大肠杆菌RecQ解旋酶的生物学活性分析

RecQ家族解旋酶是DNA解旋酶中高度保守的一个重要家族,在维持染色体的稳定性中起着重要的作用.人类RecQ家族解旋酶突变会导致几种与癌症有关的疾病.本研究旨在诱导大肠杆菌RecQ解旋酶体外表达,并应用生物化学和生物物理学技术研究大肠杆菌RecQ解旋酶的生物学活性.体外诱导表达获得纯度达90%以上并具有高活性的大肠杆菌重组RecQ解旋酶,其可溶性好;经生物学活性分析显示具有DNA结合活性、ATP依赖的DNA解链活性、DNA依赖的ATP酶活性.较之双链DNA(dsDNA),大肠杆菌RecQ解旋酶更容易与单链DNA(ssDNA)结合(P0.01),但与长度不同的dsDNA的结合特性有差异(P0.01)而与ssDNA没有差异(P0.05);大肠杆菌RecQ解旋酶对3种dsDNA的解链速率不同(P0.05);大肠杆菌RecQ解旋酶的ATP酶活性与辅助因子ssDNA长度也呈正相关(P0.01).这些研究结果将有助于阐明大肠杆菌RecQ解旋酶的分子作用机制,并为研究RecQ解旋酶家族其它成员的结构与功能提供帮助。     

甲磺酸培氟沙星抑制大肠杆菌RecQ解旋酶的体外DNA结合、解链和ATPase活性

RecQ家族解旋酶是DNA解旋酶中高度保守的一个重要家族,参与DNA复制、修复、重组、转录及维持端粒稳定等细胞代谢过程,在维持染色体稳定性与完整性中起着重要作用．甲磺酸培氟沙星(pefloxacin mesylate,PFM)是一种新型氟喹诺酮类抗菌药物,对一些革兰氏阴性菌具有明显的杀菌效果,临床上已广泛使用．本研究利用荧光偏振、自由磷检测技术研究PFM对大肠杆菌RecQ解旋酶的DNA结合活性、解链活性、ATPase活性的影响．结果表明,低浓度PFM可促进大肠杆菌RecQ解旋酶与ssDNA、dsDNA结合,达到一定量后PFM则抑制酶与DNA底物的结合,这种影响与DNA底物有关;PFM对RecQ解旋酶的DNA解链活性和ATP酶活性都具有抑制作用,但其抑制的效果有极显著差异(P<0.01)：比较PFM对两种活性抑制的Ci值(对解链活性抑制的Ci值为(1.5±0.2) μmol/L,对ATP酶活性抑制的Ci值为(0.010±0.005) μmol/L)可知,PFM对大肠杆菌RecQ解旋酶ATPase活性的抑制强于其解链活性. 这些结果可为研究以DNA解旋酶为药物靶标的分子机理奠定相关理论基础．     

荧光偏振技术研究Bloom解旋酶催化核心与双链DNA的相互作用

Bloom 综合症(BLM)解旋酶是RecQ家族DNA解旋酶中的一个重要成员,参与了DNA复制、修复、转录、重组以及端粒的维持等细胞代谢过程,在维持染色体的稳定性中具有重要的作用．BLM解旋酶的突变可导致Bloom综合症,患者遗传不稳定易患多种类型癌症．本研究运用荧光偏振技术研究BLM解旋酶催化核心(BLM642-1290)与双链DNA(dsDNA)的相互作用,分析其相关特征参数,了解BLM642-1290解旋酶与dsDNA的结合和解链特性．结果表明,BLM642-1290解旋酶与dsDNA的结合和解链和dsDNA3’末端的单链DNA(ssDNA)长度有关;解旋酶优先结合于dsDNA底物的ssDNA末端,且每分子解旋酶可结合9.6 nt的ssDNA;dsDNA3’末端ssDNA的长度为9.6 nt时,解旋酶的解链效率达到最大且不再随其长度而变化．另外,BLM642-1290解旋酶也能够结合和解链钝末端dsDNA,但其结合亲和力和解链效率低于有3’末端ssDNA的dsDNA．推测BLM642-1290解旋酶在与dsDNA底物结合和解链时是单体形式,可能以尺蠖的形式解开dsDNA．这些结果可为进一步研究BLM解旋酶的功能特征提供理论基础．     

