RNA loop–loop interactions are essential for genomic RNA dimerization and regulation of gene expression. In this article, a statistical mechanics-based computational method that predicts the structures and thermodynamic stabilities of RNA complexes with loop–loop kissing interactions is described. The method accounts for the entropy changes for the formation of loop–loop interactions, which is a notable advancement that other computational models have neglected. Benchmark tests with several experimentally validated systems show that the inclusion of the entropy parameters can indeed improve predictions for RNA complexes. Furthermore, the method can predict not only the native structures of RNA/RNA complexes but also alternative metastable structures. For instance, the model predicts that the SL1 domain of HIV-1 RNA can form two different dimer structures with similar stabilities. The prediction is consistent with experimental observation. In addition, the model predicts two different binding sites for hTR dimerization: One binding site has been experimentally proposed, and the other structure, which has a higher stability, is structurally feasible and needs further experimental validation

Cao, Song

Chen, Shijie

Xu, Xiaojun

PubMed

RNA loop–loop interactions are essential for genomic RNA dimerization and regulation of gene expression. In this article, a statistical mechanics-based computational method that predicts the structures and thermodynamic stabilities of RNA complexes with loop–loop kissing interactions is described. The method accounts for the entropy changes for the formation of loop–loop interactions, which is a notable advancement that other computational models have neglected. Benchmark tests with several experimentally validated systems show that the inclusion of the entropy parameters can indeed improve predictions for RNA complexes. Furthermore, the method can predict not only the native structures of RNA/RNA complexes but also alternative metastable structures. For instance, the model predicts that the SL1 domain of HIV-1 RNA can form two different dimer structures with similar stabilities. The prediction is consistent with experimental observation. In addition, the model predicts two different binding sites for hTR dimerization: One binding site has been experimentally proposed, and the other structure, which has a higher stability, is structurally feasible and needs further experimental validation.</jats:p

Song Cao

Xiaojun Xu

Shi-Jie Chen

Crossref

Predicting structure and stability for RNA complexes with intermolecular loop–loop base-pairing

