A Model for Competency-Based Grading and Its Effect on Student Outcomes in a Biomechanics Course.

Competency-based grading (CBG) can take different forms in different subject areas. We present a method for implementing CBG in a biomechanics course with nine primary learning objectives. Competency in each learning objective is measured by the student's ability to correctly answer knowledge questions and solve analytical problems in the field of biomechanics. The primary goal of implementing CBG was to provide more opportunities for lower-performing students to learn the material and to demonstrate that learning. To determine the efficacy of CBG to improve student learning, the primary measure was course grade distribution before and after implementation of CBG. The course grade distribution data indicated that CBG has primarily helped midperforming students to improve their grades. Because of the limitations of course grades as a measure of learning, we also performed analysis of student performance on successive attempts which indicated initial and secondary attempts are best, with student success declining on subsequent attempts. Anecdotally, many students improved performance, and thus their grade, on the (optional) final exam attempts. Limitations of the study include the limited course offerings with CBG (three), and that effects of COVID-19 may be confounding CBG data. Also, the approach places nearly all the grade on quizzes or exams. However, the approach could be modified to include homework grades, projects, and the like. Overall, the student learning in this course and implementation appears to be only positively affected, so this approach appears to have benefits in a biomechanics course.

Low processivity for DNA translocation by the ISWI molecular motor.

The motor protein ISWI (Imitation SWItch) is the conserved catalytic ATPase domain of the ISWI family of chromatin remodelers. Members of the ISWI family are involved in regulating the structure of cellular chromatin during times of transcription, translation, and repair. Current models for the nucleosome repositioning activity of ISWI and other chromatin remodelers require the translocation of the remodeling protein along double-stranded DNA through an ATP-dependent mechanism. Here we report results from spectrofluorometric stopped-flow experiments which demonstrate that ISWI displays very low processivity for free DNA translocation. By combining these results with those from experiments monitoring the DNA stimulated ATPase activity of ISWI we further demonstrate that the DNA translocation by ISWI is tightly coupled to ATP hydrolysis. The calculated coupling efficiency of 0.067±0.018 ATP/ISWI/bp is seemingly quite low in comparison to similar DNA translocases and we present potential models to account for this. Nevertheless, the tight coupling of ATP hydrolysis to DNA translocation suggests that DNA translocation is not energetically rate limiting for nucleosome repositioning by ISWI.

ISWI remodels nucleosomes through a random walk.

The chromatin remodeler ISWI is capable of repositioning clusters of nucleosomes to create well-ordered arrays or moving single nucleosomes from the center of DNA fragments toward the ends without disrupting their integrity. Using standard electrophoresis assays, we have monitored the ISWI-catalyzed repositioning of different nucleosome samples each containing a different length of DNA symmetrically flanking the initially centrally positioned histone octamer. We find that ISWI moves the histone octamer between distinct and thermodynamically stable positions on the DNA according to a random walk mechanism. Through the application of a spectrophotometric assay for nucleosome repositioning, we further characterized the repositioning activity of ISWI using short nucleosome substrates and were able to determine the macroscopic rate of nucleosome repositioning by ISWI. Additionally, quantitative analysis of repositioning experiments performed at various ISWI concentrations revealed that a monomeric ISWI is sufficient to obtain the observed repositioning activity as the presence of a second ISWI bound had no effect on the rate of nucleosome repositioning. We also found that ATP hydrolysis is poorly coupled to nucleosome repositioning, suggesting that DNA translocation by ISWI is not energetically rate-limiting for the repositioning reaction. This is the first calculation of a microscopic ATPase coupling efficiency for nucleosome repositioning and also further supports our conclusion that a second bound ISWI does not contribute to the repositioning reaction.

Quantitative determination of binding of ISWI to nucleosomes and DNA shows allosteric regulation of DNA binding by nucleotides.

