Structural requirement for the two-step dimerization of human immunodeficiency virus type 1 genome

Structural Expansion of Catalytic RNA Nanostructures through Oligomerization of a Cyclic Trimer of Engineered Ribozymes

The multimolecular assembly of three-dimensionally structured proteins forms their quaternary structures, some of which have high geometric symmetry. The size and complexity of protein quaternary structures often increase in a hierarchical manner, with simpler, smaller structures serving as units for larger quaternary structures. In this study, we exploited oligomerization of a ribozyme cyclic trimer to achieve larger ribozyme-based RNA assembly. By installing kissing loop (KL) interacting units to one-, two-, or three-unit RNA molecules in the ribozyme trimer, we constructed dimers, open-chain oligomers, and branched oligomers of ribozyme trimer units. One type of open-chain oligomer preferentially formed a closed tetramer containing 12 component RNAs to provide 12 ribozyme units. We also observed large assembly of ribozyme trimers, which reached 1000 nm in size.

Acquisition of Dual Ribozyme-Functions in Nonfunctional Short Hairpin RNAs through Kissing-Loop Interactions

The acquisition of functions via the elongation of nucleotides is an important factor in the development of the RNA world. In our previous study, we found that the introduction of complementary seven-membered kissing loops into inactive R3C ligase ribozymes revived their ligation activity. In this study, we applied the kissing complex formation-induced rearrangement of RNAs to two nonfunctional RNAs by introducing complementary seven-membered loops into each of them. By combining these two forms of RNAs, the ligase activity (derived from the R3C ligase ribozyme) as well as cleavage activity (derived from the hammerhead ribozyme) was obtained. Thus, effective RNA evolution toward the formation of a life system may require the achievement of “multiple” functions via kissing-loop interactions, as indicated in this study. Our results point toward the versatility of kissing-loop interactions in the evolution of RNA, i.e., two small nonfunctional RNAs can gain dual functions via a kissing-loop interaction.

RNA Structural Requirements for Nucleocapsid Protein-Mediated Extended Dimer Formation

Retroviruses package two copies of their genomic RNA (gRNA) as non-covalently linked dimers. Many studies suggest that the retroviral nucleocapsid protein (NC) plays an important role in gRNA dimerization. The upper part of the L3 RNA stem-loop in the 5' leader of the avian leukosis virus (ALV) is converted to the extended dimer by ALV NC. The L3 hairpin contains three stems and two internal loops. To investigate the roles of internal loops and stems in the NC-mediated extended dimer formation, we performed site-directed mutagenesis, gel electrophoresis, and analysis of thermostability of dimeric RNAs. We showed that the internal loops are necessary for efficient extended dimer formation. Destabilization of the lower stem of L3 is necessary for RNA dimerization, although it is not involved in the linkage structure of the extended dimer. We found that NCs from ALV, human immunodeficiency virus type 1 (HIV-1), and Moloney murine leukemia virus (M-MuLV) cannot promote the formation of the extended dimer when the apical stem contains ten consecutive base pairs. Five base pairs correspond to the maximum length for efficient L3 dimerization induced by the three NCs. L3 dimerization was less efficient with M-MuLV NC than with ALV NC and HIV-1 NC.

Highly conserved s2m element of SARS-CoV-2 dimerizes via a kissing complex and interacts with host miRNA-1307-3p

The ongoing COVID-19 pandemic highlights the necessity for a more fundamental understanding of the coronavirus life cycle. The causative agent of the disease, SARS-CoV-2, is being studied extensively from a structural standpoint in order to gain insight into key molecular mechanisms required for its survival. Contained within the untranslated regions of the SARS-CoV-2 genome are various conserved stem-loop elements that are believed to function in RNA replication, viral protein translation, and discontinuous transcription. While the majority of these regions are variable in sequence, a 41-nucleotide s2m element within the genome 3' untranslated region is highly conserved among coronaviruses and three other viral families. In this study, we demonstrate that the SARS-CoV-2 s2m element dimerizes by forming an intermediate homodimeric kissing complex structure that is subsequently converted to a thermodynamically stable duplex conformation. This process is aided by the viral nucleocapsid protein, potentially indicating a role in mediating genome dimerization. Furthermore, we demonstrate that the s2m element interacts with multiple copies of host cellular microRNA (miRNA) 1307-3p. Taken together, our results highlight the potential significance of the dimer structures formed by the s2m element in key biological processes and implicate the motif as a possible therapeutic drug target for COVID-19 and other coronavirus-related diseases.

Aminoacylation of short hairpin RNAs through kissing-loop interactions indicates evolutionary trend of RNA molecules

The unique G3:U70 base pair in the acceptor stem of tRNA^Ala has been shown to be a critical recognition site by alanyl-tRNA synthetase (AlaRS). The base pair resides on one of the arms of the L-shaped structure of tRNA (minihelix) and the genetic code has likely evolved from a primordial tRNA-aaRS (aminoacyl-tRNA synthetase) system. In terms of the evolution of tRNA, incorporation of a G:U base pair in the structure would be important. Here, we found that two independent short hairpin RNAs change their conformation through kissing-loop interactions, finally forming a minihelix-like structure, in which the G3:U70 base pair is incorporated. The RNA system can be properly aminoacylated by the minimal Escherichia coli AlaRS variant with alanylation activity (AlaRS442N). Thus, characteristic structural features produced via kissing-loop interactions may provide important clues into the evolution of RNA.

RNA Aptamers for a tRNA-Binding Protein from Aeropyrum pernix with Homologous Counterparts Distributed Throughout Evolution

In the present in vitro selection study, we isolated and characterized RNA aptamers for a tRNA-binding protein (Trbp) from an extremophile archaeon Aeropyrum pernix. Trbp-like structures are frequently found not only in aminoacyl-tRNA synthetases but also in diverse types of proteins from different organisms. They likely arose early in evolution and have played important roles in evolution through interactions with key RNA structures. RNA aptamers specific for A. pernix Trbp were successfully selected from a pool of RNAs composed of 60 nucleotides, including a random 30-nucleotide region. From the secondary structures, we obtained a shortened sequence composed of 21 nucleotides, of which the 3′-terminal single stranded CA nucleotides are essential for binding. This may be related to the initial evolutionary role of the universal CCA-3′ terminus of tRNA in the interaction with Trbp-like structures.