Digital Commons@Becker

Supplemental Material:Predicting Structure and Stability for RNA Complexes with Intermolecular Loop-loopBase PairingSong CAO, Xiaojun XU and Shi-Jie CHENDepartment of Physics and Department of BiochemistryUniversity of Missouri, Columbia, MO 65211[1] Virtual bond representation and loop entropy calculationDue to the rotameric nature of RNA backbone torsional angles, the original six-bond nucleotide can be reducedto a two-bond system, where each bond is a virtual bond (Fig.1). In the Vfold model we compute the conformationalentropy by enumerating the virtual bond conformations (Fig. 1). In the current version of the Vfold model, the virtualbonds are configured on a diamond lattice with three equiprobable torsional angles (60◦, 180◦, 300◦) and fixed bondlength of 3.9 A˚ and bond angle of 109.47o .An advantage of the model for the loop entropy calculation is the ability to account for chain connectivity, excludedvolume effect and completeness of the conformational ensemble. With the Vfold model, we have computed theentropy parameters for several RNA motifs, such as hairpin loops, internal loops, bulge loops, H-type pseudoknotsand hairpin-hairpin kissing motifs:1. Hairpin, internal and bulge loops, in Ref [1];2. Pseudoknots without inter-helix junction, in Ref [2];3. Pseudoknots with inter-helix junction, in Ref [3];4. Hairpin-hairpin kissing, in Ref [4].[2] Partition functionBased on a recursive algorithm1−4, we compute the partition function for all the possible secondary and pseudo-knotted structures from the sequence. For each given structure, the helix free energy is computed from the empiricalthermodynamic parameters of the base stacks (Turner rules) and the loop free energies are calculated from the Vfoldmodel.For the loop treatment, the Vfold model distinguishes itself from other models by accounting for the intraloopmismatched base stacking interactions. The formation of intraloop stacks can cause significant constraint in loopconformation and a resultant reduction of conformational entropy. For given intraloop stacks, We use the Turnerrules to determine the free energy of the mismatched base stacks and use the Vfold model to compute the loop en-tropy. Depending on the loop sequence, such Vfold-predicted loop entropy parameters could be different from theexperimentally measured loop entropy parameters, which is the Boltzmann average over all the possible intraloopbase stacks. The partition function of a loop (see Fig. S1) is calculated as the sum over all the possible intra-loopmismatched base stacks. Such Vfold-predicted loop free energy can be temperature and sequence dependent.From the partition function Q(T ), we can calculate the heat capacity C(T) melting curves: C(T ) = ∂∂T[kBT2 ∂∂TlnQ(T )].Furthermore, from the conditional partition function Q(i, j, T ) for the ensemble of conformations with base pair (i, j),we compute the probability Pij(T ) for the formation of the (i, j) pair: Pij(T ) = Q(i, j, T )/Q(T ). From the distribu-tion of the base-pairing probability, we can deduce the stable structures at temperature T.S1The computational time scales with the chain length N as O(N6) and the memory scales as O(N2).A    UA    UA    UA    UA    UA    UA    UA    UAUAGCAGCACUCCACAGCCCUhairpin_9A AGUC C CACU CCCCCCCCGCCC C   CA    UA    UA    CC    GU    GA    AA    CU    Amismatch       +       +hairpin_4bulge_1mismatch       +hairpin_3       +internal_2mismatch       +hairpin_3       +bulge_2mismatch       +hairpin_7AUCA...Figure S1: In the Vfold model, we enumerate all the possible structures (see the left panel) that contain secondary/pseudoknotstructures using a recursive algorithm. Helix free energies are calculated from the Turner’s thermodynamic parameters and loopfree energies are computed from the partition function over all the possible arrangements of the intra-loop mismatched basestacks for a given loop sequence. Here, we show an example of a hairpin of size 9 nts closed by a A-U base pair. The ensembleof the loop conformations contains 5 different arrangements of mismatched base stacks within the loop, as shown in the rightpanel.S2[3] Additional experimental tests for the Vfold modelWe calculated the stabilities for three small RNA systems[5] using the Vfold model and compare the results withthe experimental data as well as the RNAfold predictions. The stacking energy parameters used in Vfold is from theTurner rule with 1M NaCl, while the experimental data is for the 150 mM NaCl and 10 mM Na2HPO4. Anotherpossible source for the inaccuracy of the models may come from the intraloop noncanonical interactions (beyondmismatched base stacks). A more accurate model should consider these effects.Overall, RNAfold and Vfold give close results for the stabilities of the bistable RNAs. For sequence 4, the energydifference between the two (bistable) states is 1.73 kBT (from the experimental result and from the RNAfold), whileVfold predicts 0.41 kBT. The slight difference between Vfold and RNAfold for the three RNAs may come from thedifferent energy parameters for the loops.Table S1: Comparison of the stabilities predicted by the Vfold with the experimental results and