A novel DNA helicase from calf thymus

Prokaryotic and eukaryotic DNA helicases. Essential molecular motor proteins for cellular machinery

DNA helicases are ubiquitous molecular motor proteins which harness the chemical free energy of ATP hydrolysis to catalyze the unwinding of energetically stable duplex DNA, and thus play important roles in nearly all aspects of nucleic acid metabolism, including replication, repair, recombination, and transcription. They break the hydrogen bonds between the duplex helix and move unidirectionally along the bound strand. All helicases are also translocases and DNA‐dependent ATPases. Most contain conserved helicase motifs that act as an engine to power DNA unwinding. All DNA helicases share some common properties, including nucleic acid binding, NTP binding and hydrolysis, and unwinding of duplex DNA in the 3′ to 5′ or 5′ to 3′ direction. The minichromosome maintenance (Mcm) protein complex (Mcm4/6/7) provides a DNA‐unwinding function at the origin of replication in all eukaryotes and may act as a licensing factor for DNA replication. The RecQ family of helicases is highly conserved from bacteria to humans and is required for the maintenance of genome integrity. They have also been implicated in a variety of human genetic disorders. Since the discovery of the first DNA helicase in Escherichia coli in 1976, and the first eukaryotic one in the lily in 1978, a large number of these enzymes have been isolated from both prokaryotic and eukaryotic systems, and the number is still growing. In this review we cover the historical background of DNA helicases, helicase assays, biochemical properties, prokaryotic and eukaryotic DNA helicases including Mcm proteins and the RecQ family of helicases. The properties of most of the known DNA helicases from prokaryotic and eukaryotic systems, including viruses and bacteriophages, are summarized in tables.

The intrinsic DNA helicase activity of Methanobacterium thermoautotrophicum delta H minichromosome maintenance protein

Minichromosome maintenance proteins (MCMs) form a family of conserved molecules that are essential for initiation of DNA replication. All eukaryotes contain six orthologous MCM proteins that function as heteromultimeric complexes. The sequencing of the complete genomes of several archaebacteria has shown that MCM proteins are also present in archaea. The archaea Methanobacterium thermoautotrophicum contains a single MCM-related sequence. Here we report on the expression and purification of the recombinant M. thermoautotrophicum MCM protein (MtMCM) in both Escherichia coli and baculovirus-infected cells. We show that purified MtMCM protein assembles in large macromolecular complexes consistent in size with being double hexamers. We demonstrate that MtMCM contains helicase activity that preferentially uses dATP and DNA-dependent dATPase and ATPase activities. The intrinsic helicase activity of MtMCM is abolished when a conserved lysine in the helicase domain I/nucleotide binding site is mutated. MtMCM helicase unwinds DNA duplexes in a 3' --> 5' direction and can unwind up to 500 base pairs in vitro. The kinetics, processivity, and directionality of MtMCM support its role as a replicative helicase in M. thermoautotrophicum. This strongly suggests that this function is conserved for MCM proteins in eukaryotes where a replicative helicase has yet to be identified.

Characterization of Werner syndrome protein DNA helicase activity: directionality, substrate dependence and stimulation by replication protein A

Werner syndrome is an inherited disease characterized by premature aging, genetic instability and a high incidence of cancer. The wild type Werner syndrome protein (WRN) has been demonstrated to exhibit DNA helicase activity in vitro. Here we report further biochemical characterization of the WRN helicase. The enzyme unwinds double-stranded DNA, translocating 3'-->5' on the enzyme-bound strand. Hydrolysis of dATP or ATP, and to a lesser extent hydrolysis of dCTP or CTP, supports WRN-catalyzed strand-displacement. K m values for ATP and dATP are 51 and 119 microM, respectively, and 2.1 and 3.9 mM for CTP and dCTP, respectively. Strand-displacement activity of WRN is stimulated by single-stranded DNA-binding proteins (SSBs). Among the SSBs from Escherichia coli, bacteriophage T4 and human, stimulation by human SSB (human replication protein A, hRPA) is the most extensive and occurs with a stoichiometry which suggests direct interaction with WRN. A deficit in the interaction of WRN with hRPA may be associated with deletion mutations that occur at elevated frequency in Werner syndrome cells.

