Reversible decatenation of kinetoplast DNA by a DNA topoisomerase from trypanosomatids.

DNA topoisomerase activity detected in cell extracts of the trypanosomatid Crithidia fasciculata interlocks kinetoplast DNA duplex minicircles into huge catenane forms resembling the natural kinetoplast DNA networks found in trypanosomes. Catenation of duplex DNA circles is reversible and equilibrium is affected by ionic strength, and by spermidine. The reaction requires magnesium, is ATP dependent and is inhibited by high concentrations of novobiocin. Extensive homology between duplex DNA rings was not required for catenane formation since DNA circles with unrelated sequences could be interlocked into mixed network forms. Covalently sealed catenaned DNA circles are specifically used as substrates for decatenation. No such preference for covalently sealed duplex DNA rings was observed for catenate formation. Its catalytic properties and DNA substrate preference, suggest a potential role for this eukaryotic topoisomerase activity in the replication of kinetoplast DNA.     

Noncomplementarity in base sequences between the cohesive ends of coliphages 186 and lambda and the formation of interlocked rings between the two DNA's

The half molecules of 186 DNA have been isolated by the Hg(II)–Cs₂SO₄ density gradient centrifugal ion technique. The buoyant densities of the two halves in CsCI at 25°C. are 1.713 and 1.709 g./cm.³, corresponding to GC contents of 54% and 50%, respectively. Similarly, 5-bromouracil labeled λ DNA halves were separated. The isolation of the four DNA halves made it possible to test for homology in base sequences between the cohesive ends of λ and those of 186. There was no indication of any significant homology in base sequences between the cohesive ends of the two DNA's, as indicated by the absence of a band with intermediate buoyant density in CsCI when either half of 186 DNA was annealed with either half of 5-bromouracil labeled λ DNA and then centrifuged. The lack of cohesion between the two DNA's made it possible to demonstrate unequivocally the formation of interlocked rings (catenanes) between the two DNA's. The existence of a dimeric catenane is evidenced by the formation of a species of intermediate buoyant density when 5-bromouracil labeled λ DNA is cyclized in the presence of cyclic 186 DNA of a relatively high concentration. The molecular weight of one DNA relative to the other can be calculated from the position of the dimeric catenane in a density gradient by using the method of Baldwin. The result was in complete agreement with our previous measurements from the sedimentation coefficients and by electron microscopy. The probability of dimeric catenane formation when one DNA is cyclized in the presence of another DNA is discussed. The experimental results agree with the theoretical expectation.     

Thermodynamics of a designed protein catenane

Topological linking of proteins is a new approach for stabilizing and controlling the oligomerization state of proteins that fold in an interwined manner. The recent design of a backbone cyclized protein catenane based on the p53tet domain suggested that topological cross-linking provided increased stability against thermal and chemical denaturation. However, the tetrameric structure complicated detailed biophysical analysis of this protein. Here, we describe the design, synthesis and thermodynamic characterization of a protein catenane based on a dimeric mutant of the p53tet domain (M340E/L344K). The formation of the catenane proceeded efficiently, and the overall structure and oligomerization of the domain was not affected by the formation of the topological link. Unfolding and refolding of the catenane was consistent with a two-state process. The topological link stabilized the dimer against thermal and chemical denaturation considerably, raising the apparent melting temperature by 59 degrees C and the midpoint of denaturation by 4.5M GuHCl at a concentration of 50 microM. The formation of the topological link increased the resistance of the dimer to proteolysis. However, the m value decreased by 1.7kcalmol(-1)M(-1), suggesting a decrease in accessible surface area in the unfolded state. This implies that the stabilization from the topological link is largely due to a destabilization of the unfolded state, similar to other cross-links in proteins. Topological linking therefore provides a powerful and orthogonal tool for the stabilization of peptide and protein oligomers.     

Early Intracellular Events in the Replication of Bacteriophage T4 Deoxyribonucleic Acid: V. Further Studies on the T4 Protein-Deoxyribonucleic Acid Complex 1