The regulation of chromatin structure is controlled by a family of molecular motors called chromatin remodelers. The ability of these enzymes to remodel chromatin structure is dependent on their ability to couple ATP binding and hydrolysis into the mechanical work that drives nucleosome repositioning. The necessary first step in determining how these essential enzymes perform this function is to characterize both how they bind nucleosomes and how this interaction is regulated by ATP binding and hydrolysis. With this goal in mind, we monitored the interaction of the chromatin remodeler ISWI with fluorophore-labeled nucleosomes and DNA through associated changes in fluorescence anisotropy of the fluorophore upon binding of ISWI to these substrates. We determined that one ISWI molecule binds to a 20 bp double-stranded DNA substrate with an affinity of 18 ± 2 nM. In contrast, two ISWI molecules can bind to the core nucleosome with short linker DNA with stoichiometric macroscopic equilibrium constants: 1/ß1 = 1.3 ± 0.6 nM, and 1/ß2 = 13 ± 7 nM(2). Furthermore, to improve our understanding of the mechanism of DNA translocation by ISWI, and hence nucleosome repositioning, we determined the effect of nucleotide analogues on substrate binding by ISWI. While the affinity of ISWI for the nucleosome substrate with short lengths of flanking DNA was not affected by the presence of nucleotides, the affinity of ISWI for the DNA substrate is weakened in the presence of nonhydrolyzable ATP analogues but not by ADP.

Subunit Communication within Dimeric SF1 DNA Helicases.

Monomers of the Superfamily (SF) 1 helicases, E. coli Rep and UvrD, can translocate directionally along single stranded (ss) DNA, but must be activated to function as helicases. In the absence of accessory factors, helicase activity requires Rep and UvrD homo-dimerization. The ssDNA binding sites of SF1 helicases contain a conserved aromatic amino acid (Trp250 in Rep and Trp256 in UvrD) that stacks with the DNA bases. Here we show that mutation of this Trp to Ala eliminates helicase activity in both Rep and UvrD. Rep(W250A) and UvrD(W256A) can still dimerize, bind DNA, and monomers still retain ATP-dependent ssDNA translocase activity, although with ∼10-fold lower rates and lower processivities than wild type monomers. Although neither wtRep monomers nor Rep(W250A) monomers possess helicase activity by themselves, using both ensemble and single molecule methods, we show that helicase activity is achieved upon formation of a Rep(W250A)/wtRep hetero-dimer. An ATPase deficient Rep monomer is unable to activate a wtRep monomer indicating that ATPase activity is needed in both subunits of the Rep hetero-dimer. We find the same results with E. coli UvrD and its equivalent mutant (UvrD(W256A)). Importantly, Rep(W250A) is unable to activate a wtUvrD monomer and UvrD(W256A) is unable to activate a wtRep monomer indicating that specific dimer interactions are required for helicase activity. We also demonstrate subunit communication within the dimer by virtue of Trp fluorescence signals that only are present within the Rep dimer, but not the monomers. These results bear on proposed subunit switching mechanisms for dimeric helicase activity.

Kinetic mechanism of DNA translocation by the RSC molecular motor.

ATP-dependent nucleosome repositioning by chromatin remodeling enzymes requires the translocation of these enzymes along the nucleosomal DNA. Using a fluorescence stopped-flow assay we monitored DNA translocation by a minimal RSC motor and through global analysis of these time courses we have determined that this motor has a macroscopic translocation rate of 2.9 bp/s with a step size of 1.24 bp. From the complementary quantitative analysis of the associated time courses of ATP consumption during DNA translocation we have determined that this motor has an efficiency of 3.0 ATP/bp, which is slightly less that the efficiency observed for several genetically related DNA helicases and which likely results from random pausing by the motor during translocation. Nevertheless, this motor is able to exert enough force during translocation to displace streptavidin from biotinylated DNA. Taken together these results are the necessary first step for quantifying both the role of DNA translocation in nucleosome repositioning by RSC and the efficiency at which RSC couples ATP binding and hydrolysis to nucleosome repositioning.

Allosteric interactions of DNA and nucleotides with S. cerevisiae RSC.

RSC (remodel the structure of chromatin) is an essential chromatin remodeler of Saccharomyces cerevisiae that has been shown to have DNA translocase properties. We studied the DNA binding properties of a "trimeric minimal RSC" (RSCt) of the RSC chromatin remodeling complex and the effect of nucleotides on this interaction using fluorescence anisotropy. RSCt binds to 20 bp fluorescein-labeled double-stranded DNA with a K(d) of ∼100 nM. The affinity of RSCt for DNA is reduced in the presence of AMP-PNP and ADP in a concentration-dependent manner with the addition of AMP-PNP having more pronounced effect. These differences in the magnitude at which the binding of ADP and AMP-PNP affects the affinity of DNA binding by RSCt suggest that the physical movement of the enzyme along DNA begins between the binding of ATP and its subsequent hydrolysis. Furthermore, the fact that the highest affinity for DNA binding by RSCt occurs in the absence of bound nucleotide offers a mechanistic explanation for the apparent low processivity of DNA translocation by the enzyme.

