Loop and stem dynamics during RNA hairpin folding and unfolding

2-Aminopurine (2AP) is a fluorescent adenine analog that probes mainly base stacking in nucleic acids. We labeled the loop or the stem of the RNA hairpin gacUACGguc with 2AP to study folding thermodynamics and kinetics at both loci. Thermal melts and fast laser temperature jumps detected by 2AP fluorescence monitored the stability and folding/unfolding kinetics. The observed thermodynamic and kinetic traces of the stem and loop mutants, though strikingly different at a first glance, can be fitted to the same free-energy landscape. The differences between the two probe locations arise because base stacking decreases upon unfolding in the stem, whereas it increases in the loop. We conclude that 2AP is a conservative adenine substitution for mapping out the contributions of different RNA structural elements to the overall folding process. Molecular dynamics (MD) totaling 0.6 μsec were performed to look at the conformations populated by the RNA at different temperatures. The combined experimental data, and MD simulations lead us to propose a minimal four-state free-energy landscape for the RNA hairpin. Analysis of this landscape shows that a sequential folding model is a good approximation for the full folding dynamics. The frayed state formed initially from the native state is a heterogeneous ensemble of structures whose stem is frayed either from the end or from the loop.     

Base excision repair of oxidative DNA damage coupled with removal of a CAG repeat hairpin attenuates trinucleotide repeat expansion

Trinucleotide repeat (TNR) expansion is responsible for numerous human neurodegenerative diseases. However, the underlying mechanisms remain unclear. Recent studies have shown that DNA base excision repair (BER) can mediate TNR expansion and deletion by removing base lesions in different locations of a TNR tract, indicating that BER can promote or prevent TNR expansion in a damage location–dependent manner. In this study, we provide the first evidence that the repair of a DNA base lesion located in the loop region of a CAG repeat hairpin can remove the hairpin, attenuating repeat expansion. We found that an 8-oxoguanine located in the loop region of CAG hairpins of varying sizes was removed by OGG1 leaving an abasic site that was subsequently 5′-incised by AP endonuclease 1, introducing a single-strand breakage in the hairpin loop. This converted the hairpin into a double-flap intermediate with a 5′- and 3′-flap that was cleaved by flap endonuclease 1 and a 3′-5′ endonuclease Mus81/Eme1, resulting in complete or partial removal of the CAG hairpin. This further resulted in prevention and attenuation of repeat expansion. Our results demonstrate that TNR expansion can be prevented via BER in hairpin loops that is coupled with the removal of TNR hairpins.     

Structure and dynamics of the DNA hairpins formed by tandemly repeated CTG triplets associated with myotonic dystrophy.

Anomalous expansion of the DNA triplet (CTG)n causes myotonic dystrophy. Structural studies have been carried out on (CTG)n repeats in an attempt to better understand the molecular mechanism of repeat expansion. NMR and gel electrophoretic studies demonstrate the presence of hairpin structures for (CTG)5 and (CTG)6 in solution. The monomeric hairpin structure remains invariant over a wide range of salt concentrations (10-200 mM NaCl), DNA concentrations (micromolar to millimolar in DNA strand) and pH (6.0-7.5). The (CTG)n hairpin contains three bases in the loop when n is odd and four bases when n is even. For both odd and even n the stacking and pairing in the stem remain the same, i.e, two hydrogen bond T.T pairs stack with the neighboring G.C pairs. All the nucleotides in (CTG)5 and (CTG)6 adopt C2'-endo, anti conformations. Full-relaxation matrix analysis has been performed to derive the NOE distance constraints from NOESY experiments at seven different mixing times (25, 50, 75, 100, 125, 200 and 500 ms). NOESY-derived distance constraints were subsequently used in restrained molecular dynamics simulations to obtain a family of structures consistent with the NMR data. The theoretical order parameters are computed for H5-H6(cytosines) and H2'-H2" dipolar correlations for both (CTG)5 and (CTG)6 by employing the Lipari-Szabo formalism. Experimental data show that the cytosine in the loop of the (CTG)5 hairpin is slightly more flexible than those in the stem. The cytosine in the loop of the (CTG)6 hairpin is extremely flexible, implying that the dynamics of the four base loop is intrinsically different from that of the three base loop.     

Trinucleotide repeats associated with human disease.