Native Electrospray Ionization Mass Spectrometry of RNA-Ligand Complexes

Native electrospray ionization mass spectrometry (native ESI-MS) is a powerful tool to investigate non-covalent biomolecular interactions. It has been widely used to study protein complexes, but only few examples are described for the analysis of complexes involving RNA-RNA interactions. Here, we provide a detailed protocol for native ESI-MS analysis of RNA complexes. As an example, we present the analysis of the HIV-1 genomic RNA dimerization initiation site (DIS) extended duplex dimer bound to the aminoglycoside antibiotic lividomycin.

Analysis of the HIV-1 Genomic RNA Dimerization Initiation Site Binding to Aminoglycoside Antibiotics Using Isothermal Titration Calorimetry

Isothermal titration calorimetry (ITC) provides a sensitive, powerful, and accurate tool to suitably analyze the thermodynamic of RNA binding events. This approach does not require any modification or labeling of the system under analysis and is performed in solution. ITC is a very convenient technique that provides an accurate determination of binding parameters, as well as a complete thermodynamic profile of the molecular interactions. Here we show how this approach can be used to characterize the interactions between the dimerization initiation site (DIS) RNA localized within the HIV-1 viral genome and aminoglycoside antibiotics. Our ITC study showed that the 4,5-disubstituted 2-desoxystreptamine (2-DOS) aminoglycosides can bind the DIS with a nanomolar affinity and a high specificity.

Impact of 5'-end nucleotide modifications of HIV-1 genomic RNA on reverse transcription

Reverse transcription of retroviral RNA is accomplished through a minus-strand strong stop cDNA (-sscDNA) synthesis and subsequent strand-transfer reactions. We have previously reported a critical role of guanosine (G) number at 5'-terminal of HIV-1 RNA for successful strand-transfer of -sscDNA. In this study, role(s) of the cap consisting of 7-methyl guanosine (^7mG), a hallmark of transcripts generated by RNA polymerase II, at the 5'-end G nucleotide (5'-G) of HIV-1 RNA were examined. In parallel, contribution of highly conserved GGG tract located at the U3/R boundary in 3' terminal region of viral RNA (3'-GGG tract) was also addressed. The in vitro reverse transcription analysis using synthetic HIV-1 RNAs possessing the 5'-G with cap or triphosphate form demonstrated that the 5'-cap significantly increased strand-transfer efficiency of -sscDNA. Meanwhile, effect of the 5'-cap on the strand-transfer was retained in the reaction using mutant HIV-1 RNAs in which two Gs were deleted from the 3'-GGG tract. Lack of apparent contribution of the 3'-GGG tract during strand-transfer events in vitro was reproduced in the context of HIV-1 replication within cells. Instead, we noticed that the 3'-GGG tract might be required for efficient gene expression from proviral DNA. These results indicated that ^7mG of the cap on HIV-1 RNA might not be reverse-transcribed and a possible role of the 3'-GGG tract to accept the non-template nucleotide addition during -sscDNA synthesis might be less likely. The 5'-G modifications of HIV-1 RNAs by the cap- or phosphate-removal enzyme revealed that the cap or monophosphate form of the 5'-G was preferred for the 1st strand-transfer compared to the triphosphate or non-phosphate form. Taken together, a status of the 5'-G determined strand-transfer efficiency of -sscDNA without affecting the non-template nucleotide addition, probably by affecting association of the 5'-G with 3'-end region of viral RNA.

Effects of complementary loop composition in truncated R3C ligase ribozymes on kiss switch activation

The formation of a kissing-loop through the introduction of complementary 7-membered loops is known to dramatically increase the activity of truncated R3C ligase ribozymes that otherwise display reduced activity. Restoration of activity is thought to result from kissing complex formation-induced rearrangement of two molecules with complementary loops. By combining two types of R3C ligase ribozyme mutants, <A> and <hairpin-ΔU>, the influence of loop composition on ligation activity was investigated. Substrate ligation occurred in <hairpin-ΔU>, but not in <A>, despite the absence of a substrate-binding site in <hairpin-ΔU>. Loop-loop interactions of <A>- and <hairpin-ΔU>-variants with complementary 6-membered loops also resulted in proper kissing-complex formation-induced substrate ligation. However, heterogeneous combinations of 7- and 6-membered loops, and/or of 6- and 5-membered loops had distinct results that depended upon the sequence and bulged nucleotides of the loop regions. These differences suggest that both thermodynamic and kinetic controls act upon the kissing-loop interaction-mediated rearrangement of the shortened trans-R3C ribozymes.

Retroviral RNA Dimerization: From Structure to Functions

The genome of the retroviruses is a dimer composed by two homologous copies of genomic RNA (gRNA) molecules of positive polarity. The dimerization process allows two gRNA molecules to be non-covalently linked together through intermolecular base-pairing. This step is critical for the viral life cycle and is highly conserved among retroviruses with the exception of spumaretroviruses. Furthermore, packaging of two gRNA copies into viral particles presents an important evolutionary advantage for immune system evasion and drug resistance. Recent studies reported RNA switches models regulating not only gRNA dimerization, but also translation and packaging, and a spatio-temporal characterization of viral gRNA dimerization within cells are now at hand. This review summarizes our current understanding on the structural features of the dimerization signals for a variety of retroviruses (HIVs, MLV, RSV, BLV, MMTV, MPMV…), the mechanisms of RNA dimer formation and functional implications in the retroviral cycle.

The Kiss Switch Brings Inactive R3C Ligase Ribozyme Back to Life

R3C ligase ribozyme catalyzes the nucleophilic attack by a 3'-hydroxyl on a 5'-α-phosphorus of triphosphates to form a 3'-5'-phosphodiester bond. In the present study, although the truncation of R3C ribozyme was accompanied by a large reduction in ligation activity (decrease by two orders of magnitude compared to that of the ligated product of full-length R3C ribozyme after 18.5 h at 23 °C), the introduction of complementary seven-membered kissing-loops served as a "switch" to reactivate the truncated R3C ribozyme with approximately one-fifth of the activity of the full-length R3C ribozyme. This reactivation occurred in a trans-manner, and the grip region and substrate-binding site of the truncated R3C ribozyme were necessary to locate the substrate in the proper position for ligation with the other molecule. Reactivation resulted from complex tertiary interactions between two ribozymes, including kissing-loop interaction-induced annealing and the formation of a stable duplex. The drastic increase of the activity of poorly active ribozymes through the kissing-loop interaction may provide an important clue into the acquisition of substantial activity during the evolution of the RNA world.