Soon after infection parental deoxyribonucleic acid (DNA) enters a structure sedimenting fast to the bottom of a sucrose gradient. The addition of chloramphenicol (CM) prevents formation of this structure, whereas treatment with Pronase releases DNA which sediments thereafter with the speed characteristic of phenol-extracted replicative DNA. It is assumed therefore that the structure responsible for fast sedimentation of replicative DNA is a newly synthesized protein. Those fast-sedimenting complexes contain preferentially the replicative form of parental DNA; this was proven by density labeling experiments. Progeny DNA labeled with (3)H-thymidine added after infection can also be detected preferentially in this fast-sedimenting moiety. The association of the DNA with the complexing protein is of a colinear or quasi-colinear type. This was proven by introducing double-strand scissions into DNA embedded in the replicative complex; double-strand scissions do not liberate DNA from the fast-sedimenting complex. Despite the apparent intimate relation between protein and DNA, DNA residing in complexes is fully sensitive to the action of nucleases. Shortly prior to the appearance of the fast-sedimenting complex, parental DNA displays still another characteristic: at about 3 min after infection, it sediments faster than reference, but sizeably slower than the complex which appears at roughly 4 to 5 min after infection. The transition between these two fast-sedimenting types of moieties is not continuous. This fast-sedimenting intermediate, which appears at 3 min after infection, cannot be inhibited by the addition of CM either at the moment or prior to infection. Fast-sedimenting intermediate can be destroyed by sodium dodecyl sulfate, Pronase, or phenol extraction. The progeny DNA labeled with (3)H-thymidine between 3 and 3.5 min after infection can be recovered in fast-sedimenting intermediate. The contribution of newly synthesized progeny DNA is so small that it cannot be detected as a shift of the parental density in a density labeling experiment. Small fragments of progeny DNA recovered in fast-sedimenting intermediate are not covalentlv attached to parental molecules and represent both strands of T4 DNA.     

Geometric arrangements of Tn3 resolvase sites

Site-specific recombination by Tn3 resolvase normally occurs in vitro and in vivo only between directly repeated res sites on the same supercoiled DNA molecule. However, with multiply interlinked catenane substrates consisting of two DNA rings each containing a single res site, resolvase efficiently carried out intermolecular recombination. The topology of the knots produced by several rounds of this reaction proves that the DNA within the synaptic intermediate is coiled in an interwound (plectonemic) fashion rather than wrapped solenoidally around resolvase as in previously characterized supercoiled DNA-protein complexes. The synaptic intermediate can contain equivalently supercoil, catenane, or knot crossings as long as the res sites have a right-handed coiling and a particular relative orientation. The structure of the product knots and catenanes also shows the path the DNA takes during strand exchange. Intermolecular recombination within multiply linked catenanes required negative supercoiling, as does the standard intramolecular reaction.     

Effects of secondary structures in RNA on interlocking probabilities

In 1967 Wang and Schwartz reported on the formation of interlocked rings between linear or circular DNA molecules by the enzyme topoisomerase. We propose viewing the secondary structured loop in RNA (or single stranded DNA) as analogous to a circular DNA molecule. Formation of a catenane between such an RNA loop with a DNA molecule may constitute a probe of the secondary and general three dimensioanl structure of the RNA molecule. The experimental results may be compared with the theoretical calculation. We suggest here a method for estimating linkage probabilities and calculate them for several cases for which secondary structures of the RNA have been proposed.     

Rolling-circle amplification under topological constraints

We have performed rolling-circle amplification (RCA) reactions on three DNA templates that differ distinctly in their topology: an unlinked DNA circle, a linked DNA circle within a pseudorotaxane-type structure and a linked DNA circle within a catenane. In the linked templates, the single-stranded circle (dubbed earring probe) is threaded, with the aid of two peptide nucleic acid openers, between the two strands of double-stranded DNA (dsDNA). We have found that the RCA efficiency of amplification was essentially unaffected when the linked templates were employed. By showing that the DNA catenane remains intact after RCA reactions, we prove that certain DNA polymerases can carry out the replicative synthesis under topological constraints allowing detection of several hundred copies of a dsDNA marker without DNA denaturation. Our finding may have practical implications in the area of DNA diagnostics.     

The capture of a DNA double helix by an ATP-dependent protein clamp: a key step in DNA transport by type II DNA topoisomerases.

The binding of linear and circular forms of DNA to yeast DNA topoisomerase II or its complex with AMPPNP, the nonhydrolyzable beta,gamma-imido analog of ATP, was carried out to probe the ATP analog-induced conformational change of the enzyme. Binding of the ATP analog is shown to convert the enzyme to a circular clamp with an annulet, through which only a linear DNA can pass; subsequent circularization of the bound linear DNA forms a salt-stable catenane between the protein circular clamp and the DNA ring. Analysis of catenane formation between a small DNA ring originally bound to the topoisomerase and a large DNA ring subsequently added, under conditions such that the two do not exchange, supports a model in which a second DNA double-helix can enter the open jaws of a DNA-bound protein clamp, and the closure of the jaws upon ATP-binding traps the second duplex and transports it through an enzyme-operated gate in the first DNA duplex.     

