The circle mode of replication of bacteriophage lambda: the role of covalently closed templates and the formation of mixed catenated dimers

Pathways of DNA unlinking: A story of stepwise simplification

In Escherichia coli DNA replication yields interlinked chromosomes. Controlling topological changes associated with replication and returning the newly replicated chromosomes to an unlinked monomeric state is essential to cell survival. In the absence of the topoisomerase topoIV, the site-specific recombination complex XerCD- dif-FtsK can remove replication links by local reconnection. We previously showed mathematically that there is a unique minimal pathway of unlinking replication links by reconnection while stepwise reducing the topological complexity. However, the possibility that reconnection preserves or increases topological complexity is biologically plausible. In this case, are there other unlinking pathways? Which is the most probable? We consider these questions in an analytical and numerical study of minimal unlinking pathways. We use a Markov Chain Monte Carlo algorithm with Multiple Markov Chain sampling to model local reconnection on 491 different substrate topologies, 166 knots and 325 links, and distinguish between pathways connecting a total of 881 different topologies. We conclude that the minimal pathway of unlinking replication links that was found under more stringent assumptions is the most probable. We also present exact results on unlinking a 6-crossing replication link. These results point to a general process of topology simplification by local reconnection, with applications going beyond DNA.

Finding, Conducting, and Nurturing Science: A Virologist's Memoir

My laboratory investigations have been driven by an abiding interest in understanding the consequences of genetic rearrangement in evolution and disease, and in using viruses to elucidate fundamental mechanisms in biology. Starting with bacteriophages and moving to the retroviruses, my use of the tools of genetics, molecular biology, biochemistry, and biophysics has spanned more than half a century-from the time when DNA structure was just discovered to the present day of big data and epigenetics. Both riding and contributing to the successive waves of technology, my laboratory has elucidated fundamental mechanisms in DNA replication, repair, and recombination. We have made substantial contributions in the area of retroviral oncogenesis, delineated mechanisms that control retroviral gene expression, and elucidated critical details of the structure and function of the retroviral enzymes-reverse transcriptase, protease, and integrase-and have had the satisfaction of knowing that the fundamental knowledge gained from these studies contributed important groundwork for the eventual development of antiviral drugs to treat AIDS. While pursuing laboratory research as a principal investigator, I have also been a science administrator-moving from laboratory head to department chair and, finally, to institute director. In addition, I have undertaken a number of community service, science-related "extracurricular" activities during this time. Filling all of these roles, while being a wife and mother, has required family love and support, creative management, and, above all, personal flexibility-with not too much long-term planning. I hope that this description of my journey, with various roles, obstacles, and successes, will be both interesting and informative, especially to young female scientists.

Properties of the novel herpes simplex virus type 1 origin binding protein, OBPC

We have recently identified a novel 53-kDa herpes simplex virus type 1 (HSV-1) protein encoded by, and in frame with, the 3' half of the UL9 open reading frame, designated OBPC (K. Baradaran, C. Dabrowski and P. A. Schaffer, J. Virol. 68:4251-4261, 1994). Here we show that OBPC is a nuclear protein synthesized at both early and late times postinfection. In gel-shift assays in vitro-synthesized OBPC bound to oriS site I DNA to form a complex identical in mobility to complex A, generated with infected cell extracts and site I DNA. OBPC inhibited both plaque formation and viral DNA replication in transient assays, consistent with its ability to bind to site I DNA and its limited ability to interact with other essential DNA replication proteins. These properties suggest that OBPC may play a role in the initiation, elongation, or packaging of viral DNA.

Electron microscopic identification of supercoiled regions in complex DNA structures