Reducing heterophilic antibody interference in immunoassays using single-chain antibodies.

Sandwich enzyme-linked immunosorbent assay (ELISA) microarrays can simultaneously quantify the levels of multiple diagnostic targets in a biological sample. However, as with traditional ELISA diagnostics, endogenous antibodies in patient sera can cause interference. We demonstrate here that reducing the diagnostic capture antibody to its minimal functional unit (i.e., a single-chain antibody fragment [scFv]) is an effective strategy for reducing assay interference. Our finding illustrates a source of error introduced by the reliance on immunoglobulin-based capture reagents in sandwich immunoassays with human serum samples. We demonstrate that scFvs can be used in such assays to improve reliability by reducing heterophilic antibody interference, thereby improving biomarker analysis and validation.

Ensemble methods for monitoring enzyme translocation along single stranded nucleic acids.

We review transient kinetic methods developed to study the mechanism of translocation of nucleic acid motor proteins. One useful stopped-flow fluorescence method monitors arrival of the translocase at the end of a fluorescently labeled nucleic acid. When conducted under single-round conditions the time courses can be analyzed quantitatively using n-step sequential models to determine the kinetic parameters for translocation (rate, kinetic step size and processivity). The assay and analysis discussed here can be used to study enzyme translocation along a linear lattice such as ssDNA or ssRNA. We outline the methods for experimental design and two approaches, along with their limitations, that can be used to analyze the time courses. Analysis of the full time courses using n-step sequential models always yields an accurate estimate of the translocation rate. An alternative semi-quantitative "time to peak" analysis yields accurate estimates of translocation rates only if the enzyme initiates translocation from a unique site on the nucleic acid. However, if initiation occurs at random sites along the nucleic acid, then the "time to peak" analysis can yield inaccurate estimates of even the rates of translocation depending on the values of other kinetic parameters, especially the rate of dissociation of the translocase. Thus, in those cases analysis of the full time course is needed to obtain accurate estimates of translocation rates.

Structural studies of bacterioferritin B from Pseudomonas aeruginosa suggest a gating mechanism for iron uptake via the ferroxidase center .

The structure of recombinant Pseudomonas aeruginosa bacterioferritin B (Pa BfrB) has been determined from crystals grown from protein devoid of core mineral iron (as-isolated) and from protein mineralized with approximately 600 iron atoms (mineralized). Structures were also obtained from crystals grown from mineralized BfrB after they had been soaked in an FeSO(4) solution (Fe soak) and in separate experiments after they had been soaked in an FeSO(4) solution followed by a soak in a crystallization solution (double soak). Although the structures consist of a typical bacterioferritin fold comprised of a nearly spherical 24-mer assembly that binds 12 heme molecules, comparison of microenvironments observed in the distinct structures provided interesting insights. The ferroxidase center in the as-isolated, mineralized, and double-soak structures is empty. The ferroxidase ligands (except His130) are poised to bind iron with minimal conformational changes. The His130 side chain, on the other hand, must rotate toward the ferroxidase center to coordinate iron. In comparison, the structure obtained from crystals soaked in an FeSO(4) solution displays a fully occupied ferroxidase center and iron bound to the internal, Fe((in)), and external, Fe((out)), surfaces of Pa BfrB. The conformation of His130 in this structure is rotated toward the ferroxidase center and coordinates an iron ion. The structures also revealed a pore on the surface of Pa BfrB that likely serves as a port of entry for Fe(2+) to the ferroxidase center. On its opposite end, the pore is capped by the side chain of His130 when it adopts its "gate-closed" conformation that enables coordination to a ferroxidase iron. A change to its "gate-open", noncoordinative conformation creates a path for the translocation of iron from the ferroxidase center to the interior cavity. These structural observations, together with findings obtained from iron incorporation measurements in solution, suggest that the ferroxidase pore is the dominant entry route for the uptake of iron by Pa BfrB. These findings, which are clearly distinct from those made with Escherichia coli Bfr [Crow, A. C., Lawson, T. L., Lewin, A., Moore, G. R., and Le Brun, N. E. (2009) J. Am. Chem. Soc. 131, 6808-6813], indicate that not all bacterioferritins operate in the same manner.

Investigation of translocation, DNA unwinding, and protein displacement by NS3h, the helicase domain from the hepatitis C virus helicase.

