Biochemical and kinetic characterization of the RNA helicase activity of eukaryotic initiation factor 4A

Eukaryotic initiation factor (eIF) 4A is the prototypic member of the DEAD box family of proteins and has been proposed to act as an RNA helicase to unwind secondary structure in the 5'-untranslated region of eukaryotic mRNAs. Previous studies have shown that the RNA helicase activity of eIF4A is dependent on the presence of a second initiation factor, eIF4B. In this report, eIF4A has been demonstrated to function independently of eIF4B as an ATP-dependent RNA helicase. The biochemical and kinetic properties of this activity were examined. By using a family of RNA duplexes with an unstructured single-stranded region followed by a duplex region of increasing length and stability, it was observed that the initial rate of duplex unwinding decreased with increasing stability of the duplex. Furthermore, the maximum amount of duplex unwound also decreased with increasing stability. Results suggest that eIF4A acts in a non-processive manner. eIF4B and eIF4H were shown to stimulate the helicase activity of eIF4A, allowing eIF4A to unwind longer, more stable duplexes with both an increase in initial rate and maximum amount of duplex unwound. A simple kinetic model is proposed to explain the mechanism by which eIF4A unwinds RNA duplex structures in an ATP-dependent manner.     

Modulation of the helicase activity of eIF4A by eIF4B, eIF4H, and eIF4F.

Eukaryotic initiation factor (eIF) 4A is a DEAD box RNA helicase that works in conjunction with eIF4B, eIF4H, or as a subunit of eIF4F to unwind secondary structure in the 5'-untranslated region of mRNA, which facilitates binding of the mRNA to the 40 S ribosomal subunit. This study demonstrates how the helicase activity of eIF4A is modulated by eIF4B, eIF4H, or as a subunit of eIF4F. Results indicate that a linear relationship exists between the initial rate or amplitude of unwinding and duplex stability for all factor combinations tested. eIF4F, like eIF4A, behaves as a non-processive helicase. Either eIF4B or eIF4H stimulated the initial rate and amplitude of eIF4A-dependent duplex unwinding, and the magnitude of stimulation is dependent on duplex stability. Furthermore, eIF4A (or eIF4F) becomes a slightly processive helicase in the presence of eIF4B or eIF4H. All combinations of factors tested indicate that the rate of duplex unwinding is equivalent in the 5' --> 3' and 3' --> 5' directions. However, the optimal rate of unwinding was dependent on the length of the single-stranded region of the substrate when different combinations of factors were used. The combinations of eIF4A, eIF4A + eIF4B, eIF4A + eIF4H, and eIF4F showed differences in their ability to unwind chemically modified duplexes. A simple model of how eIF4B or eIF4H affects the duplex unwinding mechanism of eIF4A is proposed.     

Vaccinia virus RNA helicase: nucleic acid specificity in duplex unwinding.

Vaccinia virus RNA helicase (NPH-II) catalyzes nucleoside triphosphate-dependent unwinding of duplex RNAs containing a single-stranded 3' RNA tail. In this study, we examine the structural features of the nucleic acid substrate that are important for helicase activity. Strand displacement was affected by the length of the 3' tail. Whereas NPH-II efficiently unwound double-stranded RNA substrates with 19- or 11-nucleotide (nt) 3' tails, shortening the 3' tail to 4 nt reduced unwinding by an order of magnitude. Processivity of the helicase was inferred from its ability to unwind a tailed RNA substrate containing a 96-bp duplex region. NPH-II exhibited profound asymmetry in displacing hybrid duplexes composed of DNA and RNA strands. A 34-bp RNA-DNA hybrid with a 19-nt 3' RNA tail was unwound catalytically, whereas a 34-bp DNA-RNA hybrid containing a 19-nt 3' DNA tail was 2 orders of magnitude less effective as a helicase substrate. NPH-II was incapable of displacing a 34-bp double-stranded DNA substrate of identical sequence. 3'-Tailed DNA molecules with 24- or 19-bp duplex regions were also inert as helicase substrates. On the basis of current models for RNA-DNA hybrid structures, we suggest the following explanation for these findings. (i) Unwinding of duplex nucleic acids by NPH-II is optimal when the polynucleotide strand of the duplex along which the enzyme translocates has adopted an A-form secondary structure, and (ii) a B-form secondary structure impedes protein translocation through DNA duplexes.     

