Sequence-dependent structural dynamics of primate adenosine-to-inosine editing substrates.

Humans have the highest level of adenosine-to-inosine (A-to-I) editing amongst primates, yet the reasons for this difference remain unclear. Sequence analysis of the Alu Sg elements (A-to-I RNA substrates) corresponding to the Nup50 gene in human, chimp, and rhesus reveals subtle sequence variations surrounding the edit sites. We have developed three constructs that represent human (HuAp5), chimp (ChAp5), and rhesus (RhAp5) Nup50 Alu Sg A-to-I editing substrates. Here, 2-aminopurine (2-Ap) was substituted for edited adenosine (A5) so as to monitor the fluorescence intensity with respect to temperature. UV and steady-state fluorescence (SSF) T(M) plots indicate that local and global unfolding are coincident, with the human construct displaying a T(M) of approximately 70°C, compared to 60°C for chimp and 54°C for rhesus. However, time-resolved fluorescence (TRF) resolves three different fluorescence lifetimes that we assign to folded, intermediate(s), and unfolded states. The TRF data fit well to a two-intermediate model, whereby both intermediates (M, J) are in equilibrium with each other, and the folded/unfolded states. Our model suggests that, at 37°C, human state J and the folded state will be the most heavily populated in comparison to the other primate constructs. In order for adenosine deaminase acting on RNA (ADAR) to efficiently dock, a stable duplex must be present that corresponds to the human construct, globally. Next, the enzyme must "flip out" the base of interest to facilitate the A-to-I conversion; a nucleotide in an intermediate-like position would enhance this conformational change. Our experiments demonstrate that subtle variations in RNA sequence might contribute to the high A-to-I editing levels found in humans.

Impact of the N5-proximal Asn on the thermodynamic and kinetic stability of the semiquinone radical in photolyase.

Flavoproteins can dramatically adjust the thermodynamics and kinetics of electron transfer at their flavin cofactor. A versatile regulatory tool is proton transfer. Here, we demonstrate the significance of proton-coupled electron transfer to redox tuning and semiquinone (sq) stability in photolyases (PLs) and cryptochromes (CRYs). These light-responsive proteins share homologous overall architectures and FAD-binding pockets, yet they have evolved divergent functions that include DNA repair, photomorphogenesis, regulation of circadian rhythm, and magnetoreception. We report the first measurement of both FAD redox potentials for cyclobutane pyrimidine dimer PL (CPD-PL, Anacystis nidulans). These values, E(1)(hq/sq) = -140 mV and E(2)(sq/ox) = -219 mV, where hq is FAD hydroquinone and ox is oxidized FAD, establish that the sq is not thermodynamically stabilized (ΔE = E(2) - E(1) = -79 mV). Results with N386D CPD-PL support our earlier hypothesis of a kinetic barrier to sq oxidation associated with proton transfer. Both E(1) and E(2) are upshifted by ∼ 100 mV in this mutant; replacing the N5-proximal Asn with Asp decreases the driving force for sq oxidation. However, this Asp alleviates the kinetic barrier, presumably by acting as a proton shuttle, because the sq in N386D CPD-PL oxidizes orders of magnitude more rapidly than wild type. These data clearly reveal, as suggested for plant CRYs, that an N5-proximal Asp can switch on proton transfer and modulate sq reactivity. However, the effect is context-dependent. More generally, we propose that PLs and CRYs tune the properties of their N5-proximal residue to adjust the extent of proton transfer, H-bonding patterns, and changes in protein conformation associated with electron transfer at the flavin.

Folding kinetics of recognition loop peptides from a photolyase and cryptochrome-DASH.