High-mobility group 1 protein inhibits helicase catalyzed displacement of cisplatin-damaged DNA

We have determined the effect of HMG-1 bound to cisplatin-damaged DNA on the activities of calf helicase E. DNase I protection analysis demonstrated HMG-1 bound a cisplatin-damaged 24 base oligonucleotide annealed to M13mp18. Exonuclease digestion experiments revealed that greater than 90% of the DNA substrates contained a single site specific cisplatin adduct and, maximally, 65% of the substrates were bound by HMG-1. Helicase E catalyzed displacement of the cisplatin-damaged DNA oligonucleotide was inhibited by HMG-1 in a concentration-dependent manner. Time course experiments revealed a decreased rate of displacement in reactions containing HMG-1. The maximum inhibition observed was 55% and taking into account that only 65% of the substrates had HMG-1 bound, approximately 85% inhibition was observed on platinated DNA substrates containing HMG-1. Inhibition of helicase activity was proportional to the amount of substrate bound by HMG-1 based on the displacement and exonuclease assays at varying HMG-1 concentrations. The ability of helicase E to displace an undamaged DNA oligonucleotide from a cisplatin-damaged DNA template was also inhibited by HMG-1. Interestingly, HMG-1 had no effect on the rate of DNA-dependent ATP hydrolysis catalyzed by helicase E on the same DNA substrate. The inhibition of helicase activity by HMG-1 binding cisplatin-damaged DNA further supports a role for HMG-1 inhibiting DNA repair which may contribute to cellular sensitivity to cisplatin.

Mechanism of tracking and cleavage of adduct-damaged DNA substrates by the mammalian 5'- to 3'-exonuclease/endonuclease RAD2 homologue 1 or flap endonuclease 1

The mammalian 5'- to 3'-exonuclease/endonuclease, called RAD2 homologue 1 or flap endonuclease 1, has a unique cleavage activity, dependent on specific substrate structure. On a primer-template, in which the primer has an unannealed 5'-tail, endonucleolytic cleavage near the annealing point releases the tail intact. Entering at the 5'-end, the nuclease tracks along the entire tail to the point of cleavage. Genetic analyses suggest that this nuclease removes DNA adducts in vivo (Sommers, C. H., Miller, E. J., Dujon, B., Prakash, S., and Prakash, L. (1995) J. Biol. Chem. 270, 4193-4196). Micrococcal nuclease footprinting shows that after tracking the nuclease protects a region of the tail 25 nucleotides long, adjacent to the cleavage site. Substrates with adducts at specific locations were used to assess the mechanism of RAD2 homologue 1 nuclease tracking and its ability to cleave modified DNA. Either a conventional cis-diamminedichloroplatinum (II) (CDDP) or a bulky CDDP derivative was placed within or beyond the region protected by the nuclease. The nuclease cleaved the tail of both substrates. In contrast, a CDDP adduct just adjacent to the expected cleavage point was inhibitory. A CDDP adduct at the very 5'-end of the tail was also cleaved. The nuclease could remove tails containing adducts on the sugar-phosphate backbone. Apparently, the nuclease is designed to slide over various types of damage on single stranded DNA and then cut past the damaged site.

Isolation and characterisation of dhel II, a DNA helicase from Drosophila melanogaster embryos stimulated by Escherichia coli-type single-stranded-DNA-binding proteins

We have purified a DNA helicase from Drosophila embryos by following unwinding activity during the purification of the cellular single-stranded DNA-binding protein dRP-A. This DNA helicase unwinds DNA 5' to 3', has a salt-tolerant activity, and has a preference for purine triphosphates as cofactors for the unwinding reaction. The purified enzyme consists of a single polypeptide of 120 kDa, which cosediments with the helicase activity. Sedimentation analysis suggests that this polypeptide exists as a monomer under high and low salt conditions. Dhel II is able to unwind long stretches of DNA, but with decreased efficiency. Addition of Escherichia coli-like single-stranded DNA-binding proteins stimulates the unwinding activity at least 10-fold on substrates greater than 200 nucleotides. In particular, the mitochondrial single-stranded DNA-binding protein isolated from Drosophila embryos is able to stimulate unwinding by dhel II. These properties show that the helicase described is different from another Drosophila helicase dhel I; it has thus has been classified as dhel II.

Calf 5' to 3' exo/endonuclease must slide from a 5' end of the substrate to perform structure-specific cleavage

Calf 5' to 3' exo/endonuclease, the counterpart of the human FEN-1 and yeast RTH-1 nucleases, performs structure-specific cleavage of both RNA and DNA and is implicated in Okazaki fragment processing and DNA repair. The substrate for endonuclease activity is a primer annealed to a template but with a 5' unannealed tail. The results presented here demonstrate that the nuclease must enter the 5' end of the unannealed tail and then slide to the region of hybridization where the cleavage occurs. The presence of bound protein or a primer at any point on the single-stranded tail prevents cleavage. However, biotinylation of a nucleotide at the 5' end or internal to the tail does not prevent cleavage. The sliding process is bidirectional. If the nuclease slides onto the tail, later binding of a primer to the tail traps the nuclease between the primer binding site and the cleavage site, preventing the nuclease from departing from the 5' end. A model for 5' entry, sliding, and cleavage is presented. The possible role of this unusual mechanism in Okazaki fragment processing, DNA repair, and protection of the replication fork from inappropriate endonucleolytic cleavage is presented.

