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.     

Mapping initiation sites for simian virus 40 DNA synthesis events in vitro.

Primer RNA-DNA, a small (approximately 30-nucleotide) RNA-DNA hybrid molecule, was identified in recent studies of simian virus 40 DNA synthesis in vitro. The available evidence indicates that primer RNA-DNA is the product of the polymerase alpha-primase complex. Primer RNA-DNA is formed exclusively on lagging-strand DNA templates; it is synthesized initially in the vicinity of the simian virus 40 origin and at later times at sites progressively distal to the origin. To further characterize initiation events, template sequences encoding the 5' ends of both primer RNA and primer DNA, formed during a 5-s pulse, have been determined. Analyses of these sequences demonstrate the existence of an initiation signal for lagging-strand synthesis. At any given position, the initiation signal is located within those template sequences encoding primer RNA, situated proximal to the nucleotide encoding the 5' end of the RNA primer. In most instances, the sequence 5'-TTN-3' (where N encodes the nucleotide at the 5' end of the primer) is a feature of the initiation signal. Initiation signals are present, on average, once every 19 nucleotides. These results are discussed in terms of the mechanism of Okazaki fragment formation and possible links between prokaryotic and eukaryotic initiation events.     

RNA helicase: a novel activity associated with a protein encoded by a positive strand RNA virus.

Most positive strand RNA viruses infecting plants and animals encode proteins containing the so-called nucleotide binding motif (NTBM) (1) in their amino acid sequences (2). As suggested from the high level of sequence similarity of these viral proteins with the recently described superfamilies of helicase-like proteins (3-5), the NTBM-containing cylindrical inclusion (CI) protein from plum pox virus (PPV), which belongs to the potyvirus group of positive strand RNA viruses, is shown to be able to unwind RNA duplexes. This activity was found to be dependent on the hydrolysis of NTP to NDP and Pi, and thus it can be considered as an RNA helicase activity. In the in vitro assay used, the PPV CI protein was only able to unwind double strand RNA substrates with 3' single strand overhangs. This result indicates that the helicase activity of the PPV CI protein functions in the 3' to 5' direction (6). To our knowledge, this is the first report on a helicase activity associated with a protein encoded by an RNA virus.     

The replicative helicases of bacteria, archaea, and eukarya can unwind RNA-DNA hybrid substrates

Replicative helicases are hexameric enzymes that unwind DNA during chromosomal replication. They use energy from nucleoside triphosphate hydrolysis to translocate along one strand of the duplex DNA and displace the complementary strand. Here, the ability of a replicative helicase from each of the three domains, bacteria, archaea, and eukarya, to unwind RNA-containing substrate was determined. It is shown that all three helicases can unwind DNA-RNA hybrids while translocating along the single-stranded DNA. No unwinding could be observed when the helicases were provided with a single-stranded RNA overhang. Using DNA, RNA, and DNA-RNA chimeric oligonucleotides it was found that whereas the enzymes can bind both DNA and RNA, they could translocate only along DNA and only DNA stimulates the ATPase activity of the enzymes. Recent observations suggest that helicases may interact with enzymes participating in RNA metabolism and that RNA-DNA hybrids may be present on the chromosomes. Thus, the results presented here may suggest a new role for the replicative helicases during chromosomal replication or in other cellular processes.     

Escherichia coli DNA helicase I catalyzes a unidirectional and highly processive unwinding reaction

Helicase I has been purified to greater than 95% homogeneity from an F+ strain of Escherichia coli, and characterized as a single-stranded DNA-dependent ATPase and a helicase. The duplex DNA unwinding reaction requires a region of ssDNA for enzyme binding and concomitant nucleoside 5'-triphosphate hydrolysis. All eight predominant nucleoside 5'-triphosphates can satisfy this requirement. Unwinding is unidirectional in the 5' to 3' direction. The length of duplex DNA unwound is independent of protein concentration suggesting that the unwinding reaction is highly processive. Kinetic analysis of the unwinding reaction indicates that the enzyme turns over very slowly from one DNA substrate molecule to another. The ATP hydrolysis reaction is continuous when circular partial duplex DNA substrates are used as DNA effectors. When linear partial duplex substrates are used ATP hydrolysis is barely detectable, although the kinetics of the unwinding reaction on linear partial duplex substrates are identical to those observed using a circular partial duplex DNA substrate. This suggests that ATP hydrolysis fuels continuous translocation of helicase I on circular single-stranded DNA while on linear single stranded DNA the enzyme translocates to the end of the DNA molecule where it must slowly dissociate from the substrate molecule and/or slowly associate with a new substrate molecule, thus resulting in a very low rate of ATP hydrolysis.     