Helicases are motor proteins that are involved in DNA and RNA metabolism, replication, recombination, transcription, and repair. The motors are powered by ATP binding and hydrolysis. Hepatitis C virus encodes a helicase called nonstructural protein (NS3). NS3 possesses protease and helicase activities on its N-terminal and C-terminal domains, respectively. The helicase domain of NS3 is termed NS3h. In vitro, NS3h catalyzes RNA and DNA unwinding in a 3'-5' direction. The directionality of unwinding is thought to arise in part from the enzyme's ability to translocate along DNA, but translocation has not been shown explicitly. We examined the DNA translocase activity of NS3h by using single-stranded oligonucleotide substrates containing a fluorescent probe on the 5' end. NS3h can bind to the ssDNA and in the presence of ATP move toward the 5' end. When the enzyme encounters the fluorescent probe, a fluorescence change is observed that allows translocation to be characterized. Under conditions that favor binding of one NS3h per DNA substrate (100 nM NS3h and 200 nM oligonucleotide), we find that NS3h translocates on ssDNA at a rate of 46 +/- 5 nucleotides/s, and that it can move for 230 +/- 60 nucleotides before dissociating from the DNA. The translocase activity of some helicases is responsible for displacing proteins that are bound to DNA. We studied protein displacement by using a ssDNA oligonucleotide covalently linked to biotin on the 5' end. Upon addition of streptavidin, a "protein block" was placed in the pathway of the helicase. Interestingly, NS3h was unable to displace streptavidin from the end of the oligonucleotide, despite its ability to translocate along the DNA. The DNA unwinding activity of NS3h was examined using a 22 bp duplex DNA substrate under conditions that were identical to those used to study translocation. NS3h exhibited little or no DNA unwinding under single-cycle conditions, supporting the conclusion that NS3h is a relatively poor helicase in its monomeric form, as has been reported. In summary, NS3h translocates on ssDNA as a monomer, but the translocase activity does not correspond to comparable DNA unwinding activity or protein displacement activity under identical conditions.

Kinetic mechanism for single-stranded DNA binding and translocation by Saccharomyces cerevisiae Isw2.

The chromatin remodeling complex Isw2 from Saccharomyces cerevisiae (yIsw2) mobilizes nucleosomes through an ATP-dependent reaction that is coupled to the translocation of the helicase domain of the enzyme along intranucleosomal DNA. In this study, we demonstrate that yIsw2 is capable of translocating along single-stranded DNA in a reaction that is coupled to ATP hydrolysis. We propose that single-stranded DNA translocation by yIsw2 occurs through a series of repeating uniform steps with an overall macroscopic processivity (P) of 0.90 +/- 0.02, corresponding to an average translocation distance of 20 +/- 2 nucleotides before dissociation. This processivity corresponds well to the processivity of nucleosome sliding by yIsw2, thus arguing that single-stranded DNA translocation or tracking may be fundamental to the double-stranded DNA translocation required for effective nucleosome mobilization. Furthermore, we find evidence that a slow initiation process, following DNA binding, may be required to make yIsw2 competent for DNA translocation. We also provide evidence that this slow initiation process may correspond to the second step of a two-step DNA binding mechanism by yIsw2 and a quantitative description of the kinetics of this DNA binding mechanism.

Molecular motor translocation kinetics: Application of Monte Carlo computer simulations to determine microscopic kinetic parameters.

Methods for studying the translocation of motor proteins along a filament (e.g., nucleic acid and polypeptide) typically monitor the total production of ADP, the arrival/departure of the motor protein at/from a particular location (often one end of the filament), or the dissociation of the motor protein from the filament. The associated kinetic time courses are often analyzed using a simple sequential uniform n-step mechanism to estimate the macroscopic kinetic parameters (e.g., translocation rate and processivity) and the microscopic kinetic parameters (e.g., kinetic step-size and the rate constant for the rate-limiting step). These sequential uniform n-step mechanisms assume repetition of uniform and irreversible rate-limiting steps of forward motion along the filament. In order to determine how the presence of non-uniform motion (e.g., backward motion, random pauses, or jumping) affects the estimates of parameters obtained from such analyses, we evaluated computer simulated translocation time courses containing non-uniform motion using a simple sequential uniform n-step model. By comparing the kinetic parameters estimated from the analysis of the data generated by these simulations with the input parameters of the simulations, we were able to determine which of the kinetic parameters were likely to be over/under estimated due to non-uniform motion of the motor protein.

Anisotropy-Based Nucleosome Repositioning Assay.