Cryptochromes (CRY) and photolyases (PL) use a common flavin adenine dinucleotide cofactor and homologous protein scaffold to accomplish numerous, seemingly dissimilar functions. PL repairs UV-damaged DNA in a mechanism requiring light and DNA base flipping. CRY cannot repair DNA, and instead function in core biological processes including plant photomorphogenesis, circadian rhythm, and magnetoreception. One subclass, CRY-DASH, does catalyze repair of single-stranded DNA; compromised base flipping may deactivate its tight binding to duplex DNA substrates. We recently demonstrated that the a "recognition loop" involved in DNA binding by both PL and CRY-DASH is among the most flexible regions in the two proteins, and exhibits especially heightened dynamics in CRY-DASH. Here, we establish that these distinct dynamics are encoded by the loop sequences: we quantify the flexibility of the isolated loop peptides through the kinetics and activation parameters for their folding. Mirroring the dynamics within the proteins, the CRY-DASH recognition loop peptide folds 2.5-fold faster than its counterpart in PL, predominantly due to a lower enthalpy of activation. We propose that these distinct dynamics are functionally significant in DNA recognition. Binding duplex DNA in the catalytically-active base-flipped conformation imposes significant order on the recognition loop, and a corresponding entropic penalty. This may be surmounted by the more preorganized PL recognition loop, but may impose too large a barrier for the more dynamic loop in CRY-DASH. These results suggest that evolution of protein dynamics, through local sequence tuning in the recognition loop, may be an important mechanism for functional diversification in PL and CRY.

Kinetic stability of the flavin semiquinone in photolyase and cryptochrome-DASH.

Photolyases and cryptochromes (CRY) are structurally homologous flavoproteins with divergent functions. While photolyases repair UV-damaged DNA by photoinduced electron transfer from their FAD cofactor, CRY are involved in varied cellular processes, including light-dependent plant growth, regulation of mammalian circadian rhythm, and possibly magnetoreception. Despite their importance in Nature and human health, little is known about how they tune their FAD redox properties to achieve remarkable functional diversity. In this study, we reveal a kinetic mechanism, exploited by cyclobutane pyrimidine dimer photolyase (PL), for regulating the stability of its FAD semiquinone (sq). We find that the sq in CRY-DASH (Synechocystis) is substantially more reactive toward oxidation than in PL (Anacystis nidulans) and, using deuterium isotope and pH effects, show that rate-limiting proton transfer contributes to the exceptional kinetic stability of the PL sq. Through mutagenesis, we identify two PL-specific residues in the flavin binding pocket, Trp392 and Gly389 (Try398 and Asn395 in CRY-DASH, respectively), that ensure this kinetic stability, possibly through interactions with the adenine moiety of FAD and/or adjusting the polarity of the binding site. Significantly, these relatively distal residues have a much more profound impact than two amino acids closer to the FAD. By quantifying sq stability in a series of PL-CRY exchange mutants, our findings pave the way for investigations aimed at correlating sq stability with function in these proteins. As is being recognized with other flavoproteins, we expect that kinetic tuning of the rates of electron transfer will play a function-defining role in photolyases and cryptochromes.

Sequence-dependent folding and unfolding of ligand-bound purine riboswitches.

Riboswitch regulation of gene expression requires ligand-mediated RNA folding. From the fluorescence lifetime distribution of bound 2-aminopurine ligand, we resolve three RNA conformers (C(o), C(i), C(c)) of the liganded G- and A-sensing riboswitches from Bacillus subtilis. The ligand binding affinities, and sensitivity to Mg(2+), together with results from mutagenesis, suggest that C(o) and C(i) are partially unfolded species compromised in key loop-loop interactions present in the fully folded C(c). These data verify that the ligand-bound riboswitches may dynamically fold and unfold in solution, and reveal differences in the distribution of folded states between two structurally homologous purine riboswitches: Ligand-mediated folding of the G-sensing riboswitch is more effective, less dependent on Mg(2+), and less debilitated by mutation, than the A-sensing riboswitch, which remains more unfolded in its liganded state. We propose that these sequence-dependent RNA dynamics, which adjust the balance of ligand-mediated folding and unfolding, enable different degrees of kinetic discrimination in ligand binding, and fine-tuning of gene regulatory mechanisms.

Distinct recognition loop dynamics in cryptochrome-DASH and photolyase revealed by limited proteolysis.

Cryptochromes (CRY) are light-responsive flavoproteins that play central roles in nature and human health, including circadian rhythm regulation. They are closely related to photolyases (PL), but, unlike PL, they cannot repair cyclobutane pyrimidine dimers (CPD) or [6-4] photoproducts in duplex DNA. Yet, if the barrier for flipping the CPD from the duplex is reduced, CRY-DASH, the subclass most structurally homologous to CPD PL, binds and repairs CPD like PL. Here, using limited proteolysis, we have identified the most flexible loops in CPD PL. One corresponds to a "recognition loop" that changes conformation substantially during substrate binding, and engages key interactions with the flipped CPD and the complementary DNA strand. Proteolysis kinetics reveal that the homologous loop in CRY-DASH is at least 10-fold more reactive. We propose that heightened dynamics of the recognition loop in CRY-DASH contribute to its compromised DNA base flipping, and its evolution of divergent function from PL.

