The RNA helicase DbpA exhibits a markedly different conformation in the ADP-bound state when compared with the ATP- or RNA-bound states

DEAD Box RNA Helicases: Biochemical Properties, Role in RNA Processing and Ribosome Biogenesis

DEAD box RNA helicases are a versatile group of ATP dependent enzymes that play an essential role in cellular processes like transcription, RNA processing, ribosome biogenesis and translation. These enzymes perform structural rearrangement of complex RNA molecules and enhance the productive folding of RNA and organization of macromolecular complexes. In this review article besides providing the outline about structural organization of helicases, an in-depth discussion will be done on the biochemical properties of RNA helicases like their substrate binding, binding and hydrolysis of ATP and related conformational changes that are important for functioning of the RNA helicase enzymes. I will extensively discuss the physiological role of RNA helicases in RNA processing and ribosome biogenesis.

Insights into the product release mechanism of dengue virus NS3 helicase

The non-structural protein 3 helicase (NS3h) is a multifunctional protein that is critical in RNA replication and other stages in the flavivirus life cycle. NS3h uses energy from ATP hydrolysis to translocate along single stranded nucleic acid and to unwind double stranded RNA. Here we present a detailed mechanistic analysis of the product release stage in the catalytic cycle of the dengue virus (DENV) NS3h. This study is based on a combined experimental and computational approach of product-inhibition studies and free energy calculations. Our results support a model in which the catalytic cycle of ATP hydrolysis proceeds through an ordered sequential mechanism that includes a ternary complex intermediate (NS3h-Pi-ADP), which evolves releasing the first product, phosphate (Pi), and subsequently ADP. Our results indicate that in the product release stage of the DENV NS3h a novel open-loop conformation plays an important role that may be conserved in NS3 proteins of other flaviviruses as well.

ATPase site configuration of the RNA helicase DbpA probed by ENDOR spectroscopy

Electron-nuclear double resonance (ENDOR) is a method that probes the local structure of paramagnetic centers via their hyperfine interactions with nearby magnetic nuclei. Here we describe the use of this technique to structurally characterize the ATPase active site of the RNA helicase DbpA, where Mg(2+)-ATP binds. This is achieved by substituting the EPR (electron paramagnetic resonance) silent Mg(2+) ion with paramagnetic, EPR active, Mn(2+) ion. (31)P ENDOR provides the interaction of the Mn(2+) with the nucleotide (ADP, ATP and its analogs) through the phosphates. The ENDOR spectra clearly distinguish between ATP- and ADP-binding modes. In addition, by preparing (13)C-enriched DbpA, (13)C ENDOR is used to probe the interaction of the Mn(2+) with protein residues. This combination allows tracking structural changes in the Mn(2+) coordination shell, in the ATPase site, in different states of the protein, namely with and without RNA and with different ATP analogs. Here, a detailed description of sample preparation and the ENDOR measurement methodology is provided, focusing on measurements at W-band (95 GHz) where sensitivity is high and spectral interpretations are relatively simple.

Duplex destabilization by four ribosomal DEAD-box proteins

DEAD-box proteins are believed to participate in the folding of RNA by destabilizing RNA secondary or tertiary structures. Although these proteins bind and hydrolyze ATP, the mechanism by which nucleotide hydrolysis is coupled to helix destabilization may vary among different DEAD-box proteins. To investigate their abilities to disrupt helices and couple ATP hydrolysis to unwinding, we assayed the Saccharomyces cerevisiae ribosomal DEAD-box proteins, Dbp3p, Dbp4p, Rok1p, and Rrp3p utilizing a series of RNA substrates containing a short duplex and either a 5' or 3' single-stranded region. All four proteins unwound a 10 bp helix in vitro in the presence of ATP; however, significant dissociation of longer helices was not observed. While Dbp3p did not require a single-stranded extension to disrupt a helix, the unwinding activities of Dbp4p, Rok1p, and Rrp3p were substantially stimulated by either a 5' or 3' single-stranded extension. Interestingly, these proteins showed a clear length dependency with 3' extensions that was not observed with 5' extensions, suggesting that they bind substrates with a preferred orientation. In the presence of AMPPNP or ADP, all four proteins displayed displacement activity suggesting that nucleotide binding is sufficient to facilitate duplex disruption. Further enhancement of the strand displacement rate in the presence of ATP was observed for only Dbp3p and Rrp3p.

