structure of reverse transcriptase complexed with a 33 nucleotide RNA pseudoknot has been determined by fitting the ligand into a high quality, 4-fold averaged 4.8 A resolution electron density map. The RNA is kinked between stems S1 and S2, thereby optimizing its contacts with subunits of the heterodimer. Its binding site extends along the cleft that lies between the polymerase and RNase H active sites, partially overlaps with that observed for duplex DNA and presumably overlaps some portion of the tRNA site. Stem S2 and loop L1 stabilize the 'closed' conformation of the polymerase through extensive electrostatic interactions with several basic residues in helix I of the p66 thumb and in the p66 fingers domain. Presumably, this RNA ligand inhibits reverse transcriptase by binding to a site that partly overlaps the primer-template binding site.

Conformational stability of dimeric HIV-1 and HIV-2 reverse transcriptases

The dissociation of dimeric reverse transcriptase (RT) of the human immunodeficiency virus (HIV) types 1 and 2 has been investigated using acetonitrile as a dissociating agent. The equilibrium transitions were monitored by combining different approaches (fluorescence spectroscopy, polymerase activity assay, and size-exclusion HPLC). The dissociation of RT induced a complete loss of polymerase activity and a 25% increase of the intrinsic fluorescence. It is fully reversible, and the midpoints of the equilibrium transition curves are dependent on the concentration of the enzyme used, suggesting a two-state transition model for the dissociation of RT in which dimers are in equilibrium with folded monomers. For both RTs, the heterodimeric form is more stable against dissociating agents and different pH than the corresponding homodimeric form. Moreover, heterodimeric HIV-2 RT exhibits a higher stability than HIV-1 RT, with a free energy of dissociation of 12.1 kcal/mol at pH 6.5 and 25 degrees C, instead of 10 kcal/mol for HIV-1 RT. The binding of a primer/template induces a marked conformational change in both RTs, shown by the lower accessibility of the tryptophans to quenchers and the increase in tryptophan heterogeneity, and stabilized the dimeric form of both RTs (10-100-fold). The central role of hydrophobic interactions in dimer formation has been revealed by the 30% increase of exposure of the tryptophan cluster to quenchers upon dissociation of RT and the binding of 4 equiv of 1-anilino-8-naphthalenesulfonate to the dissociated enzymes.

Inhibition of human immunodeficiency virus type 1 reverse transcriptase dimerization using synthetic peptides derived from the connection domain

Based on presently available information on the structure of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase, peptides have been synthesized which correspond to the sequence of a particular region of the protein involved in formation of the active heterodimeric form of the enzyme. Several peptides that are 15-19 amino acids long and that are derived from the so-called connection domain of the reverse transcriptase are able to inhibit dimerization of the enzyme and thus inhibit development of its enzymatic activities. In particular, a tryptophan-rich 19-mer corresponding to residues 389-407 was relatively efficient, showing an apparent dissociation constant in the micromolar range for one or both of the subunits. The sequence of this region is identical for both subunits, since one (molecular mass of 51 kDa) is the proteolytic product of the other (molecular mass of 66 kDa). Dissociation of the preformed heterodimer could not be induced by the peptides, but increasing concentrations reduced the rate of dimerization in a concentration-dependent manner until it became immeasurable at high concentrations. The results suggest that inhibition of dimerization of reverse transcriptase is an attractive approach to chemotherapeutic intervention in HIV infection and that further development of peptide-based inhibition strategies is worth pursuing.

Kinetics of interaction of HIV reverse transcriptase with primer/template

Intrinsic protein fluorescence of reverse transcriptases from HIV-1 and HIV-2 provides a sensitive signal for monitoring the interaction of the enzymes with primer/template duplex molecules. Kd values for 18/36-mer DNA/DNA duplexes were found to be in the range of a few nanomolar (about 3 times higher for the enzyme from HIV-2 than for that from HIV-1). The quenching of protein fluorescence induced on binding primer/template, together with an increase in extrinsic fluorescence on interaction with primer/template containing a fluorescent nucleotide at the 3'-end of the primer, was used to investigate the kinetics of interaction with reverse transcriptase from HIV-1. The results can be explained in terms of a two-step binding model, with a rapid diffusion-limited initial association (k(ass) = ca. 5 x 10(8) M-1 s-1) followed by a slow isomerization step (k = ca. 0.5 s-1). These (forward) rate constants are increased in the presence of a non-nucleoside inhibitor (S-TIBO) of HIV-1 reverse transcriptase, while the reverse rate constant for the second step is decreased, leading to an increase in affinity between the enzyme and primer/template by a factor of at least 10 when S-TIBO is bound. The results are discussed in terms of present knowledge of the structure of reverse transcriptase.