NMR Studies of the Structure and Function of the HIV-1 5'-Leader

The 5′-leader of the human immunodeficiency virus type 1 (HIV-1) genome plays several critical roles during viral replication, including differentially establishing mRNA versus genomic RNA (gRNA) fates. As observed for proteins, the function of the RNA is tightly regulated by its structure, and a common paradigm has been that genome function is temporally modulated by structural changes in the 5′-leader. Over the past 30 years, combinations of nucleotide reactivity mapping experiments with biochemistry, mutagenesis, and phylogenetic studies have provided clues regarding the secondary structures of stretches of residues within the leader that adopt functionally discrete domains. More recently, nuclear magnetic resonance (NMR) spectroscopy approaches have been developed that enable direct detection of intra- and inter-molecular interactions within the intact leader, providing detailed insights into the structural determinants and mechanisms that regulate HIV-1 genome packaging and function.

NMR detection of intermolecular interaction sites in the dimeric 5'-leader of the HIV-1 genome

HIV type-1 (HIV-1) contains a pseudodiploid RNA genome that is selected for packaging and maintained in virions as a noncovalently linked dimer. Genome dimerization is mediated by conserved elements within the 5'-leader of the RNA, including a palindromic dimer initiation signal (DIS) that has been proposed to form kissing hairpin and/or extended duplex intermolecular contacts. Here, we have applied a ²H-edited NMR approach to directly probe for intermolecular interactions in the full-length, dimeric HIV-1 5'-leader (688 nucleotides; 230 kDa). The interface is extensive and includes DIS:DIS base pairing in an extended duplex state as well as intermolecular pairing between elements of the upstream Unique-5' (U5) sequence and those near the gag start site (AUG). Other pseudopalindromic regions of the leader, including the transcription activation (TAR), polyadenylation (PolyA), and primer binding (PBS) elements, do not participate in intermolecular base pairing. Using a ²H-edited one-dimensional NMR approach, we also show that the extended interface structure forms on a time scale similar to that of overall RNA dimerization. Our studies indicate that a kissing dimer-mediated structure, if formed, exists only transiently and readily converts to the extended interface structure, even in the absence of the HIV-1 nucleocapsid protein or other RNA chaperones.

DNA-DNA kissing complexes as a new tool for the assembly of DNA nanostructures

Kissing-loop annealing of nucleic acids occurs in nature in several viruses and in prokaryotic replication, among other circumstances. Nucleobases of two nucleic acid strands (loops) interact with each other, although the two strands cannot wrap around each other completely because of the adjacent double-stranded regions (stems). In this study, we exploited DNA kissing-loop interaction for nanotechnological application. We functionalized the vertices of DNA tetrahedrons with DNA stem-loop sequences. The complementary loop sequence design allowed the hybridization of different tetrahedrons via kissing-loop interaction, which might be further exploited for nanotechnology applications like cargo transport and logical elements. Importantly, we were able to manipulate the stability of those kissing-loop complexes based on the choice and concentration of cations, the temperature and the number of complementary loops per tetrahedron either at the same or at different vertices. Moreover, variations in loop sequences allowed the characterization of necessary sequences within the loop as well as additional stability control of the kissing complexes. Therefore, the properties of the presented nanostructures make them an important tool for DNA nanotechnology.

Fate of HIV-1 cDNA intermediates during reverse transcription is dictated by transcription initiation site of virus genomic RNA

Retroviral reverse transcription is accomplished by sequential strand-transfers of partial cDNA intermediates copied from viral genomic RNA. Here, we revealed an unprecedented role of 5′-end guanosine (G) of HIV-1 genomic RNA for reverse transcription. Based on current consensus for HIV-1 transcription initiation site, HIV-1 transcripts possess a single G at 5′-ends (G1-form). However, we found that HIV-1 transcripts with additional Gs at 5′-ends (G2- and G3-forms) were abundantly expressed in infected cells by using alternative transcription initiation sites. The G2- and G3-forms were also detected in the virus particle, although the G1-form predominated. To address biological impact of the 5′-G number, we generated HIV clone DNA to express the G1-form exclusively by deleting the alternative initiation sites. Virus produced from the clone showed significantly higher strand-transfer of minus strong-stop cDNA (-sscDNA). The in vitro assay using synthetic HIV-1 RNAs revealed that the abortive forms of -sscDNA were abundantly generated from the G3-form RNA, but dramatically reduced from the G1-form. Moreover, the strand-transfer of -sscDNA from the G1-form was prominently stimulated by HIV-1 nucleocapsid. Taken together, our results demonstrated that the 5′-G number that corresponds to HIV-1 transcription initiation site was critical for successful strand-transfer of -sscDNA during reverse transcription.

In NMR tube transcription for rapid screening of RNA conformation

A simple method for rapid structure screening for RNA by NMR is proposed. Target RNA is transcribed in a NMR tube and its spectra are measured without purification. The proposed method, in NMR tube transcription or INTT, was applied for three RNAs for which NMR spectra have been measured by using the conventionally purified samples. By the real-time measuring, increase of imino proton signals and decrease of NTP signals can be observed. It was confirmed that INTT spectra are in general similar to those obtained by the conventional method. INTT can be used for the first-step screening of RNA folding.

The design of RNA binders: targeting the HIV replication cycle as a case study

The human immunodeficiency virus 1 (HIV-1) replication cycle is finely tuned with many important steps involving RNA-RNA or protein-RNA interactions, all of them being potential targets for the development of new antiviral compounds. This cycle can also be considered as a good benchmark for the evaluation of early-stage strategies aiming at designing drugs that bind to RNA, with the possibility to correlate in vitro activities with antiviral properties. In this review, we highlight different approaches developed to interfere with four important steps of the HIV-1 replication cycle: the early stage of reverse transcription, the transactivation of viral transcription, the nuclear export of partially spliced transcripts and the dimerization step.

HIV-1 DIS stem loop forms an obligatory bent kissing intermediate in the dimerization pathway

The HIV-1 dimerization initiation sequence (DIS) is a conserved palindrome in the apical loop of a conserved hairpin motif in the 5′-untranslated region of its RNA genome. DIS hairpin plays an important role in genome dimerization by forming a ‘kissing complex’ between two complementary hairpins. Understanding the kinetics of this interaction is key to exploiting DIS as a possible human immunodeficiency virus (HIV) drug target. Here, we present a single-molecule Förster resonance energy transfer (smFRET) study of the dimerization reaction kinetics. Our data show the real-time formation and dissociation dynamics of individual kissing complexes, as well as the formation of the mature extended duplex complex that is ultimately required for virion packaging. Interestingly, the single-molecule trajectories reveal the presence of a previously unobserved bent intermediate required for extended duplex formation. The universally conserved A272 is essential for the formation of this intermediate, which is stabilized by Mg²⁺, but not by K⁺ cations. We propose a 3D model of a possible bent intermediate and a minimal dimerization pathway consisting of three steps with two obligatory intermediates (kissing complex and bent intermediate) and driven by Mg²⁺ ions.