Wheat germ translation initiation factor eIF4B affects eIF4A and eIFiso4F helicase activity by increasing the ATP binding affinity of eIF4A

It has been proposed that, during translational initiation, structures in the 5' untranslated region of mRNA are unwound. eIF4A, a member of the DEAD box family of proteins (those that contain a DEAD amino acid sequence), separately or in conjunction with other eukaryotic initiation factors, utilizes the energy from ATP hydrolysis to unwind these structures. As a step in defining the mechanism of helicase activity in the wheat germ protein synthesis system, we have utilized direct fluorescence measurements, ATPase assays, and helicase assays. The RNA duplex unwinding activity of wheat germ eIF4A is similar to other mammalian systems; however, eIF4F or eIFiso4F is required, probably because of the low binding affinity of wheat germ eIF4A for mRNA. Direct ATP binding measurements showed that eIF4A had a higher binding affinity for ADP than ATP, resulting in a limited hydrolysis and procession along the RNA in the helicase assay. The addition of eIF4B resulted in a change in binding affinity for ATP, increasing it almost 10-fold while the ADP binding affinity was approximately the same. The data presented in this paper suggest that eIF4F or eIFiso4F acts to position the eIF4A and stabilize the interaction with mRNA. ATP produces a conformational change which allows a limited unwinding of the RNA duplex. The binding of eIF4B either prior to or after hydrolysis allows for increased affinity for ATP and for the cycle of conformational changes to proceed, resulting in further unwinding and processive movement along the mRNA.     

Probing the relationship between RNA-stimulated ATPase and helicase activities of HCV NS3 using 2'-O-methyl RNA substrates

The hepatitis C virus (HCV) NS3 protein contains an amino terminal protease (NS3 aa. 1-180) and a carboxyl terminal RNA helicase (NS3 aa. 181-631). NS3 functions as a heterodimer of NS3 and NS4A (NS3/4A). NS3 helicase, a nucleic acid stimulated ATPase, can unwind RNA, DNA, and RNA:DNA duplexes, provided that at least one strand of the duplex contains a single-stranded 3' overhang (this strand of the duplex is referred to as the 3' strand). We have used 2'-O-methyl RNA (MeRNA) substrates to study the mechanism of NS3 helicase activity and to probe the relationship between its helicase and RNA-stimulated ATPase activities. NS3/4A did not unwind double-stranded (ds) MeRNA. NS3/4A unwinds hybrid RNA:MeRNA duplex containing MeRNA as the 5' strand but not hybrid duplex containing MeRNA as the 3' strand. The helicase activity of NS3/4A was 50% inhibited by 40 nM single-stranded (ss) RNA but only 35% inhibited by 320 nM ss MeRNA. Double-stranded RNA was 17 times as effective as double-stranded MeRNA in inhibiting NS3/4A helicase activity, while the apparent affinity of NS3/4A for ds MeRNA differed from ds RNA by only 2.4-fold. However ss MeRNA stimulated NS3/4A ATPase activity similar to ss RNA. These results indicate that the helicase mechanism involves 3' to 5' procession of the NS3 helicase along the 3' strand and only weak association of the enzyme with the displaced 5' strand. Further, our findings show that maximum stimulation of NS3 ATPase activity by ss nucleic acid is not directly related to procession of the helicase along the 3' strand.     

The DEAD-box protein Ded1 unwinds RNA duplexes by a mode distinct from translocating helicases

Helicases unwind RNA or DNA duplexes and displace proteins from nucleic acids in an ATP-dependent fashion. To unwind duplexes, helicases typically load onto one of the two nucleic acid strands, usually at a single-stranded region, and then translocate on this strand in a unidirectional fashion, thereby displacing the complementary DNA or RNA. Here we show that the DEAD-box RNA helicase Ded1 unwinds duplexes in a different manner. Ded1 uses the single-stranded region to gain access to the duplex. Strand separation is directly initiated from the duplex region and no covalent connection between the single strand and the duplex region is required. This new type of helicase activity explains observations with other DEAD-box proteins and may be the prototype for duplex-unwinding reactions in RNA metabolism.     