Ligand-interaction kinetics of the pheromone- binding protein from the gypsy moth, L. dispar: insights into the mechanism of binding and release.

The pheromone-binding proteins (PBPs), which exist at a high concentration in the sensillum lymph surrounding olfactory neurons, are proposed to be important in pheromone detection and discrimination in insects. Here, we present a systematic study of PBP-ligand interaction kinetics. We find that PBP2, from the gypsy moth, Lymantria dispar, associates and dissociates slowly with its biofunctional ligands, (+)- and (-)-disparlure. Tryptophan anisotropy measurements detect PBP multimers in solution as well as an increase in the multimeric state of the protein upon long exposure to ligand. We propose a kinetic model that includes monomer/multimer equilibria and a two-step binding process: (1) external binding of the pheromone assisted by the C terminus of PBP2, and (2) slow embedding of the pheromone into the internal pocket. This experimentally derived model sheds light on the potential biological function and mechanism of PBPs as ligand scavengers.

Substrate directs enzyme dynamics by bridging distal sites: UDP-galactopyranose mutase.

UDP-Galactopyranose mutase (UGM) is a flavoenzyme that catalyzes interconversion of UDP-galactopyranose (UDP-Galp) and UDP-galactofuranose (UDP-Galf); its activity depends on FAD redox state. The enzyme is vital to many pathogens, not native to mammals, and is an important drug target. We have probed binding of substrate, UDP-Galp, and UDP to wild type and W160A UGM from K. pneumoniae, and propose that substrate directs recognition loop dynamics by bridging distal FAD and W160 sites; W160 interacts with uracil of the substrate and is functionally essential. Enhanced Trp fluorescence upon substrate binding to UGM indicates conformational changes remote from the binding site because the fluorescence is unchanged upon binding to W70F/W290F UGM where W160 is the sole Trp. MD simulations map these changes to recognition loop closure to coordinate substrate. This requires galactose-FAD interactions as Trp fluorescence is unchanged upon substrate binding to oxidized UGM, or binding of UDP to either form of the enzyme, and MD show heightened recognition loop mobility in complexes with UDP. Consistent with substrate-directed loop closure, UDP binds 10-fold more tightly to oxidized UGM, yet substrate binds tighter to reduced UGM. This requires the W160-U interaction because redox-switched binding affinity of substrate reverses in the W160A mutant where it only binds when oxidized. Without the anchoring W160-U interaction, an alternative binding mode for UDP is detected, and STD-NMR experiments show simultaneous binding of UDP-Galp and UDP to different subsites in oxidized W160A UGM: Substrate no longer directs recognition loop dynamics to coordinate tight binding to the reduced enzyme.

Long-range oxidative damage to cytosines in duplex DNA.

Charge transport (CT) through DNA has been found to occur over long molecular distances in a reaction that is sensitive to intervening structure. The process has been described mechanistically as involving diffusive charge-hopping among low-energy guanine sites. Using a kinetically fast electron hole trap, N(4)-cyclopropylcytosine ((CP)C), here we show that hole migration must involve also the higher-energy pyrimidine bases. In DNA assemblies containing either [Rh(phi)(2)(bpy')](3+) or an anthraquinone derivative, two high-energy photooxidants, appreciable oxidative damage at a distant (CP)C is observed. The damage yield is modulated by lower-energy guanine sites on the same or complementary strand. Significantly, the efficiency in trapping at (CP)C is equivalent to that at N(2)-cyclopropylguanosine ((CP)G). Indeed, even when (CP)G and (CP)C are incorporated as neighboring bases on the same strand, their efficiency of photodecomposition is comparable. Thus, CT is not simply a function of the relative energies of the isolated bases but instead may require orbital mixing among the bases. We propose that charge migration through DNA involves occupation of all of the DNA bases with radical delocalization within transient structure-dependent domains. These delocalized domains may form and break up transiently, facilitating and limiting CT. This dynamic delocalized model for DNA CT accounts for the sensitivity of the process to sequence-dependent DNA structure and provides a basis to reconcile and exploit DNA CT chemistry and physics.