Eukaryotic ribonucleases HI and HII generate characteristic hydrolytic patterns on DNA-RNA hybrids: further evidence that mitochondrial RNase H is an RNase HII

RNase H activities from HeLa cells (either of cytoplasmic or mitochondrial origin), and from mitochondria of beef heart and Xenopus ovaries, have been tested with RNA-DNA substrates of defined length (20 bp) and sequence. Substrates were either blunt-ended, or presented DNA or RNA overhangs. The hydrolysis profiles obtained at early times of the digestion showed a good correlation between the class of RNase H, either type I or II assigned according to biochemical parameters, whatever the organism. Consequently, the pattern of primary cuts can be considered as a signature of the predominant RNase H activity. For a given sequence, hydrolysis profiles obtained are similar, if not identical, for either blunt-ended substrates or those presenting overhangs. However, profiles showed variations depending on the sequence used. Of the three sequences tested, one appears very discriminatory, class I RNases H generating a unique primary cut 3 nt from the 3' end of the RNA strand, whereas class II RNases H generated two simultaneous primary cuts at 6 and at 8 nt from the 5' end of the RNA strand. Hydrolysis profiles further confirm the assignation of the mitochondrial RNase H activity from HeLa cells, beef heart and Xenopus oocytes to the class II.     

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)     

Properties of cloned and expressed human RNase H1.

We have characterized cloned His-tag human RNase H1. The activity of the enzyme exhibited a bell-shaped response to divalent cations and pH. The optimum conditions for catalysis consisted of 1 mM Mg(2+) and pH 7-8. In the presence of Mg(2+), Mn(2+) was inhibitory. Human RNase H1 shares many enzymatic properties with Escherichia coli RNase H1. The human enzyme cleaves RNA in a DNA-RNA duplex resulting in products with 5'-phosphate and 3'-hydroxy termini, can cleave overhanging single strand RNA adjacent to a DNA-RNA duplex, and is unable to cleave substrates in which either the RNA or DNA strand has 2' modifications at the cleavage site. Human RNase H1 binds selectively to "A-form"-type duplexes with approximately 10-20-fold greater affinity than that observed for E. coli RNase H1. The human enzyme displays a greater initial rate of cleavage of a heteroduplex-containing RNA-phosphorothioate DNA than an RNA-DNA duplex. Unlike the E. coli enzyme, human RNase H1 displays a strong positional preference for cleavage, i.e. it cleaves between 8 and 12 nucleotides from the 5'-RNA-3'-DNA terminus of the duplex. Within the preferred cleavage site, the enzyme displays modest sequence preference with GU being a preferred dinucleotide. The enzyme is inhibited by single-strand phosphorothioate oligonucleotides and displays no evidence of processivity. The minimum RNA-DNA duplex length that supports cleavage is 6 base pairs, and the minimum RNA-DNA "gap size" that supports cleavage is 5 base pairs.     

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.     

Junction ribonuclease activity specified in RNases HII/2

Junction ribonuclease (JRNase) recognizes the transition from RNA to DNA of an RNA-DNA/DNA hybrid, such as an Okazaki fragment, and cleaves it, leaving a mono-ribonucleotide at the 5' terminus of the RNA-DNA junction. Although this JRNase activity was originally reported in calf RNase H2, some other RNases H have recently been suggested to possess it. This paper shows that these enzymes can also cleave an RNA-DNA/RNA heteroduplex in a manner similar to the RNA-DNA/DNA substrate. The cleavage site of the RNA-DNA/RNA substrate corresponds to the RNA/RNA duplex region, indicating that the cleavage activity cannot be categorized as RNase H activity, which specifically cleaves an RNA strand of an RNA/DNA hybrid. Examination of several RNases H with respect to JRNase activity suggested that the activity is only found in RNase HII orthologs. Therefore, RNases HIII, which are RNase HII paralogs, are distinguished from RNases HII by the absence of JRNase activity. Whether a substrate can be targeted by JRNase activity would depend only on whether or not an RNA-DNA junction consisting of one ribonucleotide and one deoxyribonucleotide is included in the duplex. In addition, although the activity has been reported not to occur on completely single-stranded RNA-DNA, it can recognize a single-stranded RNA-DNA junction if a double-stranded region is located adjacent to the junction.     

TWINKLE Has 5' -> 3' DNA helicase activity and is specifically stimulated by mitochondrial single-stranded DNA-binding protein

Mutations in TWINKLE cause autosomal dominant progressive external ophthalmoplegia, a human disorder associated with multiple deletions in the mitochondrial DNA. TWINKLE displays primary sequence similarity to the phage T7 gene 4 primase-helicase, but no specific enzyme activity has been assigned to the protein. We have purified recombinant TWINKLE to near homogeneity and demonstrate here that TWINKLE is a DNA helicase with 5' to 3' directionality and distinct substrate requirements. The protein needs a stretch of 10 nucleotides of single-stranded DNA on the 5'-side of the duplex to unwind duplex DNA. In addition, helicase activity is not observed unless a short single-stranded 3'-tail is present. The helicase activity has an absolute requirement for hydrolysis of a nucleoside 5'-triphosphate, with UTP being the optimal substrate. DNA unwinding by TWINKLE is specifically stimulated by the mitochondrial single-stranded DNA-binding protein. Our enzymatic characterization strongly supports the notion that TWINKLE is the helicase at the mitochondrial DNA replication fork and provides evidence for a close relationship of the DNA replication machinery in bacteriophages and mammalian mitochondria.