荧光偏振技术研究Bloom解旋酶催化核心与双链DNA的相互作用

Bloom 综合症(BLM)解旋酶是RecQ家族DNA解旋酶中的一个重要成员,参与了DNA复制、修复、转录、重组以及端粒的维持等细胞代谢过程,在维持染色体的稳定性中具有重要的作用．BLM解旋酶的突变可导致Bloom综合症,患者遗传不稳定易患多种类型癌症．本研究运用荧光偏振技术研究BLM解旋酶催化核心(BLM^642～1290)与双链DNA(dsDNA)的相互作用,分析其相关特征参数,了解BLM^642～1290解旋酶与dsDNA的结合和解链特性．结果表明：BLM^642～1290解旋酶与dsDNA的结合和解链与dsDNA 3′端的单链DNA(ssDNA)长度有关;解旋酶优先结合于dsDNA底物的ssDNA末端,且每分子解旋酶可结合9.6 nt的ssDNA;dsDNA 3′端ssDNA的长度为9.6 nt时,解旋酶的解链效率达到最大且不再随其长度而变化．另外,BLM^642～1290解旋酶也能够结合和解链钝末端dsDNA,但其结合亲和力和解链效率低于有3′端ssDNA的dsDNA．推测BLM^642～1290解旋酶在与dsDNA底物结合和解链时是单体形式,可能以尺蠖的形式解开dsDNA．这些结果可为进一步研究BLM解旋酶的功能特征提供理论基础．     

洛美沙星对Bloom综合征解旋酶生物学特性影响的机理研究

Bloom综合征解旋酶(BLM)是RecQ家族DNA解旋酶中的一个重要成员,参与了DNA复制、修复、转录、重组以及端粒的维持等细胞代谢过程,在维持染色体的稳定性中具有重要作用.BLM解旋酶的突变可导致Bloom综合征.Bloom综合征是一种罕见隐性常染色体遗传疾病,患者遗传不稳定,并易患多种类型癌症.洛美沙星(LMX)可以抑制细胞内多种酶,并通过结合DNA干扰DNA代谢,从而治疗多种疾病,但是其具体的作用机理还未完全清楚.运用荧光偏振技术和自由磷检测技术,研究了LMX对BLM642～1290解旋酶DNA结合活性、解链活性和ATP酶活性的影响.运用荧光及紫外吸收光谱法研究了LMX与解旋酶结合的结合常数、结合位点数、作用力类型、结合距离等参数.结果表明,LMX与解旋酶之间能自发进行反应,两种分子有一个结合位点,通过静电引力和疏水作用力形成稳定的BLM-LMX复合物,且解旋酶的内源荧光被LMX静态猝灭,主要原因是非辐射能量转移.在这一过程中,LMX能抑制解旋酶的解链活性和ATP酶活性,而促进解旋酶的DNA结合活性.LMX对BLM解旋酶生物学活性影响的机理可能是LMX使解旋酶通过别构机制影响其ATP酶活性,并使酶的构象维持在较低解链活性的状态,通过抑制ATP催化水解与解链过程的偶联和阻止解旋酶的易位,从而抑制其解链.LMX能够促进解旋酶的DNA结合活性,可能是因为其C-6和C-7上的取代功能基团可以增加酶活力,以及增强药物、酶和DNA的结合,从而形成药物-酶-DNA复合物.这些结果为研究以DNA解旋酶为药物靶标的分子机理和理解喹诺酮类药物的作用机理奠定相关理论基础.     

甘草次酸对Bloom解旋酶生物学特性的影响

甘草次酸(glycyrrhetinic acid,GA)是甘草主要活性组分,可诱导肿瘤细胞凋亡,抑制肿瘤细胞生长.然而,其对BLM解旋酶的抑制作用尚未见报道.本文注视甘草次酸对BLM解旋酶构象、二级结构和生化活性的影响.圆二色光谱和紫外光谱分析显示,GA可破坏BLM642-1290解旋酶α-螺旋结构,改变其构象,并具有2个结合位点.采用荧光偏振技术和自由磷检测证明,GA以浓度依赖的方式抑制BLM642-1290解旋酶与底物dsDNA及ssDNA的结合,抑制BLM642-1290解旋酶活性及ATP酶活性,且抑制类型为混合抑制.综上所述,本文证明GA可通过结合BLM解旋酶,改变BLM解旋酶构象,抑制BLM解旋酶与DNA的结合,从而抑制BLM解旋酶的生化活性.我们的发现将对深入认识GA的抗肿瘤作用有新的启示.     