Structure-guided discovery of a novel aminoglycoside conjugate targeting HIV-1 RNA viral genome

The dimerization initiation site (DIS) of the HIV-1 genomic RNA is a conserved stem-loop that promotes viral genome dimerization by forming a loop-loop complex. The DIS constitutes a potentially interesting target because it is crucial for several key steps of the viral replication. In this work we describe the synthesis of a rationally designed aminoglycoside conjugate that binds the HIV-1 DIS viral RNA with high specificity, as shown by an extensive in vitro binding characterization. We propose a three-dimensional model of the drug-RNA interaction that perfectly fits with binding data. Our results show the feasibility of targeting the HIV DIS viral RNA dimer and open the way to the rationale design of a new class of antiviral drugs. In addition, due to similarities between the HIV-1 DIS RNA and the bacterial aminoacyl decoding site (A site) RNA, we show that this novel aminoglycoside conjugate also binds the bacterial A site with a similar affinity as natural aminoglycoside antibiotics.

Glycols modulate terminator stem stability and ligand-dependency of a glycine riboswitch

The Bacillus subtilis glycine riboswitch comprises tandem glycine-binding aptamers and a putative terminator stem followed by the gcvT operon. Gene expression is regulated via the sensing of glycine. However, we found that the riboswitch behaves in a "glycine-independent" manner in the presence of polyethylene glycol (PEG) and ethylene glycol. The effect is related to the formation of a terminator stem within the expression platform under such conditions. The results revealed that increasing PEG stabilized the structure of the terminator stem. By contrast, the addition of ethylene glycol destabilized the terminator stem. PEG and ethylene glycol have opposite effects on transcription as well as on stable terminator stem formation. The glycine-independency of the riboswitch and the effects of such glycols might shed light on the evolution of riboswitches.

Molecular determinants of HIV-1 NCp7 chaperone activity in maturation of the HIV-1 dimerization initiation site

Human immunodeficiency virus genome dimerization is initiated through an RNA-RNA kissing interaction formed via the dimerization initiation site (DIS) loop sequence, which has been proposed to be converted to a more thermodynamically stable linkage by the viral p7 form of the nucleocapsid protein (NC). Here, we systematically probed the role of specific amino acids of NCp7 in its chaperone activity in the DIS conversion using 2-aminopurine (2-AP) fluorescence and nuclear magnetic resonance spectroscopy. Through comparative analysis of NCp7 mutants, the presence of positively charged residues in the N-terminus was found to be essential for both helix destabilization and strand transfer functions. It was also observed that the presence and type of the Zn finger is important for NCp7 chaperone activity, but not the order of the Zn fingers. Swapping single aromatic residues between Zn fingers had a significant effect on NCp7 activity; however, these mutants did not exhibit the same activity as mutants in which the order of the Zn fingers was changed, indicating a functional role for other flanking residues. RNA chaperone activity is further correlated with NCp7 structure and interaction with RNA through comparative analysis of nuclear magnetic resonance spectra of NCp7 variants, and complexes of these proteins with the DIS dimer.

Hepatitis C virus RNA: molecular switches mediated by long-range RNA-RNA interactions?

Multiple conserved structural cis-acting regulatory elements have been recognized both in the coding and untranslated regions (UTRs) of the hepatitis C virus (HCV) genome. For example, the cis-element 5BSL3.2 in the HCV-coding region has been predicted to use both its apical and internal loops to interact with the X RNA in the 3'-UTR, with the IIId domain in the 5'-UTR and with the Alt sequence in the coding region. Additionally, the X RNA region uses a palindromic sequence that overlaps the sequence required for the interaction with 5BSL3.2, to dimerize with another HCV genome. The ability of the 5BSL3.2 and X RNA regions to engage in multi-interactions suggests the existence of one or more molecular RNA switches which may regulate different steps of the HCV life cycle. In this study, we used biophysical methods to characterize the essential interactions of these HCV cis-elements at the molecular level. Our results indicate that X RNA interacts with 5BSL3.2 and another X RNA molecule by adopting two different conformations and that 5BSL3.2 engages simultaneously in kissing interactions using its apical and internal loops. Based on these results, we propose a mode of action for possible molecular switches involving the HCV RNA.

Visualizing transient low-populated structures of RNA

The visualization of RNA conformational changes has provided fundamental insights into how regulatory RNAs carry out their biological functions. The RNA structural transitions that have been characterized to date involve long-lived species that can be captured by structure characterization techniques. Here, we report the Nuclear Magnetic Resonance visualization of RNA transitions towards invisible ‘excited states’ (ES), which exist in too little abundance (2–13%) and for too short periods of time (45–250 μs) to allow structural characterization by conventional techniques. Transitions towards ESs result in localized rearrangements in base-pairing that alter building block elements of RNA architecture, including helix-junction-helix motifs and apical loops. The ES can inhibit function by sequestering residues involved in recognition and signaling or promote ATP-independent strand exchange. Thus, RNAs do not adopt a single conformation, but rather exist in rapid equilibrium with alternative ESs, which can be stabilized by cellular cues to affect functional outcomes.

Dimerization of nucleic acid hairpins in the conditions caused by neutral cosolutes

Characterization of metal ion binding to RNA and DNA base pairs is important for understanding their energy contribution to the folding and conformational changes of nucleic acid structures. In this study, we examine the equilibrium shift from the hairpin toward the dimer formation, induced by nonspecifically bound metal ions. The hairpin dimerization is markedly enhanced in the presence of high background concentrations of poly(ethylene glycol) (PEG) and several small organic molecules. The simple volume exclusion effect and the base pair stability cannot entirely account for this increase. We find that the dielectric constant correlates well with the dimerization efficiency in the conditions caused by small alcohol molecules and amide compounds as well as PEG. The hairpin dimerization experiments reveal the potential of PEG for enhancing the binding affinity between nucleic acids and metal ions, by reducing the solution dielectric constant without decreasing the thermodynamic stability of nucleic acid structures. The results presented here contribute to the understanding of nucleic acid folding and its ability to switch between alternative conformations under the condition of limited cation availability and cellular physiology.