When intracellular lambda replicative intermediates (theta structures) are intercalated with psoralen and then irradiated with long wavelength ultraviolet light (u.v.), interstrand crosslinks are produced. After purification and denaturation of these theta structures, a global difference in denaturation can be observed by electron microscopy; parental sections are essentially native whereas daughter segments are highly denatured. This difference can be explained if parental sections are covalently continuous (and therefore able to supercoil) and daughter segments are not. Due to the higher thermal stability of supercoiled DNA, parental DNA will remain native while daughter sections will denature. Because these structures are crosslinked, the thermal treatment does not lead to dissociation of the highly denatured daughter strands. Experiments with simple negatively supercoiled plasmid circles support the above conclusions. When circles are crosslinked with psoralen-u.v. and then denatured, they remain native because of the higher thermal stability of covalently closed structures. If the circles are linearized before heating but after the psoralen-u.v. treatment, the thermal stability effect is eliminated and the molecules become highly denatured. In this case, however, the crosslinking density is found to be higher than in samples linearized before psoralen-u.v. treatment. This, therefore, shows that crosslinking density also reflects the superhelical state of the molecule at the time of psoralen-u.v. treatment. Two different properties can be used to discriminate between supercoiled and covalently discontinuous domains in complex DNA structures. First, supercoiled regions remain native while covalently discontinuous segments denature following a thermal treatment. This effect requires that covalent continuity exists up to and during the heating treatment. Second, because negative superhelicity enhances psoralen intercalation, crosslinking density is higher in these regions. Even if supercoiled domains are destroyed after the psoralen-u.v. treatment, the imprint of superhelicity is retained and can be recognized as a higher than normal crosslinking density.

Biochemical topology: applications to DNA recombination and replication

Processes of DNA rearrangement such as recombination or replication frequently have as products different subsets of the limitless number of distinguishable catenanes or knots. The use of gel electrophoresis and electron microscopy for analysis of these topological isomers has made it possible to deduce physical and geometric features of DNA structure and reaction mechanisms that are otherwise experimentally inaccessible. Quantitative as well as qualitative characterization is possible for any pathway in which the fate of a circular DNA can be followed. The history, theory, and techniques are reviewed and illustrative examples from recent studies are presented.

DNA supercoiling in gyrase mutants

Nucleoids isolated from Escherichia coli strains carrying temperature-sensitive gyrA or gyrB mutations were examined by sedimentation in ethidium bromide-containing sucrose density gradients. A shift to restrictive temperature resulted in nucleoid DNA relaxation in all of the mutant strains. Three of these mutants exhibited reversible nucleoid relaxation: when cultures incubated at restrictive temperature were cooled to 0 degree C over a 4- to 5-min period, supercoiling returned to levels observed with cells grown at permissive temperature. Incubation of these three mutants at restrictive temperature also caused nucleoid sedimentation rates to increase by about 50%.

Bacterial chromosome segregation: evidence for DNA gyrase involvement in decatenation

Nucleoids isolated from a temperature-sensitive gyrB mutant of E. coli, incubated at restrictive temperatures, exhibit increased sedimentation rates and an abnormal doublet or dumbbell-shaped morphology. Shifting cells from restrictive to permissive temperature prior to nucleoid isolation leads to decreases in the percentage of doublet nucleoids and in nucleoid sedimentation rates. When nucleoids isolated from mutant cells exposed to restrictive temperature are incubated with purified gyrase, the percentage of doublet nucleoids decreases as the total number of nucleoids increases. These results, together with the demonstrated ability of gyrase to decatenate small circular DNA molecules in vitro, suggest that gyrase participates in bacterial chromosome segregation through its decatenating activity.

Studies on the replication of Escherichia coli phage lambda DNA. I. The kinetics of DNA replication and requirements for the generation of rolling circles

Escherichia coli phage lambda DNA has been isolated from infected bacteria using a new technique by which virtually all phage DNA is recovered. Isolated DNA is examined by electron microscopy. Addition of phi X174 RF1 molecules as a counting standard enables us to determine the average number of lambda DNA molecules present in an infected cell. In this study, we have followed the kinetics of lambda DNA replication and examined rolling circle replication. The most important findings are the following: (1) Rolling circle replication is initiated at roughly the same time as is theta replication, indicating that the rolling circle is not solely a late-replicating form. (2) theta replication stops at about 16 min after infection. (3) Early in infection the number of DNA molecules per cell doubles every 2-3 min until theta replication stops, at which point most DNA synthesis consists of growth of the tails of about three rolling circles per cell. (4) Neither the timing of rolling circle replication nor the number of molecules is affected by the activity of the lambda red genes. (5). The red genes are responsible for the production of oligomeric circles late in infection.