Probing conformational variations at the ATPase site of the RNA helicase DbpA by high-field electron-nuclear double resonance spectroscopy

The RNA helicase DbpA promotes RNA remodeling coupled to ATP hydrolysis. It is unique because of its specificity to hairpin 92 of 23S rRNA (HP92). Although DbpA kinetic pathways leading to ATP hydrolysis and RNA unwinding have been recently elucidated, the molecular (atomic) basis for the coupling of ATP hydrolysis to RNA remodeling remains unclear. This is, in part, due to the lack of detailed structural information on the ATPase site in the presence and absence of RNA in solution. We used high-field pulse ENDOR (electron-nuclear double resonance) spectroscopy to detect and analyze fine conformational changes in the protein's ATPase site in solution. Specifically, we substituted the essential Mg(2+) cofactor in the ATPase active site for paramagnetic Mn(2+) and determined its close environment with different nucleotides (ADP, ATP, and the ATP analogues ATPγS and AMPPnP) in complex with single- and double-stranded RNA. We monitored the Mn(2+) interactions with the nucleotide phosphates through the (31)P hyperfine couplings and the coordination by protein residues through (13)C hyperfine coupling from (13)C-enriched DbpA. We observed that the nucleotide binding site of DbpA adopts different conformational states upon binding of different nucleotides. The ENDOR spectra revealed a clear distinction between hydrolyzable and nonhydrolyzable nucleotides prior to RNA binding. Furthermore, both the (13)C and the (31)P ENDOR spectra were found to be highly sensitive to changes in the local environment of the Mn(2+) ion induced by the hydrolysis. More specifically, ATPγS was efficiently hydrolyzed upon binding of RNA, similar to ATP. Importantly, the Mn(2+) cofactor remains bound to a single protein side chain and to one or two nucleotide phosphates in all complexes, whereas the remaining metal coordination positions are occupied by water. The conformational changes in the protein's ATPase active site associated with the different DbpA states occur in remote coordination shells of the Mn(2+) ion. Finally, a competitive Mn(2+) binding site was found for single-stranded RNA construct.

The nuclear pore complex and nuclear transport

Internal membrane bound structures sequester all genetic material in eukaryotic cells. The most prominent of these structures is the nucleus, which is bounded by a double membrane termed the nuclear envelope (NE). Though this NE separates the nucleoplasm and genetic material within the nucleus from the surrounding cytoplasm, it is studded throughout with portals called nuclear pore complexes (NPCs). The NPC is a highly selective, bidirectional transporter for a tremendous range of protein and ribonucleoprotein cargoes. All the while the NPC must prevent the passage of nonspecific macromolecules, yet allow the free diffusion of water, sugars, and ions. These many types of nuclear transport are regulated at multiple stages, and the NPC carries binding sites for many of the proteins that modulate and modify the cargoes as they pass across the NE. Assembly, maintenance, and repair of the NPC must somehow occur while maintaining the integrity of the NE. Finally, the NPC appears to be an anchor for localization of many nuclear processes, including gene activation and cell cycle regulation. All these requirements demonstrate the complex design of the NPC and the integral role it plays in key cellular processes.

The mechanism of ATP-dependent RNA unwinding by DEAD box proteins

DEAD box proteins catalyze the ATP-dependent unwinding of double-stranded RNA (dsRNA). In addition, they facilitate protein displacement and remodeling of RNA or RNA/protein complexes. Their hallmark feature is local destabilization of RNA duplexes. Here, we summarize current data on the DEAD box protein mechanism and present a model for RNA unwinding that integrates recent data on the effect of ATP analogs and mutations on DEAD box protein activity. DEAD box proteins share a conserved helicase core with two flexibly linked RecA-like domains that contain all helicase signature motifs. Variable flanking regions contribute to substrate binding and modulate activity. In the presence of ATP and RNA, the helicase core adopts a compact, closed conformation with extensive interdomain contacts and high affinity for RNA. In the closed conformation, the RecA-like domains form a catalytic site for ATP hydrolysis and a continuous RNA binding site. A kink in the backbone of the bound RNA locally destabilizes the duplex. Rearrangement of this initial complex generates a hydrolysis- and unwinding-competent state. From this complex, the first RNA strand can dissociate. After ATP hydrolysis and phosphate release, the DEAD box protein returns to a low-affinity state for RNA. Dissociation of the second RNA strand and reopening of the cleft in the helicase core allow for further catalytic cycles.

The DEAD-box protein Dbp5 controls mRNA export by triggering specific RNA:protein remodeling events

Messenger RNA (mRNA) export involves the unidirectional passage of ribonucleoprotein particles (RNPs) through nuclear pore complexes (NPCs), presumably driven by the ATP-dependent activity of the DEAD-box protein Dbp5. Here we report that Dbp5 functions as an RNP remodeling protein to displace the RNA-binding protein Nab2 from RNA. Strikingly, the ADP-bound form of Dbp5 and not ATP hydrolysis is required for RNP remodeling. In vivo studies with nab2 and dbp5 mutants show that a Nab2-bound mRNP is a physiological Dbp5 target. We propose that Dbp5 functions as a nucleotide-dependent switch to control mRNA export efficiency and release the mRNP from the NPC.