Triplet repeat expansion diseases (TREDs) are characterized by the coincidence of disease manifestation with amplification of d(CAG. CTG), d(CGG.CCG) or d(GAA.TTC) repeats contained within specific genes. Amplification of triplet repeats continues in offspring of affected individuals, which generally results in progressive severity of the disease and/or an earlier age of onset, phenomena clinically referred to as 'anticipation'. Recent biophysical and biochemical studies reveal that five of the six [d(CGG)n, d(CCG)n, (CAG)n, d(CTG)n and d(GAA)n] complementary sequences that are associated with human disease form stable hairpin structures. Although the triplet repeat sequences d(GAC)n and d(GTC)n also form hairpins, repeats of the double-stranded forms of these sequences are conspicuously absent from DNA sequence databases and are not anticipated to be associated with human disease. With the exception of d(GAG)n and d(GTG)n, the remaining triplet repeat sequences are unlikely to form hairpin structures at physiological salt and temperature. The details of hairpin structures containing trinucleotide repeats are summarized and discussed with respect to potential mechanisms of triplet repeat expansion and d(CGG.CCG) n methylation/demethylation.     

Sequence length dictates repeated CAG folding in three-way junctions

The etiology of a large class of inherited neurological diseases is founded on hairpin structures adopted by repeated DNA sequences, and this folding is determined by base sequence and DNA context. Using single substitutions of adenine with 2-aminopurine, we show that intrastrand folding in repeated CAG trinucleotides is also determined by the number of repeats. This isomeric analogue has a fluorescence quantum yield that varies strongly with solvent exposure, thereby distinguishing particular DNA motifs. Prior studies demonstrated that (CAG)(8) alone favors a stem-loop hairpin, yet the same sequence adopts an open loop conformation in a three-way junction. This comparison suggests that repeat folding is disrupted by base pairing in the duplex arms and by purine-purine mismatches in the repeat stem. However, these perturbations are overcome in longer CAG repeats, as demonstrated by studies of isolated and integrated forms of (CAG)(15). The oligonucleotide alone forms a symmetrically folded hairpin with looplike properties exhibited by the relatively high emission intensities from a modification in the central eighth repeat and with stemlike properties evident from the relatively low emission intensities from peripheral modifications. Significantly, these hairpin properties are retained when (CAG)(15) is integrated into a duplex. Intrastrand folding by (CAG)(15) in the three-way junction contrasts with the open loop adopted by (CAG)(8) in the analogous context. This distinction suggests that cooperative interactions in longer repeat tracts overwhelm perturbations to reassert the natural folding propensity. Given that anomalously long repeats are the genetic basis of a large class of inherited neurological diseases, studies with (CAG)-based three-way junctions suggest that their secondary structure is a key factor in the length-dependent manifestation and progression of such diseases.     

Dynamics and stability of GCAA tetraloops with 2-aminopurine and purine substitutions

The contributions of various interactions in the GGCGCAAGCC hairpin containing a GCAA tetraloop were studied by computer simulations using the substitutions of functional groups. The guanosine (G) in the first tetraloop position or in the C-G closing base pair was replaced by 2-aminopurine (AP), and the individual tetraloop's adenosines (A) were replaced by purine (PUR). These substitutions eliminated particular hydrogen bonds thought to stabilize the GCAA tetraloop. For each substitution, molecular dynamics (MD) simulations were carried out in an aqueous solution with sodium counterions, using the CHARMM27 force field. The MD simulations showed that the substitutions in the first (G-->AP) and the third (A-->PUR) position of the GCAA tetraloop did not significantly influence the conformation of the hairpin. A long-lived bridging water molecule observed in the GCAA loop was present in both modified loops. The substitutions made in the last loop position (A-->PUR) or in the C-G base pair closing the tetraloop (G-->AP) to some extent influenced the loop structure and dynamics. These loops did not display the long-lived bridging water molecules. When the second A in the GCAA loop was replaced by PUR, the first A in the loop was observed in the anti or in the syn orientation about the glycosyl bond. The G to AP substitution in C-G base pair led to a change of their arrangement from the Watson-Crick to wobble. The MD simulations of the hairpin with C-AP wobble closing base pair showed increased conformational dynamics of the hairpin. The changes of hairpin formation free energy associated with the substitutions of individual bases were calculated by the free energy perturbation method. Our theoretical estimates suggest a larger destabilization for the G to AP substitutions in GCAA loop than for the substitutions of individual A's by PUR, which is in accordance with experimental tendency. The calculations predicted a similar free energy change for G to AP substitutions in the GCAA tetraloop and in the C-G closing base pair.     