Initiation of bacteriophage lambda DNA replication in vitro with purified lambda replication proteins

We have developed a soluble enzyme system that replicates exogenously added plasmid DNA (lambda dv) bearing the replication origin of the bacteriophage lambda chromosome. The system contains pure phage lambda O and P replication proteins and a partially purified mixture of Escherichia coli replication proteins [the enzyme system of Fuller, R.S., Kaguni, J.M. & Kornberg, A. (1981) Proc. Natl. Acad. Sci. USA 78, 7370-7374). The features of lambda dv replication in this system closely resemble the known characteristics of phage lambda DNA replication in vivo. The system (i) depends completely on exogenously supplied DNA, (ii) specifically replicates supercoiled plasmid DNA that contains a lambda replication origin, (iii) depends on both the lambda O protein and the lambda P protein, (iv) depends on RNA polymerase, (v) depends on host replication proteins (e.g., primase, dnaB protein, and several others that function in the priming of DNA synthesis in E. coli) as judged by antibody inhibitions, and (vi) replicates as much as 32% of added lambda dv plasmid DNA through a single complete round to generate catenated daughter molecules. Furthermore, replication of lambda dv DNA in vitro requires DNA gyrase and an ATP-regenerating system. It is notable that addition of lambda O and P proteins to the mixture of E. coli replication proteins inhibits replication of plasmids bearing the origin of the E. coli chromosome. Exploitation of this enzyme system should allow a detailed investigation of the biochemical mechanisms involved in bacteriophage lambda DNA replication and its regulation.

Viral DNA synthesized in vitro by avian retrovirus particles permeabilized with melittin. II. Evidence for a strand displacement mechanism in plus-strand synthesis

Analyses of the native DNA product of mellitin-activated avian retrovirus reverse transcription have revealed a unique structure. The vast majority of the molecules were linear, either 7.7 (genome) or 8.0 (extended genome) kilobases in length, and contained single-stranded DNA branches distributed throughout. These conclusions are based on electrophoretic properties of intact and restriction endonuclease-treated molecules before and after treatment with single-strand-specific nuclease S1. Preliminary data from linear viral DNA extracted from infected cells suggest that these molecules have a similar structure. The findings summarized in this report and those in the preceding paper indicated that the single-stranded branches are of positive polarity and are generated by a strand displacement mechanism. The existence of these branches suggests a role for strand displacement in replication and recombination.

Formation and resolution of DNA catenanes by DNA gyrase

We have discovered that DNA gyrase interlocks duplex DNA circles to form catenanes and resolves catenanes into component monomers. The reactions were inhibited by novobiocin and oxolinic acid and required ATP, Mg++ and spermidine. DNA sequence homology is not involved in catenation, since hybrid catenanes were formed efficiently between supercoiled phi X174 and Col E1 DNA. Strikingly different results were obtained with native and relaxed Col E1 DNA substrates. Up to 50-60% of input native DNA was converted into oligomeric catenanes, predominantly dimers and trimers. Relaxed substrates were instead converted into vast interlocked networks and were occasionally knotted. Optimal catenation occurred only in the narrow range of 20-35 mM KCl; increased ionic strength blocked catenation completely but activated the back reaction of decatenation. Gyrase resolved both the oligomeric catenanes and interlocked networks it produced, as well as naturally occurring catenanes. These results imply that the mechanism of gyrase involves a transient double-strand break and passage of a DNA segment through the resulting gap. Gyrase is representative of a general class of enzymes, found in both procaryotic and eucaryotic cells, that facilitate diffusion of duplex DNA segments through each other and may thereby solve topological problems arising from the replication, recombination and condensation of DNA.

Isolation and characterization of recombinant DNA clones of avian retroviruses: size heterogeneity and instability of the direct repeat

Unintegrated proviral DNA of Schmidt-Ruppin B Rous sarcoma virus was cloned in the bacteriophage lambda vector Charon 21A. A total of 12 independent recombinant lambda SRBtd clones which were derived from the transformation-defective component in the viral preparation were analyzed with restriction endonucleases and molecular hybridization techniques. Three classes of clones were observed. Type I clones contained a 5.0-megadalton insert of viral DNA, type II clones contained phage with two size classes of inserts (5.0 and 5.2 megadaltons), and one type III clone contained only a 5.2-megadalton insert. The smaller insert present in type II clones appeared to be derived by deletion of one copy of a directly repeated sequence which was present in the larger insert. Mapping data indicated that the deletion includes all or part of the terminal repeat found in linear double-stranded proviral DNA. Similar results were obtained from lambda RAV2 recombinant clones derived from Rous-associated virus type 2. Analysis of DNA from type II and type III clones of lambda SRBtd and lambda RAV2 revealed limited heterogeneity in the size of the direct repeat.