嗜热脱铁去硫弧菌Pif1解旋酶生物学活性的分子特征分析

已知Pif1解旋酶在维持基因组稳定性方面发挥重要作用,且不同生物Pif1解旋酶具有不同的生物学活性;然而迄今为止,嗜热细菌Pif1解旋酶的生物学活性分子特征的研究尚未见报道。本文运用生物化学与生物物理学前沿技术,系统地研究了嗜热脱铁去硫弧菌Pif1解旋酶（Defe.Pif1）结合活性与解旋活性的分子特征。通过原核表达纯化系统,本研究获得纯度95%以上、无标签的Defe.Pif1蛋白。利用荧光偏振技术研究Defe.Pif1结合反应的底物特异性,揭示出Defe.Pif1优先结合ssDNA与G4 DNA,并对含3′-尾链的部分双链底物有较强亲和力,其结合反应底物特异性为：ssDNA > G4 DNA > 3′-ssDNA-dsDNA≈Y-structure > Other substrates。通过快速停留检测技术研究Defe.Pif1的解旋活性,明确其最适解旋温度为50℃,最佳反应溶液为10 mmol/L NaCl、3 mmol/L DTT、3 mmol/L MgCl2及1 mmol/L ATP;进一步的解旋动力学特征分析结果显示,Defe.Pif1可以高效解旋含G4结构的DNA底物,其解旋5′-G4 dsDNA底物时的解旋幅度超过90%,解旋速率也与其解旋5′-ss-dsDNA底物的速率相近,提示Defe.Pif1解旋G4 DNA更接近Bs.Pif1的单体反应模式。此外,本研究还发现Defe.Pif1解旋不同类型复制叉/复制泡底物时拥有独特的解旋倾向性：与解旋其它复制中间体DNA的低效性不同,Defe.Pif1解旋12nt bubble底物的速率与幅度均较高,暗示12nt bubble结构很可能是该解旋酶复制中间体的天然底物。上述结果证明,Defe.Pif1不仅具有Pif1解旋酶家族成员共同的结合与解旋G4 DNA等活性特征;而且作为嗜热细菌的解旋酶,它还具有独特的反应条件与解旋底物特异性。本研究为研究Pif1解旋酶家族其它成员的分子特征与生物功能提供了潜在的研究策略,为阐明此类Pif1解旋酶的分子作用机制奠定实验基础。     

野猪DHX36解旋酶酶学特性及保守性分析

DHX36解旋酶(DEAH-box helicase 36)在生物体内广泛存在,可作为外源核酸传感器广泛参与机体免疫反应,因其对G-四链体具有高度亲和性和解旋活性而备受关注。目前已报道了3个物种DHX36解旋酶的三维结构,但其酶学活性的保守性研究鲜见报道。本文以哺乳动物野猪(Sus scrofa)DHX36解旋酶(SsDHX36)为研究对象,通过生物化学与生物物理研究技术系统研究了其酶学性质,并对比其与低等无脊椎动物黑腹果蝇(Drosophila melanogaster)DHX36解旋酶(DmDHX36)的活性,探究DHX36在物种间的功能保守性。本研究通过原核表达系统,分离纯化得到了纯度大于95%的SsDHX36解旋酶;利用荧光偏振和快速停留技术得到SsDHX36的最佳酶学反应条件,发现SsDHX36对G4 DNA具有平行构型的亲和选择性,对富含鸟嘌呤的ssDNA具有结合和解旋的底物偏好性;结合单分子荧光共振能量转移技术对SsDHX36和DmDHX36进行活性比较,发现两者与G4 DNA结合的构型选择性和对富含鸟嘌呤DNA的底物偏好性是保守的。但两者对不同序列长度ssDNA的亲和性差异显著,SsDHX36受序列长度影响较大且亲和力随序列长度的增加而增强,而DmDHX36则完全相反。本文克隆纯化了SsDHX36解旋酶并研究了其酶学活性,着重分析了SsDHX36和DmDHX36的功能保守性,为理解DHX36的保守功能机制,探究基于DHX36与富含鸟嘌呤序列互作的免疫反应酶学活性基础和靶向药物设计提供了理论与实验基础。     

随机单链DNA文库SELEX筛选寡核苷酸适配子方法的建立

指数富集配基的系统进化(SELEX)技术是一种新的组合化学技术.体外构建了一个长度为81 nt、含有35个随机序列的单链DNA(ssDNA)文库,优化了ssDNA文库扩增为双链DNA (dsDNA)文库的PCR反应条件.通过对比不对称PCR和生物素-链亲和素磁珠分离方法制备ssDNA文库的效果,确定了以生物素-链亲和素磁珠分离方法制备ssDNA.由于脱氧核糖核酸的疏水性导致ssDNA文库与硝酸纤维素滤膜的结合背景过高,因此选择以微孔板为介质,分离与靶蛋白结合的适配子.经过9轮循环筛选,随机ssDNA文库与丙型肝炎病毒(HCV)核心蛋白(C蛋白)的结合率从0.5%上升到32.5%.     