Ultrafast fluorescence decay profiles reveal differential unstacking of 2-aminopurine from neighboring bases in single-stranded DNA-binding protein subsites

Gene 5 protein (g5p) is a dimeric single-stranded DNA-binding protein encoded by Ff strains of Escherichia coli bacteriophages. The 2-fold rotationally symmetric binding sites of a g5p dimer each bind to four nucleotides, and the dimers bind with high cooperativity to saturate antiparallel single-stranded DNA (ssDNA) strands. Ultrafast time-resolved fluorescence spectroscopies were used to investigate the conformational heterogeneity and dynamics of fluorescent 2-aminopurine (2AP) labels sequestered by bound g5p. The 2AP labels were positioned within the noncomplementary antiparallel tail sequences of d(AC)(8) or d(AC)(9) of hairpin constructs so that each fluorescent label could probe a different subsite location within the DNA-binding site of g5p. Circular dichroism and isothermal calorimetric titrations yielded binding stoichiometries of approximately six dimers per oligomer hairpin when tails were of these lengths. Mobility shift assays demonstrated the formation of a single type of g5p-saturated complex. Femtosecond time-resolved fluorescence spectroscopy showed that the 2AP in the free (non-protein-bound) DNAs had similar heterogeneous distributions of conformations. However, there were significant changes, dominated by a large increase in the population of unstacked bases from ~22 to 59-68%, depending on their subsite locations, when the oligomers were saturated with g5p. Anisotropy data indicated that 2AP in the bound state was less flexible than in the free oligomer. A control oligomer was labeled with 2AP in the loop of the hairpin and showed no significant change in its base stacking upon g5p binding. A proposed model summarizes the data.     

Dynamics and Stability of GCAA Tetraloops with 2-Aminopurine and Purine Substitutions

Abstract

The contributions of various interactions in the GGCGCAAGCC hairpin containing a GCAA tetraloop were studied by computer simulations using the substitutions of functional groups. The guanosine (G) in the first tetraloop position or in the C-G closing base pair was replaced by 2-aminopurine (AP), and the individual tetraloop's adenosines (A) were replaced by purine (PUR). These substitutions eliminated particular hydrogen bonds thought to stabilize the GCAA tetraloop. For each substitution, molecular dynamics (MD) simulations were carried out in an aqueous solution with sodium counterions, using the CHARMM27 force field. The MD simulations showed that the substitutions in the first (G→AP) and the third (A→PUR) position of the GCAA tetraloop did not significantly influence the conformation of the hairpin. A long-lived bridging water molecule observed in the GCAA loop was present in both modified loops. The substitutions made in the last loop position (A→PUR) or in the C-G base pair closing the tetraloop (G→AP) to some extent influenced the loop structure and dynamics. These loops did not display the long- lived bridging water molecules. When the second A in the GCAA loop was replaced by PUR, the first A in the loop was observed in the anti or in the syn orientation about the gly- cosyl bond. The G to AP substitution in C-G base pair led to a change of their arrangement from the Watson-Crick to wobble. The MD simulations of the hairpin with C-AP wobble closing base pair showed increased conformational dynamics of the hairpin. The changes of hairpin formation free energy associated with the substitutions of individual bases were calculated by the free energy perturbation method. Our theoretical estimates suggest a larger destabilization for the G to AP substitutions in GCAA loop than for the substitutions of individual A's by PUR, which is in accordance with experimental tendency. The calculations predicted a similar free energy change for G to AP substitutions in the GCAA tetraloop and in the C-G closing base pair.     