Thermodynamic and kinetic analysis of an RNA kissing interaction and its resolution into an extended duplex

Kissing hairpin interactions form when the loop residues of two hairpins have Watson-Crick complementarity. In a unimolecular context, kissing interactions are important for tertiary folding and pseudoknot formation, whereas in a bimolecular context, they provide a basis for molecular recognition. In some cases, kissing complexes can be a prelude to strand displacement reactions where the two hairpins resolve to form a stable extended intermolecular duplex. The kinetics and thermodynamics of kissing-complex formation and their subsequent strand-displacement reactions are poorly understood. Here, biophysical techniques including isothermal titration calorimetry, surface plasmon resonance, and single-molecule fluorescence have been employed to probe the factors that govern the stability of kissing complexes and their subsequent structural rearrangements. We show that the general understanding of RNA duplex formation can be extended to kissing complexes but that kissing complexes display an unusual level of stability relative to simple duplexes of the same sequence. These interactions form and break many times at room temperature before becoming committed to a slow, irreversible forward transition to the strand-displaced form. Furthermore, using smFRET we show that the primary difference between stable and labile kissing complexes is based almost completely on their off rates. Both stable and labile complexes form at the same rate within error, but less stable species dissociate rapidly, allowing us to understand how these complexes can help generate specificity along a folding pathway or during a gene regulation event.

Structure and stability of RNA/RNA kissing complex: with application to HIV dimerization initiation signal

We develop a statistical mechanical model to predict the structure and folding stability of the RNA/RNA kissing-loop complex. One of the key ingredients of the theory is the conformational entropy for the RNA/RNA kissing complex. We employ the recently developed virtual bond-based RNA folding model (Vfold model) to evaluate the entropy parameters for the different types of kissing loops. A benchmark test against experiments suggests that the entropy calculation is reliable. As an application of the model, we apply the model to investigate the structure and folding thermodynamics for the kissing complex of the HIV-1 dimerization initiation signal. With the physics-based energetic parameters, we compute the free energy landscape for the HIV-1 dimer. From the energy landscape, we identify two minimal free energy structures, which correspond to the kissing-loop dimer and the extended-duplex dimer, respectively. The results support the two-step dimerization process for the HIV-1 replication cycle. Furthermore, based on the Vfold model and energy minimization, the theory can predict the native structure as well as the local minima in the free energy landscape. The root-mean-square deviations (RMSDs) for the predicted kissing-loop dimer and extended-duplex dimer are ~3.0 Å. The method developed here provides a new method to study the RNA/RNA kissing complex.

Melting of model HIV-1 stem-loop 1 RNA dimers monitored by 2-aminopurine fluorescence

Viral maturation of HIV-1 involves refolding of its genomic RNA, which is believed to include a rearrangement of the SL1 stem-loop from a metastable conformation called kissing loop dimer (KD) to a stable one termed extended dimer (ED). To investigate this rearrangement in vitro we have studied the thermal melting of the RNA dimers formed by slightly modified 23-nucleotide SL1 RNA of HIV-1 Mal. Local structural changes in the RNA dimers during the melting were monitored by changes in the fluorescence of 2-aminopurine (2AP) incorporated in predetermined positions of RNA. We have shown that the stem regions of both preformed KD and ED melt in the temperature interval from 75 ° C to 90 ° C. Kissing loop interface of the KD RNA is found to be disrupted at lower temperatures from 20 ° C to 55 ° C, at which the stem regions remain intact. Conversion of the preformed KD to ED overcoming the kinetic barrier occurs between 55 ° C and 65 ° C. The melting of "loop-loop" regions in both preformed and newly formed EDs takes place around 70 ° C. Our finding that thermoinduced KD-to-ED conversion is preceded by transient dissociation of loop-loop interface disagrees with a common idea of strand exchange without disruption of loop-loop-contact.

Formation of immature and mature genomic RNA dimers in wild-type and protease-inactive HIV-1: differential roles of the Gag polyprotein, nucleocapsid proteins NCp15, NCp9, NCp7, and the dimerization initiation site

Formation of immature genomic RNA (gRNA) dimers is exquisitely nucleocapsid (NC)-dependent in protease-inactive (PR-in) HIV-1. This establishes that Pr55gag/Pr160gag-pol has NC-dependent chaperone activity within intact HIV-1. Mutations in the proximal zinc finger and the linker of the NC sequence of Pr55gag/Pr160gag-pol abolish gRNA dimerization in PR-in HIV-1. In wild type, where the NC of Pr55gag is processed into progressively smaller proteins termed NCp15 (NCp7-p1-p6), NCp9 (NCp7-p1) and NCp7, formation of immature dimers is much swifter than in PR-in HIV-1. NCp7 and NCp15 direct this rapid accumulation. NCp9 is sluggish in this process, but it stimulates the transition from immature to mature gRNA dimer as well as NCp7 and much better than NCp15. The amino-terminus, proximal zinc finger, linker, and distal zinc finger of NCp7 contribute to this maturation event in intact HIV-1. The DIS is a dimerization initiation site for all immature gRNA dimers, irrespective of their mechanism of formation.

Cation-dependent cleavage of the duplex form of the subtype-B HIV-1 RNA dimerization initiation site

The crystal structure of subtype-B HIV-1 genomic RNA Dimerization Initiation Site duplex revealed chain cleavage at a specific position resulting in 3'-phosphate and 5'-hydroxyl termini. A crystallographic analysis showed that Ba(2+), Mn(2+), Co(2+) and Zn(2+) bind specifically on a guanine base close to the cleaved position. The crystal structures also point to a necessary conformational change to induce an 'in-line' geometry at the cleavage site. In solution, divalent cations increased the rate of cleavage with pH/pKa compensation, indicating that a cation-bound hydroxide anion is responsible for the cleavage. We propose a 'Trojan horse' mechanism, possibly of general interest, wherein a doubly charged cation hosted near the cleavage site as a 'harmless' species is further transformed in situ into an 'aggressive' species carrying a hydroxide anion.