退火解旋酶SMARCAL1在维持基因组稳定中的作用与机制

SMARCAL1是属于SWI/SNF (SWItch/Sucrose Non-Fermentable)相关、基质相关和激动蛋白依赖的染色质调节因子家族成员ATP驱动的DNA退火解旋酶。SMARCAL1在体外和体内能催化单链结合蛋白RPA结合的DNA单链与其互补链退火成双链DNA。人Smarcal1基因的突变与Schimke免疫骨性发育不良(Schimke immuno-osseous dysplasia, SIOD)所能表现出的临床症状呈高度相关。本文对SMARCAL1在DNA损伤部位DNA复制叉的重塑、在DNA双链断裂(double-stranded DNA, dsDNA)处参与经典的非同源末端连接(non-homologous end joining, NHEJ)修复,以及在人染色体端粒完整性维护等方面的作用与机制进行了梳理,对Smarcal1基因突变类型与SIOD症状之间的对应关系进行了更新,并对SMARCAL1在三核苷酸重复序列扩增关联的神经–肌肉退行性病变过程中的可能作用进行了分析和讨论,旨在更好地理解该退火解旋酶在维持基因组稳定中的作用和机制。     

Biochemical characterization of the DNA helicase activity of the escherichia coli RecQ helicase

We demonstrate that RecQ helicase from Escherichia coli is a catalytic helicase whose activity depends on the concentration of ATP, free magnesium ion, and single-stranded DNA-binding (SSB) protein. Helicase activity is cooperative in ATP concentration, with an apparent S(0.5) value for ATP of 200 microm and a Hill coefficient of 3.3 +/- 0.3. Therefore, RecQ helicase utilizes multiple, interacting ATP-binding sites to mediate double-stranded DNA (dsDNA) unwinding, implicating a multimer of at least three subunits as the active unwinding species. Unwinding activity is independent of dsDNA ends, indicating that RecQ helicase can unwind from both internal regions and ends of dsDNA. The K(M) for dsDNA is 0.5-0.9 microm base pairs; the k(cat) for DNA unwinding is 2.3-2.7 base pairs/s/monomer of RecQ helicase; and unexpectedly, helicase activity is optimal at a free magnesium ion concentration of 0.05 mm. Omitting Escherichia coli SSB protein lowers the rate and extent of dsDNA unwinding, suggesting that RecQ helicase associates with the single-stranded DNA (ssDNA) product. In agreement, the ssDNA-dependent ATPase activity is reduced in proportion to the SSB protein concentration; in its absence, ATPase activity saturates at six nucleotides/RecQ helicase monomer and yields a k(cat) of 24 s(-1). Thus, we conclude that SSB protein stimulates RecQ helicase-mediated unwinding by both trapping the separated ssDNA strands after unwinding and preventing the formation of non-productive enzyme-ssDNA complexes.     

The Escherichia coli RecQ helicase functions as a monomer

The RecQ helicases belong to an important family of highly conserved DNA helicases that play a key role in chromosomal maintenance, and their defects have been shown to lead to several disorders and cancer in humans. In this work, the conformational and functional properties of the Escherichia coli RecQ helicase have been determined using a wide array of biochemical and biophysical techniques. The results obtained clearly indicate that E. coli RecQ helicase is monomeric in solution up to a concentration of 20 microM and in a temperature range between 4 and 37 degrees C. Furthermore, these properties are not affected by the presence of ATP, which is strictly required for the unwinding and translocating activity of the protein, or by its nonhydrolyzable analogue 5'-adenylyl-beta,gamma-imidodiphosphate. Consistent with the structural properties, functional analysis shows that both DNA unwinding activity and single-stranded DNA-stimulated ATPase specific activity were independent of RecQ concentration. The monomeric state was further confirmed by the ATPase-deficient mutants of RecQ protein. The rate of unwinding was unchanged when the wild type RecQ helicase was mixed with the ATPase-deficient mutants, indicating that nonprotein-protein interactions were involved in the unwinding processes. Taken together, these results indicate that RecQ helicase functions as a monomer and provide new data on the structural and functional properties of RecQ helicase that may help elucidate its mechanism action.     