Cooperative binding of ATP and RNA induces a closed conformation in a DEAD box RNA helicase

RNA helicases couple the energy from ATP hydrolysis with structural changes of their RNA substrates. DEAD box helicases form the largest class of RNA helicases and share a helicase core comprising two RecA-like domains. An opening and closing of the interdomain cleft during RNA unwinding has been postulated but not shown experimentally. Single-molecule FRET experiments with the Bacillus subtilis DEAD box helicase YxiN carrying donor and acceptor fluorophores on different sides of the interdomain cleft reveal an open helicase conformation in the absence of nucleotides, or in the presence of ATP, or ADP, or RNA. In the presence of ADP and RNA, the open conformation is retained. By contrast, cooperative binding of ATP and RNA leads to a compact helicase structure, proving that the ATP- and ADP-bound states of RNA helicases display substantially different structures only when the RNA substrate is bound. These results establish a closure of the interdomain cleft in the helicase core at the beginning of the unwinding reaction, and suggest a conserved mechanism of energy conversion among DEAD box helicases across kingdoms.

The ATPase cycle mechanism of the DEAD-box rRNA helicase, DbpA

DEAD-box proteins are ATPase enzymes that destabilize and unwind duplex RNA. Quantitative knowledge of the ATPase cycle parameters is critical for developing models of helicase activity. However, limited information regarding the rate and equilibrium constants defining the ATPase cycle of RNA helicases is available, including the distribution of populated biochemical intermediates, the catalytic step(s) that limits the enzymatic reaction cycle, and how ATP utilization and RNA interactions are linked. We present a quantitative kinetic and equilibrium characterization of the ribosomal RNA (rRNA)-activated ATPase cycle mechanism of DbpA, a DEAD-box rRNA helicase implicated in ribosome biogenesis. rRNA activates the ATPase activity of DbpA by promoting a conformational change after ATP binding that is associated with hydrolysis. Chemical cleavage of bound ATP is reversible and occurs via a gamma-phosphate attack mechanism. ADP-P(i) and RNA binding display strong thermodynamic coupling, which causes DbpA-ADP-P(i) to bind rRNA with >10-fold higher affinity than with bound ATP, ADP or in the absence of nucleotide. The rRNA-activated steady-state ATPase cycle of DbpA is limited both by ATP hydrolysis and by P(i) release, which occur with comparable rates. Consequently, the predominantly populated biochemical states during steady-state cycling are the ATP- and ADP-P(i)-bound intermediates. Thermodynamic linkage analysis of the ATPase cycle transitions favors a model in which rRNA duplex destabilization is linked to strong rRNA and nucleotide binding. The presented analysis of the DbpA ATPase cycle reaction mechanism provides a rigorous kinetic and thermodynamic foundation for developing testable hypotheses regarding the functions and molecular mechanisms of DEAD-box helicases.

Crystal structure and nucleotide binding of the Thermus thermophilus RNA helicase Hera N-terminal domain

DEAD box RNA helicases use the energy of ATP hydrolysis to unwind double-stranded RNA regions or to disrupt RNA/protein complexes. A minimal RNA helicase comprises nine conserved motifs distributed over two RecA-like domains. The N-terminal domain contains all motifs involved in nucleotide binding, namely the Q-motif, the DEAD box, and the P-loop, as well as the SAT motif, which has been implicated in the coordination of ATP hydrolysis and RNA unwinding. We present here the crystal structure of the N-terminal domain of the Thermus thermophilus RNA helicase Hera in complex with adenosine monophosphate (AMP). Upon binding of AMP the P-loop adopts a partially collapsed or half-open conformation that is still connected to the DEAD box motif, and the DEAD box in turn is linked to the SAT motif via hydrogen bonds. This network of interactions communicates changes in the P-loop conformation to distant parts of the helicase. The affinity of AMP is comparable to that of ADP and ATP, substantiating that the binding energy from additional phosphate moieties is directly converted into conformational changes of the entire helicase. Importantly, the N-terminal Hera domain forms a dimer in the crystal similar to that seen in another thermophilic prokaryote. It is possible that this mode of dimerization represents the prototypic architecture in RNA helicases of thermophilic origin.