Binding characteristics of small molecules that mimic nucleocapsid protein-induced maturation of stem-loop 1 of HIV-1 RNA

As a retrovirus, the human immunodeficiency virus (HIV-1) packages two copies of the RNA genome as a dimer in the infectious virion. Dimerization is initiated at the dimer initiation site (DIS) which encompasses stem-loop 1 (SL1) in the 5'-UTR of the genome. Study of genomic dimerization has been facilitated by the discovery that short RNA fragments containing SL1 can dimerize spontaneously without any protein factors. On the basis of the palindromic nature of SL1, a kissing loop model has been proposed. First, a metastable kissing dimer is formed via standard Watson-Crick base pairs and then converted into a more stable extended dimer by the viral nucleocapsid protein (NCp7). This dimer maturation in vitro is believed to mimic initial steps in the RNA maturation in vivo, which is correlated with viral infectivity. We previously discovered a small molecule activator, Lys-Ala-7-amido-4-methylcoumarin (KA-AMC), which facilitates dimer maturation in vitro, and determined aspects of its structure-activity relationship. In this report, we present measurements of the binding affinity of the activators and characterization of their interactions with the SL1 RNA. Guanidinium groups and increasing positive charge on the side chain enhance affinity and activity, but features in the aromatic ring at least partially decouple affinity from activity. Although KA-AMC can bind to multiple structural motifs, the NMR study showed KA-AMC preferentially binds to unique structural motifs, such as the palindromic loop and the G-rich internal loop in the SL1 RNA. NCp7 binds to SL1 only 1 order of magnitude more tightly than the best small molecule ligand tested. This study provides guidelines for the design of superior small molecules that bind to the SL1 RNA that have the potential of being developed as an antiviral by interfering with SL1-NCp7 interaction at the packaging and/or maturation stages.

Hepatitis C virus genomic RNA dimerization is mediated via a kissing complex intermediate

With over 200 million people infected with hepatitis C virus (HCV) worldwide, there is a need for more effective and better-tolerated therapeutic strategies. The HCV genome is a positive-sense; single-stranded RNA encoding a large polyprotein cleaved at multiple sites to produce at least ten proteins, among them an error-prone RNA polymerase that confers a high mutation rate. Despite considerable overall sequence diversity, in the 3'-untranslated region of the HCV genomic RNA there is a 98-nucleotide (nt) sequence named X RNA, the first 55 nt of which (X55 RNA) are 100% conserved among all HCV strains. The X55 region has been suggested to be responsible for in vitro dimerization of the genomic RNA in the presence of the viral core protein, although the mechanism by which this occurs is unknown. In this study, we analyzed the X55 region and characterized the mechanism by which it mediates HCV genomic RNA dimerization. Similar to a mechanism proposed previously for the human immunodeficiency 1 virus (HIV-1) genome, we show that dimerization of the HCV genome involves formation of a kissing complex intermediate, which is converted to a more stable extended duplex conformation in the presence of the core protein. Mutations in the dimer linkage sequence loop sequence that prevent RNA dimerization in vitro significantly reduced but did not completely ablate the ability of HCV RNA to replicate or produce infectious virus in transfected cells.

Noncovalent probes for the investigation of structure and dynamics of protein-nucleic acid assemblies: the case of NC-mediated dimerization of genomic RNA in HIV-1

The nature of specific RNA-RNA and protein-RNA interactions involved in the process of genome dimerization and isomerization in HIV-1, which is mediated in vitro by stemloop 1 (SL1) of the packaging signal and by the nucleocapsid (NC) domain of the viral Gag polyprotein, was investigated by using archetypical nucleic acid ligands as noncovalent probes. Small-molecule ligands make contact with their target substrates through complex combinations of H-bonds, salt bridges, and hydrophobic interactions. Therefore, their binding patterns assessed by electrospray ionization mass spectrometry can provide valuable insights into the factors determining specific recognition between species involved in biopolymer assemblies. In the case of SL1, dimerization and isomerization create unique structural features capable of sustaining stable interactions with classic nucleic acid ligands. The binding modes exhibited by intercalators and minor groove binders were adversely affected by the significant distortion of the duplex formed by palindrome annealing in the kissing-loop (KL) dimer, whereas the modes observed for the corresponding extended duplex (ED) confirmed a more regular helical structure. Consistent with the ability to establish electrostatic interactions with highly negative pockets typical of helix anomalies, polycationic aminoglycosides bound to the stem-bulge motif conserved in all SL1 conformers, to the unpaired nucleotides located at the hinge between kissing hairpins in KL, and to the exposed bases flanking the palindrome duplex in ED. The patterns afforded by intercalators and minor groove binders did not display detectable variations when the corresponding NC-SL1 complexes were submitted to probing. In contrast, aminoglycosides displayed the ability to compete with the protein for overlapping sites, producing opposite effects on the isomerization process. Indeed, displacing NC from the stem-bulges of the KL dimer induced inhibition of stem melting and decreased the efficiency of isomerization. Competition for the hinge region, instead, eliminated the NC stabilization of a grip motif formed by nucleobases of opposite strands, thus facilitating the strand-exchange required for isomerization. These noncovalent probes provided further evidence that the structural context of the actual binding sites has significant influence on the chaperone activities of NC, which should be taken in account when developing potential drug candidates aimed at disrupting genome dimerization and isomerization in HIV-1.

Dissecting structural transitions in the HIV-1 dimerization initiation site RNA using 2-aminopurine fluorescence

A highly conserved 35 nucleotide RNA stem-loop, the dimerization initiation site (DIS), in the 5' untranslated region (UTR) of the human immunodeficiency virus type I (HIV-1) genome has been identified as the sequence primarily responsible for initiation of viral genome dimerization. The DIS initiates viral genome dimerization through a loop-loop 'kissing' interaction and is converted from an intermediate 'kissing' to a more thermodynamically stable extended duplex dimer in a conformational rearrangement that is chaperoned by the HIV-1 nucleocapsid protein (NCp7). Here we describe fluorescence methods designed to probe local RNA dynamics and structural transitions associated with the DIS dimer formation and its NCp7 chaperoned structural conversion. These methods take advantage of the exquisite sensitivity of the quantum yield of the fluorescent nucleotide base analog, 2-aminopurine (2-AP), to its immediate structural and dynamic environment. The 2-AP fluorescence methods described allow a detailed kinetic and thermodynamic examination of this type of RNA-RNA interaction, as well as an analysis of the molecular mechanism of NCp7 chaperone activity.

Regulation of primate lentiviral RNA dimerization by structural entrapment

BACKGROUND

Genomic RNA dimerization is an important process in the formation of an infectious lentiviral particle. One of the signals involved is the stem-loop 1 (SL1) element located in the leader region of lentiviral genomic RNAs which also plays a role in encapsidation and reverse transcription. Recent studies revealed that HIV types 1 and 2 leader RNAs adopt different conformations that influence the presentation of RNA signals such as SL1. To determine whether common mechanisms of SL1 regulation exist among divergent lentiviral leader RNAs, here we compare the dimerization properties of SIVmac239, HIV-1, and HIV-2 leader RNA fragments using homologous constructs and experimental conditions. Prior studies from several groups have employed a variety of constructs and experimental conditions.