Translocation of E. coli RecQ helicase on single-stranded DNA

A member of the SF2 family of helicases, Escherichia coli RecQ, is involved in the recombination and repair of double-stranded DNA breaks and single-stranded DNA (ssDNA) gaps. Although the unwinding activity of this helicase has been studied biochemically, the mechanism of translocation remains unclear. To this end, using ssDNA of varying lengths, the steady-state ATP hydrolysis activity of RecQ was analyzed. We find that the rate of ATP hydrolysis increases with DNA length, reaching a maximum specific activity of 38 ± 2 ATP/RecQ/s. Analysis of the rate of ATP hydrolysis as a function of DNA length implies that the helicase has a processivity of 19 ± 6 nucleotides on ssDNA and that RecQ requires a minimal translocation site size of 10 ± 1 nucleotides. Using the T4 phage encoded gene 32 protein (G32P), which binds ssDNA cooperatively, to decrease the lengths of ssDNA gaps available for translocation, we observe a decrease in the rate of ATP hydrolysis activity that is related to lattice occupancy. Analysis of the activity in terms of the average gap sizes available to RecQ on the ssDNA coated with G32P indicates that RecQ translocates on ssDNA on average 46 ± 11 nucleotides before dissociating. Moreover, when bound to ssDNA, RecQ hydrolyzes ATP in a cooperative fashion, with a Hill coefficient of 2.1 ± 0.6, suggesting that at least a dimer is required for translocation on ssDNA. We present a kinetic model for translocation by RecQ on ssDNA based on this characterization.     

Structural basis for DNA strand separation by a hexameric replicative helicase

Hexameric helicases are processive DNA unwinding machines but how they engage with a replication fork during unwinding is unknown. Using electron microscopy and single particle analysis we determined structures of the intact hexameric helicase E1 from papillomavirus and two complexes of E1 bound to a DNA replication fork end-labelled with protein tags. By labelling a DNA replication fork with streptavidin (dsDNA end) and Fab (5′ ssDNA) we located the positions of these labels on the helicase surface, showing that at least 10 bp of dsDNA enter the E1 helicase via a side tunnel. In the currently accepted ‘steric exclusion’ model for dsDNA unwinding, the active 3′ ssDNA strand is pulled through a central tunnel of the helicase motor domain as the dsDNA strands are wedged apart outside the protein assembly. Our structural observations together with nuclease footprinting assays indicate otherwise: strand separation is taking place inside E1 in a chamber above the helicase domain and the 5′ passive ssDNA strands exits the assembly through a separate tunnel opposite to the dsDNA entry point. Our data therefore suggest an alternative to the current general model for DNA unwinding by hexameric helicases.     

RecQ helicase and topoisomerase III comprise a novel DNA strand passage function: a conserved mechanism for control of DNA recombination.

E. coli RecQ protein is a multifunctional helicase with homologs that include the S. cerevisiae Sgs1 helicase and the H. sapiens Wrn and Blm helicases. Here we show that RecQ helicase unwinds a covalently closed double-stranded DNA (dsDNA) substrate and that this activity specifically stimulates E. coli topoisomerase III (Topo III) to fully catenate dsDNA molecules. We propose that these proteins functionally interact and that their shared activity is responsible for control of DNA recombination. RecQ helicase has a comparable effect on the Topo III homolog of S. cerevisiae, consistent with other RecQ and Topo III homologs acting together in a similar capacity. These findings highlight a novel, conserved activity that offers insight into the function of the other RecQ-like helicases.     

Coupling DNA-binding and ATP hydrolysis in Escherichia coli RecQ: role of a highly conserved aromatic-rich sequence