DNA-mediated charge transport requires conformational motion of the DNA bases: elimination of charge transport in rigid glasses at 77 K.

We have proposed that DNA-mediated charge transport (CT) is gated by base motions, with only certain base conformations being CT-active; a CT-active conformation can be described as a domain, a transiently extended pi-orbital defined dynamically by DNA sequence. Here, to explore these CT-active conformations, we examine the yield of base-base CT between photoexcited 2-aminopurine (Ap*) and guanine in DNA in rigid LiCl glasses at 77 K, where conformational rearrangement is effectively eliminated. Duplex DNA assemblies (35-mers) were constructed containing adenine bridges Ap(A)nG (n = 0-4). The yield of CT was monitored through fluorescence quenching of Ap* by G. We find, first, that the emission intensity of Ap* in all DNA duplexes increases dramatically upon cooling and becomes comparable to free Ap*. This indicates that all quenching of Ap* in duplex DNA is a dynamic process that requires conformational motion of the DNA bases. Second, DNA-mediated CT between Ap* and G is not observed at 77 K; rather than hindering the ability of DNA to transport charge, conformational motion is required. Moreover, the lack of DNA-mediated CT at 77 K, even through the shortest bridge, suggests that the static structures adopted upon cooling do not represent optimum CT-active conformations. These observations are consistent with our model of conformationally gated CT. Through conformational motion of the DNA bases, CT-active domains form and break-up transiently, both facilitating and limiting CT.

DNA charge transport: conformationally gated hopping through stacked domains.

The role of base motions in delocalization and propagation of charge through double helical DNA must be established experimentally and incorporated into mechanistic descriptions of DNA-mediated charge transport (CT). Here, we address these fundamental issues by examining the temperature dependence of the yield of CT between photoexcited 2-aminopurine (Ap) and G through DNA bridges of varied length and sequence. DNA assemblies (35-mers) were constructed containing adenine bridges Ap(A)(n)()G (n = 0-9, 3.4-34 A) and mixed bridges, ApAAIAG and ApATATG. CT was monitored through fluorescence quenching of Ap by G and through HPLC analysis of photolyzed DNA assemblies containing Ap and the modified guanine, N(2)-cyclopropylguanosine ((CP)G); upon oxidation, the (CP)G radical cation undergoes rapid ring opening. First, we find that below the duplex melting temperature ( approximately 60 degrees C), the yield of CT through duplex DNA increases with increasing temperature governed by the length and sequence of the DNA bridge. Second, the distance dependence of CT is regulated by temperature; enhanced DNA base fluctuations within duplex DNA extend CT to significantly longer distances, here up to 34 A in <10 ns. Third, at all temperatures the yield of CT does not exhibit a simple distance dependence; an oscillatory component, with a period of approximately 4-5 base pairs, is evident. These data cannot be rationalized by superexchange, hopping of a localized charge injected into the DNA bridge, a temperature-induced transition from superexchange to thermally induced hopping, or by phonon-assisted polaron hopping. Instead, we propose that CT occurs within DNA assemblies possessing specific, well-coupled conformations of the DNA bases, CT-active domains, accessed through base motion. CT through DNA is described as conformationally gated hopping among stacked domains. Enhanced DNA base motions lead to longer range CT with a complex distance dependence that reflects the roles of coherent dynamics and charge delocalization through transient domains. Consequently, DNA CT is not a simple function of distance but is intimately related to the dynamical structure of the DNA bridge.

Direct chemical evidence for charge transfer between photoexcited 2-aminopurine and guanine in duplex DNA.