RESULTS

Although some idiosyncratic differences in the dimerization details were observed, we find unifying principles in the regulation strategies of the three viral RNAs through long- and short-range base pairing interactions. Presentation and efficacy of dimerization through SL1 depends strongly upon the formation or dissolution of the lower stem of SL1 called stem B. SL1 usage may also be down-regulated by long-range interactions involving sequences between SL1 and the first codons of the gag gene.

CONCLUSION

Despite their sequence differences, all three lentiviral RNAs tested in this study showed a local regulation of dimerization through the stabilization of SL1.

2-aminopurine fluorescence: discrimination between specific and unspecific ligand binding to the kissing-loop dimer of the HIV-1 RNA

The fluorescent 2-aminopurine probe (2-AP) incorporated into the loop of 23-mer RNA hairpin of HIV-1 genome dimerization initiation site (DIS) was used for discrimination of specific and unspecific binding of paromomycin and spermine to the kissing loop dimer (KD) formed in solution. While both ligands stabilized the KD RNA structure, only paromomycin binding resulted in significant increase of 2-AP fluorescence. These observations suggest that the 2-AP fluorescent RNA construct might be useful for selecting ligands specifically binding the HIV-1 kissing loop RNA dimer.

Insight into the intrinsic flexibility of the SL1 stem-loop from genomic RNA of HIV-1 as probed by molecular dynamics simulation

The SL1 stem-loop is the dimerization initiation site for linking the two copies of the RNA forming the HIV-1 genome. The 26 nucleotides stem contains a defect consisting on a highly conserved G-rich 1-3 asymmetrical internal loop, which is a major site for nucleocapsid protein binding. Several NMR attempts were undertaken to determine the internal loop structure in the SL1 monomer. However, the RNA constructs used in the different studies were largely mutated, in particular with replacement of the nine nucleotides apical loop by a tetraloop, and divergent results were obtained ranging from a rigid structure to a particularly large flexibility. To investigate the reasons for such discrepancies, we used molecular dynamics simulation of the SL1 monomer to probe the effect of mutations on the conformational stability of the internal loop and of the whole stem. It is found that in the wild-type sequence, the internal loop displays conformational variability originating mainly from the nine nucleotides apical loop flexibility that causes large conformational fluctuations (without changing the average structure) in the 7 bp duplex linking the apical and internal loops. The large amplitude atomic motions in the duplex are transmitted to the internal loop in which they induce conformational changes characterized by a labile hydrogen bond network such as G5 successively H-bonded to A29 and G30. On the contrary, with a four nucleotides apical loop, conformational fluctuations in the duplex are reduced by a factor of 2 and are not sufficiently energizing for promoting changes in the internal loop structure at the time scale of the simulations.

Mapping of nucleocapsid residues important for HIV-1 genomic RNA dimerization and packaging

Retroviral genomic RNA (gRNA) dimerization appears essential for viral infectivity, and the nucleocapsid protein (NC) of human immunodeficiency virus type 1 (HIV-1) facilitates HIV-1 gRNA dimerization. To identify the relevant and dispensable positions of NC, 34 of its 55 residues were mutated, individually or in small groups, in a panel of 40 HIV-1 mutants prepared by site-directed mutagenesis. It was found that the amino-terminus, the proximal zinc finger, the linker, and the distal zinc finger of NC each contributed roughly equally to efficient HIV-1 gRNA dimerization. The N-terminal and linker segments appeared to play predominantly electrostatic and steric roles, respectively. Mutating the hydrophobic patch of either zinc finger, or substituting alanines for their glycine doublet, was as disabling as deleting the corresponding finger. Replacing the CysX(2)CysX(4)HisX(4)Cys motif of either finger by CysX(2)CysX(4)CysX(4)Cys or CysX(2)CysX(4)HisX(4)His, interchanging the zinc fingers or, replacing one zinc finger by a copy of the other one, had generally intermediate effects; among these mutations, the His23-->Cys substitution in the N-terminal zinc finger had the mildest effect. The charge of NC could be increased or decreased by up to 18%, that of the linker could be reduced by 75% or increased by 50%, and one or two electric charges could be added or subtracted from either zinc finger, without affecting gRNA dimerization. Shortening, lengthening, or making hydrophobic the linker was as disabling as deleting the N-terminal or the C-terminal zinc finger, but a neutral and polar linker was innocuous. The present work multiplies by 4 and by 33 the number of retroviral and lentiviral NC mutations known to inhibit gRNA dimerization, respectively. It shows the first evidence that gRNA dimerization can be inhibited by: 1) mutations in the N-terminus or the linker of retroviral NC; 2) mutations in the proximal zinc finger of lentiviral NC; 3) mutations in the hydrophobic patch or the conserved glycines of the proximal or the distal retroviral zinc finger. Some NC mutations impaired gRNA dimerization more than mutations inactivating the viral protease, indicating that gRNA dimerization may be stimulated by the NC component of the Gag polyprotein. Most, but not all, mutations inhibited gRNA packaging; some had a strong effect on virus assembly or stability.

In vitro dimerization of human immunodeficiency virus type 1 (HIV-1) spliced RNAs

The human immunodeficiency virus type 1 (HIV-1) packages its genomic RNA as a dimer of homologous RNA molecules that has to be selected among a multitude of cellular and viral RNAs. Interestingly, spliced viral mRNAs are packaged into viral particles with a relatively low efficiency despite the fact that they contain most of the extended packaging signal found in the 5' untranslated region of the genomic RNA, including the dimerization initiation site (DIS). As a consequence, HIV-1 spliced viral RNAs can theoretically homodimerize and heterodimerize with the genomic RNA, and thus they should directly compete with genomic RNA for packaging. To shed light on this issue, we investigated for the first time the in vitro dimerization properties of spliced HIV-1 RNAs. We found that singly spliced (env, vpr) and multispliced (tat, rev, and nef) RNA fragments are able to dimerize in vitro, and to efficiently form heterodimers with genomic RNA. Chemical probing experiments and inhibition of RNA dimerization by an antisense oligonucleotide directed against the DIS indicated that the DIS is structurally functional in spliced HIV-1 RNA, and that RNA dimerization occurs through a loop-loop interaction. In addition, by combining in vitro transcription and dimerization assays, we show that heterodimers can be efficiently formed only when the two RNA fragments are synthesized simultaneously, in the same environment. Together, our results support a model in which RNA dimerization would occur during transcription in the nucleus and could thus play a major role in splicing, transport, and localization of HIV-1 RNA.