Crystal structure and activity of Kunjin virus NS3 helicase; protease and helicase domain assembly in the full length NS3 protein

Flaviviral NS3 is a multifunctional protein displaying N-terminal protease activity in addition to C-terminal helicase, nucleoside 5'-triphosphatase (NTPase), and 5'-terminal RNA triphosphatase (RTPase) activities. NS3 is held to support the separation of RNA daughter and template strands during viral replication. In addition, NS3 assists the initiation of replication by unwinding the RNA secondary structure in the 3' non-translated region (NTR). We report here the three-dimensional structure (at 3.1 A resolution) of the NS3 helicase domain (residues 186-619; NS3:186-619) from Kunjin virus, an Australian variant of the West Nile virus. As for homologous helicases, NS3:186-619 is composed of three domains, two of which are structurally related and held to host the NTPase and RTPase active sites. The third domain (C-terminal) is involved in RNA binding/recognition. The NS3:186-619 construct occurs as a dimer in solution and in the crystals. We show that NS3:186-619 displays both ATPase and RTPase activities, that it can unwind a double-stranded RNA substrate, being however inactive on a double-stranded DNA substrate. Analysis of different constructs shows that full length NS3 displays increased helicase activity, suggesting that the protease domain plays an assisting role in the RNA unwinding process. The structural interaction between the helicase and protease domain has been assessed using small angle X-ray scattering on full length NS3, disclosing that the protease and helicase domains build a rather elongated molecular assembly differing from that observed in the NS3 protein from hepatitis C virus.     

The RNA Helicase eIF4A Is Required for Sapovirus Translation

The eukaryotic initiation factor 4A (eIF4A) is a DEAD box helicase that unwinds RNA structure in the 5′ untranslated region (UTR) of mRNAs. Here, we investigated the role of eIF4A in porcine sapovirus VPg-dependent translation. Using inhibitors and dominant-negative mutants, we found that eIF4A is required for viral translation and infectivity, suggesting that despite the presence of a very short 5′ UTR, eIF4A is required to unwind RNA structure in the sapovirus genome to facilitate virus translation.     

Studies on three E. coli DEAD-box helicases point to an unwinding mechanism different from that of model DNA helicases

DEAD-box proteins participate in various aspects of RNA metabolism in all organisms. These RNA-dependent ATPases are usually regarded as double-stranded RNA unwinding enzymes, though in vitro this activity has only been demonstrated for a subset of them. Given their high biological specificity, their equivocal unwinding activity may reflect the noncognate character of the substrates used in vitro. Here, we pinpoint other reasons for this elusiveness. We have compared the ATPase and helicase activities of three E. coli DEAD-box proteins, CsdA, RhlE and SrmB. Whereas the ATPase activity of all proteins is stimulated (albeit to various degree) by long RNAs, only RhlE is stimulated by short oligoribonucleotides. Consistently, all three proteins can unwind RNA duplexes with long single-stranded extensions, but only RhlE is effective when extensions are short or absent. Another critical constraint concerns the length of the duplex region: in the case of RhlE, the ratio (duplex unwound)/(ATP hydrolyzed) drops 1000-fold upon going from 11 to 14 base pairs, indicating a low processivity. Remarkably, allowing for these constraints, all three proteins can unwind substrates with either 5' or 3' extensions (or no extension in the case of RhlE). This behavior, which contrasts with that of well studied SF1 DNA helicases, is discussed in the light of available structural and biochemical data.     

Unwinding of unnatural substrates by a DNA helicase

Helicases separate double-stranded DNA into single-stranded DNA intermediates that are required during replication and recombination. These enzymes are believed to transduce free energy available from ATPase activity to unwind the duplex and translocate along the nucleic acid lattice. The nature of enzyme-substrate interactions between helicases and duplex DNA substrates has not been well-defined. Most helicases require a single-stranded DNA overhang adjacent to duplex DNA in order to initiate unwinding. The strand containing the overhang is referred to as the loading strand whereas the complementary strand is referred to as the displaced strand. We have investigated the interactions between a DNA helicase and the DNA substrate by replacing the displaced strand with a nucleic acid mimic, peptide nucleic acid (PNA). PNA is capable of forming duplex structures with DNA according to Watson-Crick base pairing rules, but contains a N-(2-aminoethyl)glycine backbone in place of the deoxyribose phosphates. The PNA-DNA hybrids had higher melting temperatures than their DNA-DNA counterparts. Dda helicase, from bacteriophage T4, was able to unwind the DNA-PNA substrates at similar rates as DNA-DNA substrates. The results indicate that the rate-limiting step for unwinding is relatively insensitive to the chemical nature of the displaced strand and the thermal stability of oligonucleotide substrates.     

