Unwinding a path to nuclear beta-catenin

In this issue of Cell, Yang et al. (2006b) show that PDGF, a growth factor that induces the transition of epithelial cells to mesenchymal cells, stimulates the c-Abl kinase-dependent phosphorylation of p68 RNA helicase. Phosphorylated p68 dissociates beta-catenin from the Axin destruction complex, thereby promoting nuclear beta-catenin signaling independent of Wnt activation.     

Synthetic shuffling expands functional protein diversity by allowing amino acids to recombine independently

We describe synthetic shuffling, an evolutionary protein engineering technology in which every amino acid from a set of parents is allowed to recombine independently of every other amino acid. With the use of degenerate oligonucleotides, synthetic shuffling provides a direct route from database sequence information to functional libraries. Physical starting genes are unnecessary, and additional design criteria such as optimal codon usage or known beneficial mutations can also be incorporated. We performed synthetic shuffling of 15 subtilisin genes and obtained active and highly chimeric enzymes with desirable combinations of properties that we did not obtain by other directed-evolution methods.     

Unwinding of primer-templates by archaeal family-B DNA polymerases in response to template-strand uracil

Archaeal family-B DNA polymerases bind tightly to deaminated bases and stall replication on encountering uracil in template strands, four bases ahead of the primer-template junction. Should the polymerase progress further towards the uracil, for example, to position uracil only two bases in front of the junction, 3′–5′ proof-reading exonuclease activity becomes stimulated, trimming the primer and re-setting uracil to the +4 position. Uracil sensing prevents copying of the deaminated base and permanent mutation in 50% of the progeny. This publication uses both steady-state and time-resolved 2-aminopurine fluorescence to show pronounced unwinding of primer-templates with Pyrococcus furiosus (Pfu) polymerase–DNA complexes containing uracil at +2; much less strand separation is seen with uracil at +4. DNA unwinding has long been recognized as necessary for proof-reading exonuclease activity. The roles of M247 and Y261, amino acids suggested by structural studies to play a role in primer-template unwinding, have been probed. M247 appears to be unimportant, but 2-aminopurine fluorescence measurements show that Y261 plays a role in primer-template strand separation. Y261 is also required for full exonuclease activity and contributes to the fidelity of the polymerase.     

Unwinding the 'Gordian knot' of helicase action

Helicases are enzymes involved in every aspect of nucleic acid metabolism. Recent structural and biochemical evidence is beginning to provide details of their molecular mechanism of action. Crystal structures of helicases have revealed an underlying common structural fold. However, although there are many similarities between the mechanisms of different classes of helicase, not all aspects of the helicase activity are the same in all members of this enzyme family.     

Unwinding of forked DNA structures by UvrD

Many studies have demonstrated the need for processing of blocked replication forks to underpin genome duplication. UvrD helicase in Escherichia coli has been implicated in the processing of damaged replication forks, or the recombination intermediates formed from damaged forks. Here we show that UvrD can unwind forked DNA structures, in part due to the ability of UvrD to initiate unwinding from discontinuities within the phosphodiester backbone of DNA. UvrD does therefore have the capacity to target DNA intermediates of replication and recombination. Such an activity resulted in unwinding of what would be the parental duplex DNA ahead of either a stalled replication fork or a D-loop formed by recombination. However, UvrD had a substrate preference for fork structures having a nascent lagging strand at the branch point but no leading strand. Furthermore, at such structures the polarity of UvrD altered so that unwinding of the lagging strand predominated. This reaction is reminiscent of the PriC-Rep pathway of replication restart, suggesting that UvrD and Rep may have at least partially redundant functions.     

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.     

Letter: Unwinding the DNA helix by intercalation

Data relating to the effect of intercalating drugs on the winding of the DNA helix is re-considered. Analyses by Paoletti &; Le Pecq (1971) of fluorescence depolarization, X-ray diffraction and molecular model building are reappraised. It is concluded that the helix is unwound by ~12 ° as proposed by Fuller &; Waring (1964). This refutes the recent suggestion by Paoletti &; Le Pecq (1971) that the intercalation winds the helix by ~13 °.     

Unwinding of DNA induced by fluorescein mercuric acetate

Fluorescein mercuric acetate causes the unwinding of DNA and binds to the separated bases. This unwinding process can be followed by measuring absorption changes of this reagent. For untreated calf thymus DNA, the initial rate was very slow, and the shape of the kinetic curve was sigmoidal. When double-strand breaks of DNA were produced by DNase II treatment or sonication, the initial rate increased and the sigmoidal character disappeared. The initial rate was shown to be proportional to the concentration of helix ends. From this relation the rate of unwinding was estimated to be 2.0 base pairs/sec at 1.0 × 10^?5M fluorescein mercuric acetate and 25°C. DNase I treatment, which produces single-strand breaks and a smaller number of double-strand breaks, also increased the initial rate. However, this increase was due only to the double-strand breaks, that is, single-strand breaks had no significant effect on the initial rate. Also, uv irradiation increased the initial rate linearly with uv dose, at least up to 2 × 10⁵ erg/mm², suggesting that this increase is due to photoproducts other than usual pyrimidine dimers. We discuss the usefulness of this kinetic method in structural studies of DNA.     