Most eukaryotic DNA is tightly packaged into nucleosomes that render these sequences largely inaccessible for transcription or repair. Molecular motors called chromatin remodelers use an ATP-dependent mechanism to relieve the inhibition of these processes by sliding or disassembling the nucleosomes. This allows them to serve an essential role in the regulation of gene expression and genomic integrity. The sliding of nucleosomes along DNA can be studied directly by monitoring the associated changes in the fluorescence anisotropy of fluorophores attached to the ends of the DNA. Nucleosome repositioning can also be monitored indirectly through the ATP hydrolysis of the chromatin remodeler during the sliding reaction. Here we discuss how the kinetic data collected in these experiments can be analyzed by simultaneous global nonlinear least squares (NLLS) analysis using simple sequential "n-step" mechanisms to obtain estimates of the macroscopic rate of nucleosome repositioning and of the stoichiometry of coupling ATP binding and hydrolysis to this reaction.

Effects of nucleosome stability on remodeler-catalyzed repositioning.

Chromatin remodelers are molecular motors that play essential roles in the regulation of nucleosome positioning and chromatin accessibility. These machines couple the energy obtained from the binding and hydrolysis of ATP to the mechanical work of manipulating chromatin structure through processes that are not completely understood. Here we present a quantitative analysis of nucleosome repositioning by the imitation switch (ISWI) chromatin remodeler and demonstrate that nucleosome stability significantly impacts the observed activity. We show how DNA damage induced changes in the affinity of DNA wrapping within the nucleosome can affect ISWI repositioning activity and demonstrate how assay-dependent limitations can bias studies of nucleosome repositioning. Together, these results also suggest that some of the diversity seen in chromatin remodeler activity can be attributed to the variations in the thermodynamics of interactions between the remodeler, the histones, and the DNA, rather than reflect inherent properties of the remodeler itself.

ATP-dependent translocation of proteins along single-stranded DNA: models and methods of analysis of pre-steady state kinetics.

Processive DNA helicases are able to translocate along single-stranded DNA (ssDNA) with biased directionality in a nucleoside triphosphate-dependent reaction, although translocation is not generally sufficient for helicase activity. An understanding of the mechanism of protein translocation along ssDNA requires pre-steady state transient kinetic experiments. Although ensemble experimental approaches have been developed recently for the study of translocation of proteins along DNA, quantitative analysis of the complete time-courses from these experiments, which is needed to obtain quantitative estimates of translocation kinetic parameters (rate constants, processivity, step sizes and ATP coupling) has been lacking. We discuss three ensemble transient kinetic experiments that can be used to study protein translocation along ssDNA, along with the advantages and limitations of each approach. We further describe methods to analyze the complete kinetic time-courses obtained from such experiments performed with a series of ssDNA lengths under "single-round" conditions (i.e. in the absence of re-binding of dissociated protein to DNA). These analysis methods utilize a sequential "n-step" model for protein translocation along ssDNA and enable quantitative determinations of the rate constant, processivity and step size for translocation through global non-linear least-squares fitting of the full time-courses.

Mechanism of ATP-dependent translocation of E.coli UvrD monomers along single-stranded DNA.

Escherichia coli UvrD protein is a 3' to 5' SF1 DNA helicase involved in methyl-directed mismatch repair and nucleotide excision repair of DNA. Using stopped-flow methods we have examined the kinetic mechanism of translocation of UvrD monomers along single-stranded DNA (ssDNA) in vitro by monitoring the transient kinetics of arrival of protein at the 5'-end of the ssDNA. Arrival at the 5'-end was monitored by the effect of protein on the fluorescence intensity of fluorophores (Cy3 or fluorescein) attached to the 5'-end of a series of oligodeoxythymidylates varying in length from 16 to 124 nt. We find that UvrD monomers are capable of ATP-dependent translocation along ssDNA with a biased 3' to 5' directionality. Global non-linear least-squares analysis of the full kinetic time-courses in the presence of a protein trap to prevent rebinding of free protein to the DNA using the methods described in the accompanying paper enabled us to obtain quantitative estimates of the kinetic parameters for translocation. We find that UvrD monomers translocate in discrete steps with an average kinetic step-size, m=3.68(+/-0.03) nt step(-1), a translocation rate constant, kt=51.3(+/-0.6) steps s(-1), (macroscopic translocation rate, mkt=189.0(+/-0.7) nt s(-1)), with a processivity corresponding to an average translocation distance of 2400(+/-600) nt before dissociation (10 mM Tris-HCl (pH 8.3), 20 mM NaCl, 20% (v/v) glycerol, 25 degrees C). However, in spite of its ability to translocate rapidly and efficiently along ssDNA, a UvrD monomer is unable to unwind even an 18 bp duplex in vitro. DNA helicase activity in vitro requires a UvrD dimer that unwinds DNA with a similar kinetic step-size of 4-5 bp step(-1), but an approximately threefold slower unwinding rate of 68(+/-9) bp s(-1) under the same solution conditions, indicating that DNA unwinding activity requires more than the ability to simply translocate directionally along ss-DNA.