Aminoglycoside binding to the HIV-1 RNA dimerization initiation site: thermodynamics and effect on the kissing-loop to duplex conversion

Owing to a striking, and most likely fortuitous, structural and sequence similarity with the bacterial 16 S ribosomal A site, the RNA kissing-loop complex formed by the HIV-1 genomic RNA dimerization initiation site (DIS) specifically binds 4,5-disubstituted 2-deoxystreptamine (2-DOS) aminoglycoside antibiotics. We used chemical probing, molecular modeling, isothermal titration calorimetry (ITC) and UV melting to investigate aminoglycoside binding to the DIS loop–loop complex. We showed that apramycin, an aminoglycoside containing a bicyclic moiety, also binds the DIS, but in a different way than 4,5-disubstituted 2-DOS aminoglycosides. The determination of thermodynamic parameters for various aminoglycosides revealed the role of the different rings in the drug–RNA interaction. Surprisingly, we found that the affinity of lividomycin and neomycin for the DIS (K_d ∼ 30 nM) is significantly higher than that obtained in the same experimental conditions for their natural target, the bacterial A site (K_d ∼ 1.6 µM). In good agreement with their respective affinity, aminoglycoside increase the melting temperature of the loop–loop interaction and also block the conversion from kissing-loop complex to extended duplex. Taken together, our data might be useful for selecting new molecules with improved specificity and affinity toward the HIV-1 DIS RNA.

Guanine tetrad and palindromic sequence play critical roles in the RNA dimerization of bovine foamy virus

Retroviruses are unique in having a diploid genome. However, the RNA sequences and structures that link the two RNA molecules are different. To identify the dimer linkage site of bovine foamy virus (BFV), complementary DNAs were used to interfere with RNA dimerization of BFV. We found that two sites, designated SI and SII, within a 53-base RNA fragment, were essential for BFV dimerization in vitro. SI consists of a potential guanine tetrad (GGGGC), which overlaps the primer binding site, while SII contains 15 nucleotides including a palindromic sequence, UCCCUAGGGA. Masking either of the sites completely abolished RNA dimer formation. Furthermore, a deletion of SII was introduced into a BFV infectious DNA clone; we found that deletion of SII significantly increased expression of BFV transactivator Borf-1. Interestingly, we also found that this deletion abolished viral infectivity. These results suggest that dimerization might play a unique role in the BFV life cycle.

HIV-2 RNA dimerization is regulated by intramolecular interactions in vitro

Genomic RNA dimerization is an essential process in the retroviral replication cycle. In vitro, HIV-2 RNA dimerization is mediated at least in part by direct intermolecular interaction at stem-loop 1 (SL1) within the 5'-untranslated leader region (UTR). RNA dimerization is thought to be regulated via alternate presentation and sequestration of dimerization signals by intramolecular base-pairings. One of the proposed regulatory elements is a palindrome sequence (pal) located upstream of SL1. To investigate the role of pal in the regulation of HIV-2 dimerization, we randomized this motif and selected in vitro for dimerization-competent and dimerization-impaired RNAs. Energy minimization folding analysis of these isolated sequences suggests the involvement of pal region in several short-distance intramolecular interactions with other upstream and downstream regions of the UTR. Moreover, the consensus predicted folding patterns indicate the altered presentation of SL1 depending on the interactions of pal with other regions of RNA. The data suggest that pal can act as a positive or negative regulator of SL1-mediated dimerization and that the modulation of base-pairing arrangements that affect RNA dimerization could coordinate multiple signals located within the 5'-UTR.

HIV-1 viral RNA is selected in the form of monomers that dimerize in a three-step protease-dependent process; the DIS of stem-loop 1 initiates viral RNA dimerization

We have characterized the viral RNA conformation in wild-type, protease-inactive (PR-) and SL1-defective (DeltaDIS) human immunodeficiency virus type 1 (HIV-1), as a function of the age of the viruses, from newly released to grown-up (>or=24 h old). We report evidence for packaging HIV-1 genomic RNA (gRNA) in the form of monomers in PR- virions, viral RNA rearrangement (not maturation) within PR- HIV-1, protease-dependent formation of thermolabile dimeric viral RNAs, a new form of immature gRNA dimer at about 5 h post virion release, and slow-acting dimerization signals in SL1-defective viruses. The rates of gRNA dimer formation were >or=3-fold and >or=10-fold slower in DeltaDIS and PR- viruses than in wild-type, respectively. Thus, the DIS, i.e. the palindrome in the apical loop of SL1, is a dimerization initiation signal, but its role can be masked by one or several slow-acting dimerization site(s) when grown-up SL1-inactive virions are investigated. Grown-up PR- virions are not flawless models for immature virions because gRNA dimerization increases with the age of PR- virions, indicating that the PR- mutation does not "freeze" gRNA conformation in a nascent primordial state. Our study is the first on gRNA conformation in newly released mutant or primate retroviruses. It shows for the first time that the packaged retroviral gRNA matures in more than one step, and that formation of immature dimeric viral RNA requires viral protein maturation. The monomeric viral RNAs isolated from budding HIV-1, as modeled by newly released PR- virions, may be seen as dimers that are much more fragile than thermolabile dimers.

Molecular dynamics simulation for probing the flexibility of the 35 nucleotide SL1 sequence kissing complex from HIV-1Lai genomic RNA

The SL1 stem-loop located in the encapsidation domain is responsible for initiating the dimerisation of HIV-1 genomic RNA by means of a loop-loop interaction known as Kissing Complex (KC). The SL1 secondary structure has been predicted as a 35 nucleotides [K. G. Murti, M. Bondurant, and A. Tereba. J Virol 37, 411-419 (1981)] stem-loop composed of a 4 base pairs (bp) terminal duplex, a 4 nt asymmetrical internal loop, a 7 bp internal duplex, and a 9 nt apical loop. Several high resolution structures of the monomer and of KC of a 23 nt sequence containing only the internal duplex and the apical loop of SL1 are available in the literature. No experimental high resolution structure of the complete native SL1 sequence has been reported so far, either for the monomer or for KC. The asymmetrical internal loop has been described from NMR studies of different monomeric hairpin sequences, leading to divergent results, which suggests its high flexibility. In this work, we built a SL1(35) KC model which was submitted to a 31 ns molecular dynamics simulation (MD). Our results allows to describe the internal dynamics of SL1(35) KC and the differences of behavior of the different parts of the dimer. Thus, we could show the stability of the interactions between the two apical loops and of the terminal duplexes, the destabilization of the internal duplexes and the high flexibility of the asymmetrical internal loops.