DNA helicases: enzymes with essential roles in all aspects of DNA metabolism

DNA helicases catalyze the disruption of the hydrogen bonds that hold the two strands of double-stranded DNA together. This energy-requiring unwinding reaction results in the formation of the single-stranded DNA required as a template or reaction intermediate in DNA replication, repair and recombination. A combination of biochemical and genetic studies have been used to probe and define the roles of the multiple DNA helicases found in E. coli. This work and similar efforts in eukaryotic cells, although far from complete, have established that DNA helicases are essential components of the machinery that interacts with the DNA molecule.

Three new DNA helicases from Saccharomyces cerevisiae

At least six DNA helicases have been identified during fractionation of extracts from the yeast Saccharomyces cerevisiae. Three of those, DNA helicases B, C, and D, have been further purified and characterized. DNA helicases B and C co-purified with DNA polymerase delta through several chromatographic steps, but were separated from the polymerase by hydrophobic chromatography. DNA helicase D co-purified with Replication Factor C over seven chromatographic steps, and was only separated from it by glycerol gradient centrifugation in the presence of 0.2 M NaCl. All three helicases are DNA dependent ATPases with Km values for ATP of 190 microM, 325 microM, and 60 microM for DNA helicases B, C, and D, respectively. Their DNA helicase activities are comparable. They are 5'-3' helicases and have pH optima of 6.5-7 and Mg2+ optima of 1-2 mM. However, they differ in the nucleotide requirement for helicase action. Whereas all three helicases preferred ATP, dATP, UTP, CTP, and dCTP as cofactors, DNA helicase C also used GTP, but not dTTP. On the other hand, DNA helicase D used dTTP, but not GTP, and DNA helicase B used neither nucleotide as cofactor. These studies allowed us to conclude that DNA helicases B, C, and D are not only distinct enzymes, but also different from two previously identified yeast DNA helicases, the RAD3 protein and ATPase III.

Isolation and characterization of a DNA helicase from cytosolic extracts of calf thymus

A DNA helicase has been isolated from calf thymus tissue. The enzyme was enriched from crude cytosolic extracts by batchwise chromatography on phosphocellulose, followed by 35% ammonium sulfate precipitation, and subsequent chromatography on phenyl-Sepharose, single-stranded DNA cellulose, and AcA 44 gel filtration. The DNA helicase had a Stokes' radius of about 45 A and a sedimentation coefficient of 4.3 S. The most purified fractions contained three polypeptides with apparent molecular weights of 110, 65, and 34 kDa. UV crosslinking with radioactive dATP stained all three major polypeptides. The helicase catalyzed the unwinding of a DNA primer from a single-stranded DNA template in an ATP- or dATP-dependent manner. DNA unwinding was also observed with CTP or dCTP, but with reduced efficiency. The helicase translocated from 3' to 5' on the single-stranded template it was bound to. Relationships between this DNA helicase and other calf thymus helicases will be discussed.

A complex between replication factor A (SSB) and DNA helicase stimulates DNA synthesis of DNA polymerase alpha on double-stranded DNA

A helicase-like DNA unwinding activity was found in highly purified fractions of the calf thymus single-stranded DNA binding protein (ctSSB), also known as replication protein A (RP-A) or replication factor A (RF-A). This activity depended on the hydrolysis of ATP or dATP, and used CTP with a lower efficiency. ctSSB promoted the homologous DNA polymerase alpha to perform DNA synthesis on double-stranded templates containing replication fork-like structures. The rate and amount of DNA synthesis was found to be dependent on the concentration of ctSSB. At a 10-fold mass excess of ctSSB over double-stranded DNA, products of 200-600 nucleotides in length were obtained. This comprises or even exceeds the length of a eukaryotic Okazaki fragment. The ctSSB-associated DNA helicase activity is most likely a distinct protein rather than an inherent property of SSB, as inferred from titration experiments between SSB and DNA. The association of a helicase with SSB and the stimulatory action of this complex to the DNA polymerase alpha-catalyzed synthesis of double-stranded DNA suggests a cooperative function of the three enzymatic activities in the process of eukaryotic DNA replication.