RecQ enzymes are broadly conserved Superfamily-2 (SF-2) DNA helicases that play critical roles in DNA metabolism. RecQ proteins use the energy of ATP hydrolysis to drive DNA unwinding; however, the mechanisms by which RecQ links ATPase activity to DNA-binding/unwinding are unknown. In many Superfamily-1 (SF-1) DNA helicases, helicase sequence motif III links these activities by binding both single-stranded (ss) DNA and ATP. However, the ssDNA-binding aromatic-rich element in motif III present in these enzymes is missing from SF-2 helicases, raising the question of how these enzymes link ATP hydrolysis to DNA-binding/unwinding. We show that Escherichia coli RecQ contains a conserved aromatic-rich loop in its helicase domain between motifs II and III. Although placement of the RecQ aromatic-rich loop is topologically distinct relative to the SF-1 enzymes, both loops map to similar tertiary structural positions. We examined the functions of the E.coli RecQ aromatic-rich loop using RecQ variants with single amino acid substitutions within the segment. Our results indicate that the aromatic-rich loop in RecQ is critical for coupling ATPase and DNA-binding/unwinding activities. Our studies also suggest that RecQ's aromatic-rich loop might couple ATP hydrolysis to DNA-binding in a mechanistically distinct manner from SF-1 helicases.     

Characterization of Biochemical Properties of Bacillus subtilis RecQ Helicase

RecQ family helicases function as safeguards of the genome. Unlike Escherichia coli, the Gram-positive Bacillus subtilis bacterium possesses two RecQ-like homologues, RecQ[Bs] and RecS, which are required for the repair of DNA double-strand breaks. RecQ[Bs] also binds to the forked DNA to ensure a smooth progression of the cell cycle. Here we present the first biochemical analysis of recombinant RecQ[Bs]. RecQ[Bs] binds weakly to single-stranded DNA (ssDNA) and blunt-ended double-stranded DNA (dsDNA) but strongly to forked dsDNA. The protein exhibits a DNA-stimulated ATPase activity and ATP- and Mg²⁺-dependent DNA helicase activity with a 3′→5′ polarity. Molecular modeling shows that RecQ[Bs] shares high sequence and structure similarity with E. coli RecQ. Surprisingly, RecQ[Bs] resembles the truncated Saccharomyces cerevisiae Sgs1 and human RecQ helicases more than RecQ[Ec] with regard to its enzymatic activities. Specifically, RecQ[Bs] unwinds forked dsDNA and DNA duplexes with a 3′-overhang but is inactive on blunt-ended dsDNA and 5′-overhung duplexes. Interestingly, RecQ[Bs] unwinds blunt-ended DNA with structural features, including nicks, gaps, 5′-flaps, Kappa joints, synthetic replication forks, and Holliday junctions. We discuss these findings in the context of RecQ[Bs]''s possible functions in preserving genomic stability.     

Model for helicase translocating along single-stranded DNA and unwinding double-stranded DNA

A model is proposed for non-hexameric helicases translocating along single-stranded (ss) DNA and unwinding double-stranded (ds) DNA. The translocation of a monomeric helicase along ssDNA in weakly-ssDNA-bound state is driven by the Stokes force that is resulted from the conformational change following the transition of the nucleotide state. The unwinding of dsDNA is resulted mainly from the bending of ssDNA induced by the strong binding force of helicase with dsDNA. The interaction force between ssDNA and helicases in weakly-ssDNA-bound state determines whether monomeric helicases such as PcrA can unwind dsDNA or dimeric helicases such as Rep are required to unwind dsDNA.     

Yeast Pif1 Helicase Exhibits a One-base-pair Stepping Mechanism for Unwinding Duplex DNA

Kinetic analysis of the DNA unwinding and translocation activities of helicases is necessary for characterization of the biochemical mechanism(s) for this class of enzymes. Saccharomyces cerevisiae Pif1 helicase was characterized using presteady state kinetics to determine rates of DNA unwinding, displacement of streptavidin from biotinylated DNA, translocation on single-stranded DNA (ssDNA), and ATP hydrolysis activities. Unwinding of substrates containing varying duplex lengths was fit globally to a model for stepwise unwinding and resulted in an unwinding rate of ∼75 bp/s and a kinetic step size of 1 base pair. Pif1 is capable of displacing streptavidin from biotinylated oligonucleotides with a linear increase in the rates as the length of the oligonucleotides increased. The rate of translocation on ssDNA was determined by measuring dissociation from varying lengths of ssDNA and is essentially the same as the rate of unwinding of dsDNA, making Pif1 an active helicase. The ATPase activity of Pif1 on ssDNA was determined using fluorescently labeled phosphate-binding protein to measure the rate of phosphate release. The quantity of phosphate released corresponds to a chemical efficiency of 0.84 ATP/nucleotides translocated. Hence, when all of the kinetic data are considered, Pif1 appears to move along DNA in single nucleotide or base pair steps, powered by hydrolysis of 1 molecule of ATP.