Interaction between the NH2-terminal domain of eIF4A and the central domain of eIF4G modulates RNA-stimulated ATPase activity

The eukaryotic translation factor 4A (eIF4A) is a member of DEA(D/H)-box RNA helicase family, a diverse group of proteins that couples ATP hydrolysis to RNA binding and duplex separation. eIF4A participates in the initiation of translation by unwinding secondary structure in the 5'-untranslated region of mRNAs and facilitating scanning by the 40 S ribosomal subunit for the initiation codon. eIF4A alone has only weak ATPase and helicase activities, but these are stimulated by eIF4G, eIF4B, and eIF4H. eIF4G has two eIF4A-binding sites, one in the central domain (cp(C3)) and one in the COOH-terminal domain (cp(C2)). In the current work, we demonstrate that these two eIF4G domains have different effects on the RNA-stimulated ATPase activity of eIF4A. cp(C3) stimulates ATP-hydrolytic efficiency by about 40-fold through two mechanisms: lowering K(m)(RNA) by 10-fold and raising k(cat) by 4-fold. cp(C3) also stimulates RNA cross-linking to eIF4A in an ATP-independent manner. Studies with eIF4G and eIF4A variants suggest a model by which cp(C3) alters the conformation of the catalytic site to favor RNA binding. cp(C2) does not stimulate ATPase activity and furthermore increases both K(m)(ATP) (at saturating RNA concentrations) and K(m)(RNA) (at subsaturating ATP concentrations). Both cp(C3) and cp(C2) directly interact with the NH(2)-terminal domain of eIF4A, which possesses conserved ATP- and oligonucleotide-binding motifs, but not with the COOH-terminal domain.     

P68 RNA helicase unwinds the human let-7 microRNA precursor duplex and is required for let-7-directed silencing of gene expression

MicroRNAs are short, single-stranded RNAs that arise from a transient precursor duplex. We have identified a novel activity in HeLa cell extracts that can unwind the let-7 microRNA duplex. Using partially purified material, we have shown that microRNA helicase activity requires ATP and has a native molecular mass of approximately 68 kDa. Affinity purification of the unwinding activity revealed co-purification of P68 RNA helicase. Importantly, recombinant P68 RNA helicase was sufficient to unwind the let-7 duplex. Moreover, like its native homolog, P68 RNA helicase did not unwind an analogous small interfering RNA duplex. We further showed that knockdown of P68 inhibited let-7 microRNA function. From our data, we conclude that P68 RNA helicase is an essential component of the let-7 microRNA pathway, and in conjunction with other factors, it may play a role in the loading of let-7 microRNA into the silencing complex.     

Protein displacement by an assembly of helicase molecules aligned along single-stranded DNA

Helicases are molecular motors that unwind double-stranded DNA or RNA. In addition to unwinding nucleic acids, an important function of these enzymes seems to be the disruption of protein-nucleic acid interactions. Bacteriophage T4 Dda helicase can displace proteins bound to DNA, including streptavidin bound to biotinylated oligonucleotides. We investigated the mechanism of streptavidin displacement by varying the length of the oligonucleotide substrate. We found that a monomeric form of Dda catalyzed streptavidin displacement; however, the activity increased when multiple helicase molecules bound to the biotinylated oligonucleotide. The activity does not result from cooperative binding of Dda to the oligonucleotide. Rather, the increase in activity is a consequence of the directional bias in translocation of individual helicase monomers. Such a bias leads to protein-protein interactions when the lead monomer stalls owing to the presence of the streptavidin block.     