The DEAD-box protein family of RNA helicases

RNA helicases of the DEAD-box protein family have been shown to participate in every aspect of RNA metabolism. They are present in most organisms where they work as RNA helicases or RNPases. The properties of these enzymes in vivo remains poorly described, however some were extensively characterized in vitro, and the solved crystal structures of a few are now available. Taken together, this information gives insight into the regulation of ATP and RNA binding as well as in the ATPase and helicase activities. This review will focus on the description of the molecular characteristics of members of the DEAD-box protein family and on the enzymatic activities they possess.

Hydrodynamic characterization of the DEAD-box RNA helicase DbpA

The Escherichia coli DEAD-box protein A (DbpA) belongs to the highly conserved superfamily-II of nucleic acid helicases that play key roles in RNA metabolism. A central question regarding helicase activity is whether the process of coupling ATP hydrolysis to nucleic acid unwinding requires an oligomeric form of the enzyme. We have investigated the structural and functional properties of DbpA by multi-angle laser light-scattering, size-exclusion chromatography, analytical ultracentrifugation, chemical cross-linking and hydrodynamic modeling. DbpA is monomeric in solution up to a concentration of 25 microM and over the temperature range of 4 degrees C to 22 degrees C. Binding of neither nucleotide (ATP or ADP) nor peptidyl transferase center (PTC) RNA, the presumed physiological RNA substrate, favor oligomerization. The hydrodynamic parameters were used together with hydrodynamic bead modeling and structural homology in conjunction with ab initio structure prediction methods to define plausible shapes of DbpA. Collectively, the results favor models where DbpA functions as an active monomer that possesses two distinct RNA binding sites, one in the helicase core domain and the other in the carboxyl-terminal domain that recognizes 23S rRNA and interacts specifically with hairpin 92 of the PTC.

Thermodynamics of ligand binding by the yeast mRNA-capping enzyme reveals different modes of binding

RNA-capping enzymes are involved in the synthesis of the cap structure found at the 5'-end of eukaryotic mRNAs. The present study reports a detailed study on the thermodynamic parameters involved in the interaction of an RNA-capping enzyme with its ligands. Analysis of the interaction of the Saccharomyces cerevisiae RNA-capping enzyme (Ceg1) with GTP, RNA and manganese ions revealed significant differences between the binding forces that drive the interaction of the enzyme with its RNA and GTP substrates. Our thermodynamic analyses indicate that the initial association of GTP with the Ceg1 protein is driven by a favourable enthalpy change (DeltaH=-80.9 kJ/mol), but is also clearly associated with an unfavourable entropy change (TDeltaS=-62.9 kJ/mol). However, the interaction between Ceg1 and RNA revealed a completely different mode of binding, where binding to RNA is clearly dominated by a favourable entropic effect (TDeltaS=20.5 kJ/mol), with a minor contribution from a favourable enthalpy change (DeltaH=-5.3 kJ/mol). Fluorescence spectroscopy also allowed us to evaluate the initial binding of GTP to such an enzyme, thereby separating the GTP binding step from the concomitant metal-dependent hydrolysis of GTP that results in the formation of a covalent GMP-protein intermediate. In addition to the determination of the energetics of ligand binding, our study leads to a better understanding of the molecular basis of substrate recognition by RNA-capping enzymes.

Equilibrium and kinetic analysis of nucleotide binding to the DEAD-box RNA helicase DbpA

The Escherichia coli DEAD-box protein A (DbpA) is an RNA helicase that utilizes the energy from ATP binding and hydrolysis to facilitate structural rearrangements of rRNA. We have used the fluorescent nucleotide analogues, mantADP and mantATP, to measure the equilibrium binding affinity and kinetic mechanism of nucleotide binding to DbpA in the absence of RNA. Binding generates an enhancement in mant-nucleotide fluorescence and a corresponding reduction in intrinsic DbpA fluorescence, consistent with fluorescence resonance energy transfer (FRET) from DbpA tryptophan(s) to bound nucleotides. Fluorescent modification does not significantly interfere with the affinities and kinetics of nucleotide binding. Different energy transfer efficiencies between DbpA-mantATP and DbpA-mantADP complexes suggest that DbpA adopts nucleotide-dependent conformations. ADP binds (K(d) approximately 50 microM at 22 degrees C) 4-7 times more tightly than ATP (K(d) approximately 400 microM at 22 degrees C). Both nucleotides bind with relatively temperature-independent association rate constants (approximately 1-3 microM(-1) s(-1)) that are much lower than predicted for a diffusion-limited reaction. Differences in the binding affinities are dictated primarily by the dissociation rate constants. ADP binding occurs with a positive change in the heat capacity, presumably reflecting a nucleotide-induced conformational rearrangement of DbpA. At low temperatures (<22 degrees C), the binding free energies are dominated by favorable enthalpic and unfavorable entropic contributions. At physiological temperatures (>22 degrees C), ADP binding occurs with positive entropy changes. We favor a mechanism in which ADP binding increases the conformational flexibility and dynamics of DbpA.