Unwinding kinetics of cooperatively melting regions in DNA

Unwinding of a single cooperatively melting region of ColE1 DNA is investigated by a slow temperature jump in formamide–neutral buffer mixed solvent. The semilogarithmic plots of unwinding relaxation curves show a marked terminal linear region following the fast decay, which occurred within the temperature rise time (1 ～ 2 s). This longest relaxation is ascribed to the total unwinding of a single cooperatively melting region. The longest relaxation time, τ₁, is uniquely determined by the final equilibrium state and becomes shorter as the final temperature increases. Decrease in ionic strength makes τ₁ and its fractional amplitude increase, and the relaxation almost approaches single-exponential decay. The facts that (1) τ₁ of a single cooperatively melting region whose unwinding suffers larger frictional resistance does not always unwind more slowly, as was shown by the observations of τ₁'s of almost the same cooperatively melting region located at different positions on two linearized ColEl DNAs and of τ₁'s of two cooperatively melting regions on the same linearized ColEl DNA; (2) τ₁ has strong dependence on the equilibrium state after a temperature jump; and (3) the observed τ₁ is much longer than the expected time of the frictional barrier all demonstrate that the τ₁ is limited by chemical but not hydrodynamic processes. The detailed unwinding process of a single cooperatively melting region, elucidated by evidence of a negative apparent activation energy of the rewinding process and by extensive computer simulation of the equilibrium melting process, suggests that the local heterogeneity of G+C content in a cooperatively melting region, as well as its averaged G+C content, strongly affects its unwinding rate. The present study of a single cooperatively melting region is found to be useful to improve our understanding of the detailed mechanism of complex unwinding of large natural DNAs, in which many cooperatively melting regions unwind.     

Unwinding initiation by the viral RNA helicase NPH-II

Viral RNA helicases of the NS3/NPH-II group unwind RNA duplexes by processive, directional translocation on one of the duplex strands. The translocation is preceded by a poorly understood unwinding initiation phase. For NPH-II from vaccinia virus, unwinding initiation is rate limiting for the overall unwinding reaction. To develop a mechanistic understanding of the unwinding initiation, we studied kinetic and thermodynamic aspects of this reaction phase for NPH-II in vitro, using biochemical and single molecule fluorescence approaches. Our data show that NPH-II functions as a monomer and that different stages of the ATP hydrolysis cycle dictate distinct binding preferences of NPH-II for duplex versus single-stranded RNA. We further find that the NPH-II-RNA complex does not adopt a single conformation but rather at least two distinct conformations in each of the analyzed stages of ATP hydrolysis. These conformations interconvert with rate constants that depend on the stage of the ATP hydrolysis cycle. Our data establish a basic mechanistic framework for unwinding initiation by NPH-II and suggest that the various stages of the ATP hydrolysis cycle do not induce single, stage-specific conformations in the NPH-II-RNA complex but primarily control transitions between multiple states.     

Unwinding the functions of the Pif1 family helicases

Helicases are ubiquitous enzymes found in all organisms that are necessary for all (or virtually all) aspects of nucleic acid metabolism. The Pif1 helicase family is a group of 5′ → 3′ directed, ATP-dependent, super family IB helicases found in nearly all eukaryotes. Here, we review the discovery, evolution, and what is currently known about these enzymes in Saccharomyces cerevisiae (ScPif1 and ScRrm3), Schizosaccharomyces pombe (SpPfh1), Trypanosoma brucei (TbPIF1, 2, 5, and 8), mice (mPif1), and humans (hPif1). Pif1 helicases variously affect telomeric, ribosomal, and mitochondrial DNA replication, as well as Okazaki fragment maturation, and in at least some cases affect these processes by using their helicase activity to disrupt stable nucleoprotein complexes. While the functions of these enzymes vary within and between organisms, it is evident that Pif1 family helicases are crucial for both nuclear and mitochondrial genome maintenance.     

A Distinct Triplex DNA Unwinding Activity of ChlR1 Helicase

Mutations in the human ChlR1 (DDX11) gene are associated with a unique genetic disorder known as Warsaw breakage syndrome characterized by cellular defects in genome maintenance. The DNA triplex helix structures that form by Hoogsteen or reverse Hoogsteen hydrogen bonding are examples of alternate DNA structures that can be a source of genomic instability. In this study, we have examined the ability of human ChlR1 helicase to destabilize DNA triplexes. Biochemical studies demonstrated that ChlR1 efficiently melted both intermolecular and intramolecular DNA triplex substrates in an ATP-dependent manner. Compared with other substrates such as replication fork and G-quadruplex DNA, triplex DNA was a preferred substrate for ChlR1. Also, compared with FANCJ, a helicase of the same family, the triplex resolving activity of ChlR1 is unique. On the other hand, the mutant protein from a Warsaw breakage syndrome patient failed to unwind these triplexes. A previously characterized triplex DNA-specific antibody (Jel 466) bound triplex DNA structures and inhibited ChlR1 unwinding activity. Moreover, cellular assays demonstrated that there were increased triplex DNA content and double-stranded breaks in ChlR1-depleted cells, but not in FANCJ^−/− cells, when cells were treated with a triplex stabilizing compound benzoquinoquinoxaline, suggesting that ChlR1 melting of triple-helix structures is distinctive and physiologically important to defend genome integrity. On the basis of our results, we conclude that the abundance of ChlR1 known to exist in vivo is likely to be a strong deterrent to the stability of triplexes that can potentially form in the human genome.