Nonspecific double-stranded DNA binding activity of simian virus 40 large T antigen is involved in melting and unwinding of the origin

Helicase activity is required for T antigen to unwind the simian virus 40 origin. We previously mapped this activity to residues 131 and 616. In this study, we generated a series of mutants with single-point substitutions in the helicase domain to discover other potential activities required for helicase function. A number of DNA unwinding-defective mutants were generated. Four of these mutants (456RA, 460ED, 462GA, and 499DA) were normal in their ability to hydrolyze ATP and were capable of associating into double hexamers in the presence of origin DNA. Furthermore, they possessed normal ability to bind to single-stranded DNA. However, they were severely impaired in unwinding origin-containing DNA fragments and in carrying out a helicase reaction with an M13 partial duplex DNA substrate. Interestingly, these mutants retained some ability to perform a helicase reaction with artificial replication forks, indicating that their intrinsic helicase activity was functional. Intriguingly, these mutants had almost completely lost their ability to bind to double-stranded DNA nonspecifically. The mutants also failed to melt the early palindrome region of the origin. Taken together, these results indicate that the mutations have destroyed a novel activity required for unwinding of the origin. This activity depends on the ability to bind to DNA nonspecifically, and in its absence, T antigen is unable to structurally distort and subsequently unwind the origin.     

The HRIGRXXR region of the DEAD box RNA helicase eukaryotic translation initiation factor 4A is required for RNA binding and ATP hydrolysis.

eIF-4A is a eukaryotic translation initiation factor that is required for mRNA binding to ribosomes. It exhibits single-stranded RNA-dependent ATPase activity, and in combination with a second initiation factor, eIF-4B, it exhibits duplex RNA helicase activity. eIF-4A is the prototype of a large family of proteins termed the DEAD box protein family, whose members share nine highly conserved amino acid regions. The functions of several of these conserved regions in eIF-4A have previously been assigned to ATP binding, ATPase, and helicase activities. To define the RNA-binding region of eIF-4A, a UV-induced cross-linking assay was used to analyze binding of mutant eIF-4A proteins to RNA. Mutants carrying mutations in the ATP-binding region (AXXXXGKT), ATPase region (DEAD), helicase region (SAT), and the most carboxy-terminal conserved region of the DEAD family, HRIGRXXR, were tested for RNA cross-linking. We show that mutations, either conservative or not, in any one of the three arginines in the HRIGRXXR sequence drastically reduced eIF-4A cross-linking to RNA. In addition, all the mutations in the HRIGRXXR region abrogate RNA helicase activity. Some but not all of these mutations affect ATP binding and ATPase activity. This is consistent with the hypothesis that the HRIGRXXR region is involved in the ATP hydrolysis reaction and would explain the coupling of ATPase and RNA-binding/helicase activities. Our results show that the HRIGRXXR region, which is QRXGRXXR or QXXGRXXR in the RNA and DNA helicases of the helicase superfamily II, is involved in ATP hydrolysis-dependent RNA interaction during unwinding. We also show that mutations in other regions of eIF-4A that abolish ATPase activity sharply decrease eIF-4A cross-linking to RNA. A model is proposed in which eIF-4A first binds ATP, resulting in a change in eIF-4A conformation which allows RNA binding that is dependent on the HRIGRXXR region. Binding of RNA induces ATP hydrolysis, leading to a more stable interaction with RNA. This process is then linked to unwinding of duplex RNA in the presence of eIF-4B.     

Escherichia coli PriA helicase: fork binding orients the helicase to unwind the lagging strand side of arrested replication forks

Escherichia coli PriA is a primosome assembly protein with 3' to 5' helicase activity whose apparent function is to promote resumption of DNA synthesis following replication-fork arrest. Here, we describe how initiation of helicase activity on DNA forks is influenced by both fork structure and by single-strand DNA-binding protein. PriA could recognize and unwind forked substrates where one or both arms were primarily duplex, and PriA required a small (two bases or larger) single-stranded gap at the fork in order to initiate unwinding. The helicase was most active on substrates with a duplex lagging-strand arm and a single-stranded leading-strand arm. On this substrate, PriA was capable of translocating on either the leading or lagging strands to unwind the duplex ahead of the fork or the lagging-strand duplex, respectively. Fork-specific binding apparently orients the helicase domain to unwind the lagging-strand duplex. Binding of single-strand-binding protein to forked templates could inhibit unwinding of the duplex ahead of the fork but not unwinding of the lagging-strand duplex or translocation on the lagging-strand template. While single-strand-binding protein could inhibit binding of PriA to the minimal, unforked DNA substrates, it could not inhibit PriA binding to forked substrates. In the cell, single-strand-binding protein and fork structure may direct PriA helicase to translocate along the lagging-strand template of forked structures such that the primosome is specifically assembled on that DNA strand.     