Srs2 helicase of Saccharomyces cerevisiae selectively unwinds triplet repeat DNA

Trinucleotide repeat expansions are the mutational cause of at least 15 genetic diseases. In vitro, single-stranded triplet repeat DNA forms highly stable hairpins, depending on repeat sequence, and a strong correlation exists between hairpin-forming ability and the risk of expansion in vivo. Hairpins are viewed, therefore, as likely mutagenic precursors to expansions. If a helicase unwinds the hairpin, it would be less likely to expand. Previous work indicated that yeast Srs2 DNA helicase selectively blocks expansions in vivo (Bhattacharyya, S., and Lahue, R. S. (2004) Mol. Cell. Biol. 24, 7324-7330). For example, srs2 mutants, including an ATPase-defective point mutant, exhibit substantially higher expansion rates than wild type controls. In contrast, mutation of another helicase gene, SGS1, had little effect on expansion rates. These findings prompted the idea that Srs2 might selectively unwind triplet repeat hairpins. In this study, DNA helicase assays were performed with purified Srs2, Sgs1, and Escherichia coli UvrD (DNA helicase II). Srs2 shows substantially faster unwinding than Sgs1 or UvrD on partial duplex substrates containing (CTG) x (CTG) sequences, provided that Srs2 encounters the triplet repeat DNA immediately on entering the duplex. Srs2 was also faster at unwinding (CAG) x (CAG)- and (CCG) x (CCG)-containing substrates and an intramolecular (CTG) x (CTG) hairpin. In contrast, all three enzymes unwind about equally well control substrates with either Watson-Crick base pairs or mismatched substrates with non-CNG repeats. Overall, the selective unwinding activity of Srs2 on triplet repeat hairpin DNA helps explain the genetic evidence that Srs2, not the RecQ homolog Sgs1, is a preferred helicase for preventing expansions.     

Small-molecule ligand induces nucleotide flipping in (CAG)n trinucleotide repeats

DNA trinucleotide repeats, particularly CXG, are common within the human genome. However, expansion of trinucleotide repeats is associated with a number of disorders, including Huntington disease, spinobulbar muscular atrophy and spinocerebellar ataxia. In these cases, the repeat length is known to correlate with decreased age of onset and disease severity. Repeat expansion of (CAG)n, (CTG)n and (CGG)n trinucleotides may be related to the increased stability of alternative DNA hairpin structures consisting of CXG-CXG triads with X-X mismatches. Small-molecule ligands that selectively bound to CAG repeats could provide an important probe for determining repeat length and an important tool for investigating the in vivo repeat extension mechanism. Here we report that napthyridine-azaquinolone (NA, 1) is a ligand for CAG repeats and can be used as a diagnostic tool for determining repeat length. We show by NMR spectroscopy that binding of NA to CAG repeats induces the extrusion of a cytidine nucleotide from the DNA helix.     

In vitro repair of DNA hairpins containing various numbers of CAG/CTG trinucleotide repeats

Expansion of CAG/CTG trinucleotide repeats (TNRs) in humans is associated with a number of neurological and neurodegenerative disorders including Huntington's disease. Increasing evidence suggests that formation of a stable DNA hairpin within CAG/CTG repeats during DNA metabolism leads to TNR instability. However, the molecular mechanism by which cells recognize and repair CAG/CTG hairpins is largely unknown. Recent studies have identified a novel DNA repair pathway specifically removing (CAG)(n)/(CTG)(n) hairpins, which is considered a major mechanism responsible for TNR instability. The hairpin repair (HPR) system targets the repeat tracts for incisions in the nicked strand in an error-free manner. To determine the substrate spectrum of the HPR system and its ability to process smaller hairpins, which may be the intermediates for CAG/CTG expansions, we constructed a series of CAG/CTG hairpin heteroduplexes containing different numbers of repeats (from 5 to 25) and examined their repair in human nuclear extracts. We show here that although repair efficiencies differ slightly among these substrates, removal of the individual hairpin structures all involve endonucleolytic incisions within the repeat tracts in the nicked DNA strand. Analysis of the repair intermediates defined specific incision sites for each substrate, which were all located within the repeat regions. Mismatch repair proteins are not required for, nor do they inhibit, the processing of smaller hairpin structures. These results suggest that the HPR system ensures CAG/CTG stability primarily by removing various sizes of (CAG)(n)/(CTG)(n) hairpin structures during DNA metabolism.     