LC-mass spectrometry analysis of N- and C-terminal boundary sequences of polypeptide fragments by limited proteolysis

Limited proteolysis is an important and widely used method for analyzing the tertiary structure and determining the domain boundaries of proteins. Here we describe a novel method for determining the N- and C-terminal boundary amino acid sequences of products derived from limited proteolysis using semi-specific and/or non-specific enzymes, with mass spectrometry as the only analytical tool. The core of this method is founded on the recognition that cleavage of proteins with non-specific proteases is not random, but patterned. Based on this recognition, we have the ability to determine the sequence of each proteolytic fragment by extracting a common association between data sets containing multiple potential sequences derived from two or more different mass spectral molecular weight measurements. Proteolytic product sequences derived from specific and non-specific enzymes can be accurately determined without resorting to the conventional time-consuming and laborious methods of SDS-PAGE and N-terminal sequencing analysis. Because of the sensitivity of mass spectrometry, multiple transient proteolysis intermediates can also be identified and analyzed by this method, which allows the ability to monitor the progression of proteolysis and thereby gain insight into protein structures.

Reaction cycle of the yeast Isw2 chromatin remodeling complex

Members of the ISWI family of chromatin remodeling factors hydrolyze ATP to reposition nucleosomes along DNA. Here we show that the yeast Isw2 complex interacts with DNA in a nucleotide-dependent manner at physiological ionic strength. Isw2 efficiently binds DNA in the absence of nucleotides and in the presence of a nonhydrolyzable ATP analog. Conversely, ADP promotes the dissociation of Isw2 from DNA. In contrast, Isw2 remains bound to mononucleosomes through multiple cycles of ATP hydrolysis. Solution studies show that Isw2 undergoes nucleotide-dependent alterations in conformation not requiring ATP hydrolysis. Our results indicate that during an Isw2 remodeling reaction, hydrolysis of successive ATP molecules coincides with cycles of DNA binding, release, and rebinding involving elements of Isw2 distinct from those interacting with nucleosomes. We propose that progression of the DNA-binding site occurs while nucleosome core contacts are maintained and generates a force dissipated by disruption of histone-DNA interactions.

The newly discovered Q motif of DEAD-box RNA helicases regulates RNA-binding and helicase activity

DEAD-box proteins are the most common RNA helicases, and they are associated with virtually all processes involving RNA. They have nine conserved motifs that are required for ATP and RNA binding, and for linking phosphoanhydride cleavage of ATP with helicase activity. The Q motif is the most recently identified conserved element, and it occurs approximately 17 amino acids upstream of motif I. There is a highly conserved, but isolated, aromatic group approximately 17 amino acids upstream of the Q motif. These two elements are involved in adenine recognition and in ATPase activity of DEAD-box proteins. We made extensive analyses of the Q motif and upstream aromatic residue in the yeast translation-initiation factor Ded1. We made site-specific mutations and tested them for viability in yeast. Moreover, we purified various mutant proteins and obtained the Michaelis-Menten parameters for the ATPase activities. We also measured RNA affinities and strand-displacement activities. We find that the Q motif not only regulates ATP binding and hydrolysis but also regulates the affinity of the protein for RNA substrates and ultimately the helicase activity.

Interaction of Escherichia coli DbpA with 23S rRNA in different functional states of the enzyme

DEx(D)/(H) proteins catalyze structural rearrangements in RNA by coupling ATP hydrolysis to the destabilization of RNA helices or RNP complexes. The Escherichia coli DEx(D)/(H) protein DbpA specifically recognizes a region within the catalytic core of 23S rRNA. To better characterize the interaction of DbpA with this region and to identify changes in the complex between different nucleotide-bound states of the enzyme, RNase T1, RNase T2, kethoxal and DMS footprinting of DbpA on a 172 nt fragment of 23S rRNA were performed. A number of protections identified in helices 90 and 92 were consistent with biochemical experiments measuring the RNA binding and ATPase activity of DbpA with truncated RNAs. When DbpA was bound with AMPPNP, but not ADP, several additional footprints were detected in helix 93 and the single-stranded region 5' of helix 90, suggesting binding of the helicase domains of DbpA at these sites. These results propose that DbpA can act at multiple sites and hint at the targets of its biological activity on rRNA.