Modification of Escherichia coli DNA ligase by cleavage with trypsin.

Limited treatment of Escherichia coli DNA ligase with trypsin results in rapid loss of DNA joining activity. However, the ability to react with DPN to form the covalent enzyme-AMP intermediate is unaffected. The cleaved enzyme is also unable to catalyze the formation of DNA-adenylate, the second covalent intermediate in the ligase-catalyzed reaction. These findings demonstrate that portions of the DNA ligase molecule that are required for phosphodiester bond formation are not required for at least one of the partial reactions catalyzed by this enzyme.     

Regioselective template synthesis, X-ray structure, and chiroptical properties of a topologically chiral sulfonamide catenane

The synthesis of a topologically chiral in,out-bis-sulfonamide catenane and its "dimer" are reported. The structures of the amide wheel and of the catenane were resolved by X-ray analysis. NMR-titration of the monosulfonamide-wheel yielded conclusive association constants supporting the proposed regioselective mechanism of the catenane formation. The enantioseparation of the catenane via chiral HPLC was successful. The enantiomers show pronounced Cotton effects in the aromatic region of the CD-spectrum. Since the template synthesis was carried out leading to the in-oriented sulfonamide-wheel blocked with an N-methyl group at its reactive sulfonamide functionality, the catenane represents the first monofunctional topologically chiral amide-based catenane. Reaction with 1,2-bis(2-iodoethoxy)ethane led to a bis-catenane containing two topological units. The meso- and the RR/SS-isomers represent a new type of topological diastereomers.     

Analysis of the structure of dimeric DNA catenanes by electron microscopy.

We analyzed the structure of open-circular and supercoiled dimeric DNA catenanes generated by site-specific recombination in vitro. Electron microscopy of open-circular catenanes shows that the number of duplex crossings in a plane is a linear function of the number of catenane interlinks (Ca/2), and that the length of the catenane axis is constant, independent of Ca. These relationships are similar to those observed with supercoiled DNA. Statistical analyses reveal, however, that the conformations of the individual rings of the catenanes are similar to those of unlinked circles. The distribution of distances between randomly chosen points on separate rings depends strongly on Ca and is consistent with a sharp decrease in the center-of-mass separation between rings with increasing Ca. Singly linked supercoiled catenanes are seen by microscopy to be linked predominantly through terminal loops in the respective superhelices. The observations suggest that chain entropy is a major factor determining the conformation of DNA catenanes.     

Formaldehyde-activated WEHI-150 induces DNA interstrand crosslinks with unique structural features

Mitoxantrone is an anticancer anthracenedione that can be activated by formaldehyde to generate covalent drug-DNA adducts. Despite their covalent nature, these DNA lesions are relatively labile. It was recently established that analogues of mitoxantrone featuring extended side-chains terminating in primary amino groups typically yielded high levels of stable DNA adducts following their activation by formaldehyde. In this study we describe the DNA sequence-specific binding properties of the mitoxantrone analogue WEHI-150 which is the first anthracenedione to form apparent DNA crosslinks mediated by formaldehyde. The utility of this compound lies in the versatility of the covalent binding modes displayed. Unlike other anthracenediones described to date, WEHI-150 can mediate covalent adducts that are independent of interactions with the N-2 of guanine and is capable of adduct formation at novel DNA sequences. Moreover, these covalent adducts incorporate more than one formaldehyde-mediated bond with DNA, thus facilitating the formation of highly lethal DNA crosslinks. The versatility of binding observed is anticipated to allow the next generation of anthracenediones to interact with a broader spectrum of nucleic acid species than previously demonstrated by the parent compounds, thus allowing for more diverse biological activities.     

Heat shock does not induce gammaH2AX foci formation but protects cells from N-methyl-N'-nitro-N-nitrosoguanidine-induced genotoxicity

The involvement of DNA damage in heat shock-induced cell death remains controversial. To investigate whether heat shock can induce DNA damage, we tested the induction of gammaH2AX foci formation, a sensitive indicator for DNA double strand breaks (DSBs), by heat shock treatment in several cell lines including HeLa, CHL, HepG2, and 293 cells, as well as human spermatozoa. Although heat shock treatment can decrease cell viability, no induction of gammaH2AX foci formation was observed in any of these cells. In addition, a p53-deficient cell line (U2OSE6tet24) and a flap endonuclease 1 (FEN1)-deficient cell line (FL-FEN1(-)) also did not show induction of gammaH2AX foci after heat shock treatment. Finally, it was found that 30min of pre-heat shock can inhibit gammaH2AX foci formation induced by an alkylating agent, N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), which is known to induce gammaH2AX foci formation. On the other hand, heat shock after MNNG treatment did not affect the gammaH2AX foci formation induced by MNNG. Taken together, these data suggest that although heat shock might influence the gammaH2AX foci formation process, it does not induce DNA damage in the cells tested in this study.     