the RNAfold resultsfor three bistable RNAs [5]. Sequence 3, 4 and 5 denote the RNAs (no. 3, 4 and 5) studied in Ref [5]. The ratios n:min the table are the relative populations of the bistable states as determined from the experiment, the RNAfold modeland the Vfold model, respectively.Sequence Exp. ratio RNAfold Vfold3 50:50 8:92 22:784 85:15 85:15 60:405 45:55 21:79 21:79Table S2: The size-dependent (sequence-independent) entropy parameters (∆S/kB , which is dimensionless) forhairpin, bulge and internal loops derived from the Vfold model.Size Hairpin Bulge Internal1 - -5.87 -2 - -6.64 -8.743 -7.28 -7.47 -9.194 -7.35 -7.81 -9.145 -7.90 -8.25 -9.276 -8.09 -8.51 -9.347 -8.41 -8.78 -9.458 -8.61 -9.01 -9.559 -8.82 -9.21 -9.66S3Table S3: Using bulge loop as a simple test for the approximation that we have used in the entropy calculation fora multi-branched kissing loop: replacing the helix terminal base pair in the loop with a single nucleotide. With thisapproximation, an n-nt bulge loop turns into an (n+ 1)-nt hairpin loop. In the table, ∆∆S/kB denotes the differencebetween the entropies of the bulge and of the hairpin loops. |∆∆S/∆Sbulge| is the relative error. In our calculation,we use the approximation only for multibranched kissing loops, for which the approximation is necessary for theentropy calculation.. For simple hairpin, bulge and internal loops, we use the rigorous entropy values without usingthe approximation.Bulge Hairpin |∆∆S/kB | |∆∆S/∆Sbulge|2 3 0.64 0.0963 4 0.12 0.0164 5 0.09 0.0115 6 0.16 0.0196 7 0.10 0.0117 8 0.17 0.0198 9 0.19 0.021Table S4: A simple test similar to the one shown in Table S3. Here we use internal loop instead of bulge loop as thetest case. With the appoximation, an internal loop of size n is converted into a hairpin loop of size of n+1.Internal Hairpin |∆∆S/kB| |∆∆S/∆Sinternal|2 3 1.46 0.1673 4 1.84 0.2004 5 1.24 0.1355 6 1.18 0.1276 7 0.93 0.0997 8 0.84 0.0888 9 0.73 0.076S4Table S5: A simple test for the effect of helix migration on loop entropy. The entropy difference ∆∆S/kB betweena bulge loop and an internal loops of the same size. The entropy parameters ∆S/kB are from Table S2. The thirdcolumn shows the relative error.Size |∆∆S/kB | |∆∆S/∆Sinternal|2 2.10 0.2403 1.72 0.1874 1.33 0.1455 1.02 0.1106 0.83 0.0887 0.67 0.0708 0.54 0.056Table S6: A simple test for the effect of helix migration on loop entropy, specifically, for the effect of relative position(l1, l2) between the helices in an internal loop with size l1 + l2 = 6. ∆∆S/kB is the entropy difference between the(l1, l2) internal loop and the entropy parameter (in Table S2) for a 6-nt internal loop averaged over all the possible (l1,l2) values.l1 l2 ∆S/kB |∆∆S/kB | |∆∆S/∆Saverage|1 5 -9.51 0.17 0.0182 4 -9.33 0.01 0.0013 3 -9.24 0.10 0.0114 2 -9.21 0.13 0.0145 1 -9.39 0.05 0.005Average -9.34 0.09 0.010S5l2l1 internal loophelixhelixFigure S2: A schematic diagram for an internal loop of size (l1+l2).S637   C 50   C37   C 50   CStrand concentration (nM)Binding site 1Binding site 2Strand concentration (nM)Binding site 1Binding site 2Strand concentration (nM)Binding site 180   CBinding site 2Strand concentration (nM)80   C(a) (b) (c)(d) (e) (f)IIa/IIa−14tfhlA/OxyS fhlA/OxyS fhlA/OxySIIa/IIa−14t IIa/IIa−14tPopulation of complexPopulation of complex 0.4 0.6 0.8 1 1  10  100  1000 1  10  100  1000 0.0002 0.0004 0.0006 0 0.4 0.2 0.6 0.8 1 0 1  100  1000 10  1  10  100  1000 0 0.1 0.2 0.3 0.4 1  10  100  1000 0.0004 0.0003 0.0002 0.0001 0 0.4 0.6 0.8 1 0 0.2 1  10  100  1000Figure S3: The predicted fractional population of the RNA/RNA complex at the different temperatures. (a), (b) and (c) are theresults for the IIa/IIa-14t complex and (d), (e) and (f) are for the fhlA/OxyS complex. The RNA strand concentration ranges from1 nM to 1000 nM in the calculation.S70 10 20 30 40 500.00.10.20.30.40.50.60.7Nth binding modeProbabilityFigure S4: The probability distribution of the 52 binding modes identified by the model for the IIa/IIa-14t complex. Thefigure shows that there exists a single overwhelmingly dominant binding mode (binding site). This allows us to use the two-step process for structure prediction, namely, to identify the most probable binding site first, then predict the structure of theRNA-RNA complex with the dominant binding site.S8References[1] Cao, S. & Chen, S.-J. (2005). Predicting RNA folding thermodynamics with a reduced chain representationmodel. RNA, 11: 1884-1897.[2] Cao, S. & Chen, S.-J. (2006). Predicting RNA pseudoknot folding thermodynamics. Nucleic Acids Res., 34:2634-2652.[3] Cao, S. & Chen, S.-J. (2009). Predicting structures and stabilities for H-type pseudoknots with inter-helix loop.RNA, 15: 696-706.[4] Cao, S. & Chen, S.-J. (2011). Structure and stability of RNA/RNA kissing complex: with application to HIVdimerization initiation signal. RNA, 17: 2130-2143.[5] Hobartner C. & Micura R. (2003). Bistable secondary structures of small RNAs and their structural probing bycomparative imino proton NMR spectroscopy. J. Mol. Biol., 325: 421-431.S9

Predicting structure and stability for RNA complexes with intermolecular loop–loop base-pairing

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