Photoexcited 2-aminopurine (Ap*) is extensively exploited as a fluorescent base analogue in the study of DNA structure and dynamics. Quenching of Ap* in DNA is often attributed to stacking interactions between Ap* and DNA bases, despite compelling evidence indicating that charge transfer (CT) between Ap* and DNA bases contributes to quenching. Here we present direct chemical evidence that Ap* undergoes CT with guanine residues in duplex DNA, generating oxidative damage at a distance. Irradiation of Ap in DNA containing the modified guanine, cyclopropylguanosine (CPG), initiates hole transfer from Ap* followed by rapid ring opening of the CPG radical cation. Ring opening accelerates hole trapping to a much shorter time regime than for guanine radicals in DNA; consequently, trapping effectively competes with back electron transfer (BET) leading to permanent CT chemistry. Significantly, BET remains competitive, even with this much faster trapping reaction, consistent with measured kinetics of DNA-mediated CT. The distance dependence of BET is sharper than that of forward CT, leading to an inverted dependence of product yield on distance; at short distances product yield is inhibited by BET, while at longer distances trapping dominates, leading to permanent products. The distance dependence of product yield is distinct from forward CT, or charge injection. As with photoinduced charge transfer in other chemical and biological systems, rapid kinetics for charge injection into DNA need not be associated with a high yield of DNA damage products.

Effects of strand and directional asymmetry on base-base coupling and charge transfer in double-helical DNA.

Mechanistic models of charge transfer (CT) in macromolecules often focus on CT energetics and distance as the chief parameters governing CT rates and efficiencies. However, in DNA, features unique to the DNA molecule, in particular, the structure and dynamics of the DNA base stack, also have a dramatic impact on CT. Here we probe the influence of subtle structural variations on base-base CT within a DNA duplex by examining photoinduced quenching of 2-aminopurine (Ap) as a result of hole transfer (HT) to guanine (G). Photoexcited Ap is used as a dual reporter of variations in base stacking and CT efficiency. Significantly, the unique features of DNA, including the strandedness and directional asymmetry of the double helix, play a defining role in CT efficiency. For an (AT)n bridge, the orientation of the base pairs is critical; the yield of intrastrand HT is markedly higher through (A)n compared with (T)n bridges, whereas HT via intrastrand pathways is more efficient than through interstrand pathways. Remarkably, for reactions through the same DNA bridge, over the same distance, and with the same driving force, HT from photoexcited Ap to G in the 5' to 3' direction is more efficient and less dependent on distance than HT from 3' to 5'. We attribute these differences in HT efficiency to variations in base-base coupling within the DNA assemblies. Thus base-base coupling is a critical parameter in DNA CT and strongly depends on subtle structural nuances of duplex DNA.

2-Aminopurine: a probe of structural dynamics and charge transfer in DNA and DNA:RNA hybrids.

Spectroscopic techniques are employed to probe relationships between structural dynamics and charge transfer (CT) efficiency in DNA duplexes and DNA:RNA hybrids containing photoexcited 2-aminopurine (Ap). To better understand the variety of interactions and reactions, including CT, between Ap and DNA, the fluorescence behavior of Ap is investigated in a full series of redox-inactive as well as redox-active assemblies. Thus, Ap is developed as a dual reporter of structural dynamics and base-base CT reactions in nucleic acid duplexes. CD, NMR, and thermal denaturation profiles are consistent with the family of DNA duplexes adopting a distinct conformation versus the DNA:RNA hybrids. Fluorescence measurements establish that the d(A)-r(U) tract of the DNA:RNA hybrid exhibits enhanced structural flexibility relative to that of the d(A)-d(T) tract of the DNA duplexes. The yield of CT from either G or 7-deazaguanine (Z) to Ap in the assemblies was determined by comparing Ap emission in redox-active G- or Z-containing duplexes to otherwise identical duplexes in which the G or Z is replaced by inosine (I), the redox-inactive nucleoside analogue. Investigations of CT not only demonstrate efficient intrastrand base-base CT in the DNA:RNA hybrids but also reveal a distance dependence of CT yield that is more shallow through the d(A)-r(U) bridge of the A-form DNA:RNA hybrids than through the d(A)-d(T) bridge of the B-form DNA duplexes. The shallow distance dependence of intrastrand CT in DNA:RNA hybrids correlates with the increased conformational flexibility of bases within the hybrid duplexes. Measurements of interstrand base-base CT provide another means to distinguish between the A- and B-form helices. Significantly, in the A-form DNA:RNA hybrids, a similar distance dependence is obtained for inter- and intrastrand reactions, while, in B-DNA, a more shallow distance dependence is evident with interstrand CT reactions. These observations are consistent with evaluations of intra- and interstrand base overlap in A- versus B-form duplexes. Overall, these data underscore the sensitivity of CT chemistry to nucleic acid structure and structural dynamics.