A Dimer of Escherichia coli UvrD is the active form of the helicase in vitro.

The Escherichia coli UvrD protein is a 3' to 5' SF1 DNA helicase involved in methyl-directed mismatch repair and nucleotide excision repair of DNA. We have characterized in vitro UvrD-catalyzed unwinding of a series of 18 bp duplex DNA substrates with 3' single-stranded DNA (ssDNA) tails ranging in length from two to 40 nt. Single turnover DNA-unwinding experiments were performed using chemical quenched flow methods, as a function of both [UvrD] and [DNA] under conditions such that UvrD-DNA binding is stoichiometric. Although a single UvrD monomer binds tightly to the single-stranded/double-stranded DNA (dsDNA) junction if the 3' ssDNA tail is at least four nt, no unwinding was observed for DNA substrates with tail-lengths /=12 nt, and the unwinding amplitude displays a sigmoidal dependence on [UvrD(tot)]/[DNA(tot)]. Quantitative analysis of these data indicates that a single UvrD monomer bound at the ssDNA/dsDNA junction of any DNA substrate, independent of 3' ssDNA tail length, is not competent to fully unwind even a short 18 bp duplex DNA, and that two UvrD monomers must bind the DNA substrate in order to form a complex that is able to unwind short DNA substrates in vitro. Other proteins, including a mutant UvrD with no ATPase activity as well as a monomer of the structurally homologous E.coli Rep helicase, cannot substitute for the second UvrD monomer, suggesting a specific interaction between two UvrD monomers and that both must be able to hydrolyze ATP. Initiation of DNA unwinding in vitro appears to require a dimeric UvrD complex in which one subunit is bound to the ssDNA/dsDNA junction, while the second subunit is bound to the 3' ssDNA tail.

Trapping of intermediates with substrate analog HBOCoA in the polymerizations catalyzed by class III polyhydroxybutyrate (PHB) synthase from Allochromatium vinosum.

Polyhydroxybutyrate (PHB) synthases (PhaCs) catalyze the formation of biodegradable PHB polymers that are considered as an ideal alternative to petroleum-based plastics. To provide strong evidence for the preferred mechanistic model involving covalent and noncovalent intermediates, a substrate analog HBOCoA was synthesized chemoenzymatically. Substitution of sulfur in the native substrate HBCoA with an oxygen in HBOCoA enabled detection of (HB)nOCoA (n = 2-6) intermediates when the polymerization was catalyzed by wild-type (wt-)PhaECAv at 5.84 h(-1). This extremely slow rate is due to thermodynamically unfavorable steps that involve the formation of enzyme-bound PHB species (thioesters) from corresponding CoA oxoesters. Synthesized standards (HB)nOCoA (n = 2-3) were found to undergo both reacylation and hydrolysis catalyzed by the synthase. Distribution of the hydrolysis products highlights the importance of the penultimate ester group as previously suggested. Importantly, the reaction between primed synthase [(3)H]-sT-PhaECAv and HBOCoA yielded [(3)H]-sTet-O-CoA at a rate constant faster than 17.4 s(-1), which represents the first example that a substrate analog undergoes PHB chain elongation at a rate close to that of the native substrate (65.0 s(-1)). Therefore, for the first time with a wt-synthase, strong evidence was obtained to support our favored PHB chain elongation model.

All motors have to decide is what to do with the DNA that is given them.

DNA translocases are a diverse group of molecular motors responsible for a wide variety of cellular functions. The goal of this review is to identify common aspects in the mechanisms for how these enzymes couple the binding and hydrolysis of ATP to their movement along DNA. Not surprisingly, the shared structural components contained within the catalytic domains of several of these motors appear to give rise to common aspects of DNA translocation. Perhaps more interesting, however, are the differences between the families of translocases and the potential associated implications both for the functions of the members of these families and for the evolution of these families. However, as there are few translocases for which complete characterizations of the mechanisms of DNA binding, DNA translocation, and DNA-stimulated ATPase have been completed, it is difficult to form many inferences. We therefore hope that this review motivates the necessary further experimentation required for broader comparisons and conclusions.