Rapid unwinding of triplet repeat hairpins by Srs2 helicase of Saccharomyces cerevisiae

Expansions of trinucleotide repeats cause at least 15 heritable human diseases. Single-stranded triplet repeat DNA in vitro forms stable hairpins in a sequence-dependent manner that correlates with expansion risk in vivo. Hairpins are therefore considered likely intermediates during the expansion process. Unwinding of a hairpin by a DNA helicase would help protect against expansions. Yeast Srs2, but not the RecQ homolog Sgs1, blocks expansions in vivo in a manner largely dependent on its helicase function. The current study tested the idea that Srs2 would be faster at unwinding DNA substrates with an extrahelical triplet repeat hairpin embedded in a duplex context. These substrates should mimic the relevant intermediate structure thought to occur in vivo. Srs2 was faster than Sgs1 at unwinding several substrates containing triplet repeat hairpins or another structured loop. In contrast, control substrates with an unstructured loop or a Watson–Crick duplex were unwound equally well by both enzymes. Results with a fluorescently labeled, three-way junction showed that Srs2 unwinding proceeds unabated through extrahelical triplet repeats. In summary, Srs2 maintains its facile unwinding of triplet repeat hairpins embedded within duplex DNA, supporting the genetic evidence that Srs2 is a key helicase in Saccharomyces cerevisiae for preventing expansions.     

Hairpin structure-forming propensity of the (CCTG.CAGG) tetranucleotide repeats contributes to the genetic instability associated with myotonic dystrophy type 2

The genetic instabilities of (CCTG.CAGG)(n) tetranucleotide repeats were investigated to evaluate the molecular mechanisms responsible for the massive expansions found in myotonic dystrophy type 2 (DM2) patients. DM2 is caused by an expansion of the repeat from the normal allele of 26 to as many as 11,000 repeats. Genetic expansions and deletions were monitored in an African green monkey kidney cell culture system (COS-7 cells) as a function of the length (30, 114, or 200 repeats), orientation, or proximity of the repeat tracts to the origin (SV40) of replication. As found for CTG.CAG repeats related to DM1, the instabilities were greater for the longer tetranucleotide repeat tracts. Also, the expansions and deletions predominated when cloned in orientation II (CAGG on the leading strand template) rather than I and when cloned proximal rather than distal to the replication origin. Biochemical studies on synthetic d(CAGG)(26) and d(CCTG)(26) as models of unpaired regions of the replication fork revealed that d(CAGG)(26) has a marked propensity to adopt a defined base paired hairpin structure, whereas the complementary d(CCTG)(26) lacks this capacity. The effect of orientation described above differs from all previous results with three triplet repeat sequences (including CTG.CAG), which are also involved in the etiologies of other hereditary neurological diseases. However, similar to the triplet repeat sequences, the ability of one of the two strands to form a more stable folded structure, in our case the CAGG strand, explains this unorthodox "reversed" behavior.     

Effects of base substitutions in an RNA hairpin from molecular dynamics and free energy simulations

Contributions of individual interactions in the GGCGCAAGCC hairpin containing a GCAA tetraloop were studied by computer simulations using base substitutions. The G in the first tetraloop position was replaced by inosine (I) or adenosine (A), and the G in the C-G basepair closing the tetraloop was replaced by I. These substitutions eliminate particular hydrogen bonds proposed in the nuclear magnetic resonance model of the GCAA tetraloop. Molecular dynamics simulations of the GCAA tetraloop in aqueous solvent displayed a well-defined hydrogen pattern between the first and last loop nucleotides (G and A) stabilized by a bridging water molecule. Substitution of G-->I in the basepair closing the tetraloop did not significantly influence the loop structure and dynamics. The ICAA loop maintained the overall structure, but displayed variation in the hydrogen-bond network within the tetraloop itself. Molecular dynamics simulations of the ACAA loop led to conformational heterogeneity of the resulting structures. Changes of hairpin formation free energy associated with substitutions of individual bases were calculated by the free energy perturbation method. The calculated decrease of the hairpin stability upon G-->I substitution in the C-G basepair closing the tetraloop was in good agreement with experimental thermodynamic data. Our theoretical estimates for G-->I and G-->A mutations located in the tetraloop suggest larger loop destabilization than corresponding experimental results. The extent of conformational sampling of the structures resulting from base substitutions and its impact on the calculated free energy was discussed.     