Escherichia coli helicase II (uvrD) protein can completely unwind fully duplex linear and nicked circular DNA

We have examined the duplex DNA unwinding (helicase) properties of the Escherichia coli helicase II protein (uvrD gene product) over a wide range of protein concentrations and solution conditions using a variety of duplex DNA substrates including fully duplex blunt ended and nicked circular molecules. We find that helicase II protein is able to initiate on and completely unwind fully duplex DNA molecules without the requirement for a covalently attached 3' single-stranded DNA tail. This DNA unwinding activity is dependent upon Mg2+ and ATP and requires that the amount of protein be in excess of that needed to saturate the resulting single-stranded DNA. Unwinding experiments on fully duplex blunt ended DNA with lengths of 341, 849, 1625, and 2671 base pairs indicate that unwinding occurs at the same high ratios of helicase II protein/nucleotide, independent of DNA length (50% unwinding requires approximately 0.6 helicase II monomers/nucleotide in 2.5 mM MgCl2, 10% glycerol, pH 7.5, 37 degrees C). Helicase II protein is also able to unwind completely a nicked circular DNA molecule containing 2671 base pairs. At lower but still high molar ratios of helicase II protein to DNA, duplex DNA molecules containing a single-stranded (ss) region attached to a 3' end of the duplex are preferentially unwound in agreement with the results obtained by S. W. Matson [1986) J. Biol. Chem. 261, 10169-10175). This preferential unwinding of duplex DNA with an attached 3' ssDNA most likely reflects the availability of a high affinity site (ssDNA) with the proper orientation for initiation; however, this may not reflect the type of DNA molecule upon which helicase II protein initiates DNA unwinding in vivo. The effects of changes in NaCl, NaCH3COO, and MgCl2 concentration on the ability of helicase II protein to unwind fully duplex DNA and duplex DNA with a 3' ssDNA tail have also been examined. Although the unwinding of fully duplex and nicked circular DNA molecules reported here occurs at higher helicase II protein to DNA ratios than have been previously used in most studies of this protein in vitro, this activity is likely to be relevant to the function of this protein in vivo since very high levels of helicase II protein accumulate in E. coli during the SOS response to DNA damage (approximately 2-5 x 10(4) copies/cell).(ABSTRACT TRUNCATED AT 400 WORDS)     

A Structural Model for the DEAD Box Helicase YxiN in Solution: Localization of the RNA Binding Domain

DEAD box proteins consist of a common helicase core formed by two globular RecA domains that are separated by a cleft. The helicase core acts as a nucleotide-dependent switch that alternates between open and closed conformations during the catalytic cycle of duplex separation, thereby providing basic helicase activity. Flanking domains can direct the helicase core to a specific RNA substrate by mediating high-affinity or high-specificity RNA binding. In addition, they may position RNA for the helicase core or may directly contribute to unwinding. While structures of different helicase cores have been determined previously, little is known about the orientation of flanking domains relative to the helicase core.YxiN is a DEAD box protein that consists of a helicase core and a C-terminal RNA binding domain (RBD) that mediates specific binding to hairpin 92 in 23S rRNA. To provide a framework for understanding the functional cooperation of the YxiN helicase core and the RBD, we mapped the orientation of the RBD in single-molecule fluorescence resonance energy transfer experiments. We present a model for the global conformation of YxiN in which the RBD lies above a slightly concave patch that is formed by flexible loops on the surface of the C-terminal RecA domain. The orientation of the RBD is different from the orientations of flanking domains in the Thermus thermophilus DEAD box protein Hera and in Saccharomyces cerevisiae Mss116p, in line with the different functions of these DEAD box proteins and of their RBDs. Interestingly, the corresponding patch on the C-terminal RecA domain that is covered by the YxiN RBD is also part of the interface between the translation factors eIF4A and eIF4G. Possibly, this region constitutes an adaptable interface that generally allows for the interaction of the helicase core with additional domains or interacting factors.