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

Intrinsic protein fluorescence has been used to study dimerization of the HIV-1 reverse transcriptase (RT). We observed a 25% increase of the tryptophan fluorescence of the enzyme during dissociation of the subunits induced by the addition of acetonitrile. Upon reassociation of the separated subunits, the original fluorescence emission of the heterodimer is restored. A two-state transition model for the RT dimerization process in which the dimers are in equilibrium with folded monomers is proposed. The free energy of dissociation was determined to be 12.2 (+/- 0.2) kcal/mol. In the absence of Mg2+ ions a decrease of this value was observed, whereas the addition of a synthetic primer/template (18/36mer) results in an increase of dimer stability. Analyzing the effect of Mg2+ on the establishment of the binding equilibrium, a dramatic effect with a 100-fold acceleration of the association by the divalent ion was observed.

Structure-function relationships of HIV-1 reverse transcriptase determined using monoclonal antibodies

The reverse transcriptase (RT) of human immunodeficiency virus type 1 (HIV-1) is one of the main targets in approaches to the chemotherapy of AIDS. A detailed knowledge of structure-function relationships of this enzyme is a prerequisite for rational drug design. We have used monoclonal antibodies as tools to identify functionally important regions of the protein. The preparation of 23 murine monoclonal antibodies (mAb) against HIV-1 reverse transcriptase and their different effects on the enzyme are described. The interaction of purified mAbs with HIV-1 RT was demonstrated by enzyme-linked immunosorbent assay (ELISA), Western blots, and high performance liquid chromatography size exclusion chromatography. One of the antibodies also recognized recombinant HIV-2 RT. Antibody binding epitopes on HIV-1 RT were analyzed by immunoblotting using cyanogen bromide fragmented RT, C-terminally truncated mutants, and a peptide ELISA employing 15-mer synthetic overlapping peptides spanning nearly the complete polypeptide chain. The epitopes were mapped within three domains corresponding to amino acids 200-230, 300-428, and 528-560. Two mAbs show neutralizing properties on enzymatic functions of RT. One affects the polymerase activity and to a certain degree the RNase H activity of the enzyme, whereas the other inhibits the latter activity exclusively. mAb 28, which blocks the polymerase activity, interferes with the nucleotide binding region of RT, as shown by fluorescence spectroscopy using a labeled template/primer complex. By investigating the antibody effects on dimer formation of the heterodimeric enzyme, three domains corresponding to amino acids 230-300, 350-428, and residues around amino acid 540 involved in protein-protein interactions were localized.

Factors contributing to the inhibition of HIV reverse transcriptase by chain-terminating nucleotides in vitro and in vivo

Arguments are presented leading to the conclusion that two major factors contribute to the potency of inhibition of DNA-polymerase activity by chain-terminating nucleotides. The relative significance of these factors varies with the reaction conditions, particularly with the length of the template and the concentration ratio of enzyme (reverse transcriptase or other DNA polymerase) to primer. It is concluded that potent inhibition of HIV-reverse transcriptase activity under typical in vitro and in vivo conditions arises from different features of the interaction of chain terminators with the enzyme. A new method of testing for the parameter important under in vivo conditions is suggested.

Expression of the heterodimeric form of human immunodeficiency virus type 2 reverse transcriptase in Escherichia coli and characterization of the enzyme

A system for the expression of recombinant human immunodeficiency virus type 2 (HIV-2) reverse transcriptase (RT) in Escherichia coli has been developed, which allows purification of the heterodimeric form of the enzyme as well as the separate purification of the two subunits. It is shown that equilibrium formation between monomeric and homodimeric forms of the recombinant 66- and 51-kDa subunits is considerably more rapid than in the case of the corresponding homodimeric forms of HIV-1 RT. In accordance with our previously published studies on HIV-1 RT (Restle, T., Müller, B., and Goody, R.S. (1990) J. Biol. Chem. 265, 8986-8988) RNA-dependent DNA polymerase activity of the HIV-2 RT preparations can be exactly correlated to their dimer content. No significant heterodimer formation can be observed upon coexpression of the 66-kDa subunit of HIV-2 RT with the 51-kDa subunit of HIV-1 RT in the same cell, indicating differences in the dimerization domains of the two proteins. Recombinant HIV-2 RT is not recognized by a set of 23 monoclonal antibodies raised against HIV-1 RT, although it shows weak cross-reactivity with sera from HIV-1-infected patients.