DNA polymerase θ promotes CAG•CTG repeat expansions in Huntington’s disease via insertion sequences of its catalytic domain

Huntington''s disease (HD), a neurodegenerative disease characterized by progressive dementia, psychiatric problems, and chorea, is known to be caused by CAG repeat expansions in the HD gene HTT. However, the mechanism of this pathology is not fully understood. The translesion DNA polymerase θ (Polθ) carries a large insertion sequence in its catalytic domain, which has been shown to allow DNA loop-outs in the primer strand. As a result of high levels of oxidative DNA damage in neural cells and Polθ''s subsequent involvement in base excision repair of oxidative DNA damage, we hypothesized that Polθ contributes to CAG repeat expansion while repairing oxidative damage within HTT. Here, we performed Polθ-catalyzed in vitro DNA synthesis using various CAG•CTG repeat DNA substrates that are similar to base excision repair intermediates. We show that Polθ efficiently extends (CAG)_n•(CTG)_n hairpin primers, resulting in hairpin retention and repeat expansion. Polθ also triggers repeat expansions to pass the threshold for HD when the DNA template contains 35 repeats upward. Strikingly, Polθ depleted of the catalytic insertion fails to induce repeat expansions regardless of primers and templates used, indicating that the insertion sequence is responsible for Polθ''s error-causing activity. In addition, the level of chromatin-bound Polθ in HD cells is significantly higher than in non-HD cells and exactly correlates with the degree of CAG repeat expansion, implying Polθ''s involvement in triplet repeat instability. Therefore, we have identified Polθ as a potent factor that promotes CAG•CTG repeat expansions in HD and other neurodegenerative disorders.     

Secondary structure and dynamics of the r(CGG) repeat in the mRNA of the fragile X mental retardation 1 (FMR1) gene.

The CGG triplet repeat found within the 5'UTR of the FMR1 gene is involved in the pathogenesis of both fragile X syndrome and fragile X-associated tremor/ataxia syndrome (FXTAS). The repeat has been shown to form both hairpins and tetraplexes in DNA; however, the secondary structure of CGG-repeat RNA has not been well defined. To this end, we have performed NMR spectroscopy on in vitro transcribed CGG-repeat RNAs and see clear evidence of intramolecular hairpins, with no evidence of tetraplex structures. Both C*G and G*G base pairs form in the hairpin stem, though in a dynamic equilibrium of conformations. In addition, we investigated the effect of an AGG repeat interruption on hairpin stability; such interruptions are often interspersed within the CGG repeat element and are thought to modulate secondary structure of the RNA. While the AGG repeat lowers the Tm of the hairpin at low Mg2+ concentrations, this difference disappears at physiological Mg2+ levels.     

Twisting Right to Left: A…A Mismatch in a CAG Trinucleotide Repeat Overexpansion Provokes Left-Handed Z-DNA Conformation

Conformational polymorphism of DNA is a major causative factor behind several incurable trinucleotide repeat expansion disorders that arise from overexpansion of trinucleotide repeats located in coding/non-coding regions of specific genes. Hairpin DNA structures that are formed due to overexpansion of CAG repeat lead to Huntington’s disorder and spinocerebellar ataxias. Nonetheless, DNA hairpin stem structure that generally embraces B-form with canonical base pairs is poorly understood in the context of periodic noncanonical A…A mismatch as found in CAG repeat overexpansion. Molecular dynamics simulations on DNA hairpin stems containing A…A mismatches in a CAG repeat overexpansion show that A…A dictates local Z-form irrespective of starting glycosyl conformation, in sharp contrast to canonical DNA duplex. Transition from B-to-Z is due to the mechanistic effect that originates from its pronounced nonisostericity with flanking canonical base pairs facilitated by base extrusion, backbone and/or base flipping. Based on these structural insights we envisage that such an unusual DNA structure of the CAG hairpin stem may have a role in disease pathogenesis. As this is the first study that delineates the influence of a single A…A mismatch in reversing DNA helicity, it would further have an impact on understanding DNA mismatch repair.     

Modeling the dynamics of a mutated stem-loop in the SL1 domain of HIV-1Lai genomic RNA by 1H-NOESY spectra

The cross-peaks of ¹H-NOESY spectra at different time delays are compared to a mode-coupling diffusion (MCD) calculation, including the evaluation of the full ¹H relaxation matrix, in the case of a 23 nucleotide fragment of the stem-loop SL1 domain of HIV-1_Lai genomic RNA mutated in a single position. The MCD theory gives significant agreement with ¹H relaxation experiments enabling a thorough understanding of the differential local dynamics along the sequence and particularly of the dynamics of nucleotides in the stem and in the loop. The differential dynamics of this hairpin structure is important in directing the dimerization of the retroviral genome, a fundamental step in the infectious process. The demonstration of a reliable use of time dependent NOE cross-peaks, largely available from NMR solution structure determination, coupled to MCD analysis, to probe the local dynamics of biological macromolecules, is a result of general interest of this paper.