Construction of DNA Hemicatenanes from Two Small Circular DNA Molecules

DNA hemicatenanes, one of the simplest possible junctions between two double stranded DNA molecules, have frequently been mentioned in the literature for their possible function in DNA replication, recombination, repair, and organization in chromosomes. They have been little studied experimentally, however, due to the lack of an appropriate method for their preparation. Here we have designed a method to build hemicatenanes from two small circular DNA molecules. The method involves, first, the assembly of two linear single strands and their circularization to form a catenane of two single stranded circles, and, second, the addition and base-pairing of the two single stranded circles complementary to the first ones, followed by their annealing using DNA topoisomerase I. The product was purified by gel electrophoresis and characterized. The arrangement of strands was as expected for a hemicatenane and clearly distinct from a full catenane. In addition, each circle was unwound by an average of half a double helical turn, also in excellent agreement with the structure of a hemicatenane. It was also observed that hemicatenanes are quickly destabilized by a single cut on either of the two strands passing inside the junction, strongly suggesting that DNA strands are able to slide easily inside the hemicatenane. This method should make it possible to study the biochemical properties of hemicatenanes and to test some of the hypotheses that have been proposed about their function, including a possible role for this structure in the organization of complex genomes in loops and chromosomal domains.     

Heat-stable and heat-labile thymidylate synthases B of Bacillus subtilis: comparison of the nucleotide and amino acid sequences

Heat treatment of wild-type Escherichia coli cells led to a transient relaxation of negatively supercoiled plasmid DNA and there was no recovery of DNA torsional strain in the DNA in gyrA mutant cells. After heat treatment, DnaK and GroEL proteins were synthesized continuously in the gyrA mutant cells, whereas they were synthesized only transiently in wild-type cells. Thus, change in superhelical density of the DNA correlated with the temperature-induced expression of heat shock proteins. Inhibitors of DNA gyrase (nalidixic acid, novobiocin), an organic solvent (ethanol) and a psychotropic drug (chlorpromazine) all stimulated relaxation of cellular DNA over the same concentration range that induces heat shock proteins. As DNA relaxation was induced by heat treatment or chemicals in an rpoH mutant, the process is not the result of induced synthesis of heat shock proteins.     

Adenosine diphosphate ribosyltransferase and protein acceptors associated with cytoplasmic free messenger ribonucleoprotein particles

ADP-ribosyltransferase activity has been characterized in free messenger ribonucleoprotein particles (mRNP) from mouse plasmacytoma cells. This enzymatic activity appears to be associated with the free mRNP and not due to nuclear contamination. The enzyme activity is not stimulated by added DNA or histone H1 and represents 34 per cent of the total cellular ADP-ribosyltransferase activity while the DNA contamination in free mRNP is less than 4 per cent of the total cellular DNA. Moreover, the ADP-ribosyltransferase specific activity per mg of DNA is about 75-fold higher in free mRNP than in the nuclei. During CsCl gradient centrifugation of the cytoplasmic fraction, the ADP-ribosylated material separates out at a buoyant density similar to that of free mRNP.This ADP-ribosyltransferase activity is inhibited by thymidine, nicotinamide and 3-aminobenzamide, while it is highly stimulated by exogenous pancreatic RNase. The in vitro synthesized acid insoluble material is rendered partly soluble by treatment by a proteolytic enzyme or by snake venom phosphodiesterase resulting in phosphoribosyl-AMP formation: the pancreatic RNase does not solubilize this material. Several ADP-ribosylated proteins are detected by lithium dodecylsulfate gel electrophoresis.Such an ADP-ribosyltransferase activity has also been detected in free mRNP from rat liver. It is suggested that this ADP-ribosylation of specific free mRNP proteins may be associated with free mRNP structure and/or with some chemical covalent type of modification rendering mRNA available for translation.     

Structure of avian tumor virus DNA intermediates.

The mechanism of conversion of virion RNA to doublestranded DNA, in avian sarcoma virus-infected duck cells, has been investigated. The evidence presented here indicates a covalent linkage between the genomic RNA and the newly synthesized is primed by the 35S virion RNA. Some data identifying the virus specific hybrid and linear double-stranded DNA molecules, which are probably intermediates, leading to the formation of supercoiled duplex viral DNA, has also been presented.