Two species of full-length cDNA are synthesized in high yield by melittin-treated avian retrovirus particles

A method of activating endogenous cDNA synthesis in avian retroviruses that results in the formation of two species of full-length cDNA in high yield is described. Tests of biological activity show infectivity of at least the same order of magnitude as for full-length cDNA made by other procedures. Melittin, the major component of bee venom, is used as an alternative to nonionic detergents to make the viral envelope permeable and thus activate the endogenous RNA-dependent DNA polymerase. This compound is a toxic peptide known to interact with phospholipid membranes. It appears to be less disruptive to the viral structure than detergents, resulting in a more efficient transcription of the viral genome. Preliminary tests indicate that this method will also prove useful for studying enzymatic activities associated with other enveloped viruses.

Bacteriophages of Streptococcus pneumoniae. Physicochemical properties of bacteriophage Dp-4 and its transfecting DNA

The properties of Dp-4 phage and its DNA have been studied. The phage has a polyhedral head of 60 nm diameter, a tail 155 nm long and a buoyant density in CsCl of 1.48 g/cm3. Analysis by acrylamide gel electrophoresis indicates the presence of five polypeptides. Dp-4 DNA has a molecular weight of 37 x 10(6), a melting point of 83.5 degrees C (when dissolved in 0.15 M NaCl/0.015 M sodium citrate, pH 7.0) and a G + C content of about 33%. Denaturation of DNA yields two strands of different buoyant density in a neutral CsCl gradient. The interaction of poly(U, G) with the heavy strand strongly enhances its density and allows the preparative separation of both strands. Native Dp-4 DNA has unusual physical properties: abnormally low buoyant densities both in CsCl (1.666 g/cm3) and in Cs2SO4 (1.410 g/cm3) (which do not correspond to the value predictable from the G + C content of the DNA), and a high thermal stability at low ionic strength.

DNA sequences and structural homologies of the replication origins of lambdoid bacteriophages

The DNA sequences for the origins of replication of the lambdoid bacteriophages phi80, 434, phi21, and lambdaimm21 (identical to phi21) have been determined and compared to the lambda structure. Two presumptive elaborate binding sites for two initiator proteins have been identified in their outer sections, while a replicational primer start site seems to be located in their centres.

Roles of bacteriophage lambda gene products O and P during early and late phases of infection cycle

Ring-to-ring (early) replication of bacteriophage lambda DNA was blocked after heat inactivation of the P protein. Rolling circle (late) replication continued for several rounds at the rate reached when the temperature shift was carried out. The same differential effect was observed after inhibition of RNA or protein synthesis during the two different phases of replication. In contrast, inactivation of the O protein resulted in a fast stop of lambda DNA synthesis at early and late times after infection. The results were consistent with the following interpretations. (i) The lambda P gene product plays a role in the initiation of the ring-to-ring replication. (ii) Ring-to-ring replication continues parallel to rolling circle replication, possibly diminishing with time after infection. (iii) The O function is stable in and necessary for the structural integrity of an elongation complex. It is unstable in free form and probably released from such a replication complex after each round of replication at the ring-to-ring stage.

Initiation of lambda DNA replication in vitro promoted by isolated P-gene product

The product of the P gene of bacteriophage lambda was isolated from heat-induced lambda-lysogenic Escherichia coli cells. It was found to bind to DNA, to be devoid of nuclease activity acting on double-stranded lambda DNA and of nicking/closing activity. Initiation of lambda DNA replication promoted by the P-gene product in a complementation assay in vitro was sensitive to rifampicin. Sedimentation analysis of the products and their hybridization to separated lambda DNA strands indicate that lambda DNA was formed in a reaction similar to ring-to-ring replication in vivo. The reaction was symmetric from the beginning, i.e. both lambda DNA strands were copied without delay.

Identification of the site of interruption in relaxed circles producing during bacteriophage lambda DNA circle replication

The DNA that accumulates in the lambda infection restricted to the early (circular) stage of replication consists of approximately two-thirds covalently closed circles and one-third relaxed circles bearing a single interruption in either strand of the duplex. The latter molecules are presumed to be a unique class in that the interruption is not repairable by DNA polymerase and ligase. Preferential radioisotopic labeling of the region immediately adjacent to the interruption, followed by hybridization to sheared fragments of the lambda chromosome with varying guanine plus cytosine content, suggested that the nick resides at the position of the mature molecular ends of the lambda chromosome. Digestion of the labeled molecules with restriction enzymes and reconstruction experiments in which Hershey circles were generated by annealing of interrupted strands isolated from the relaxed circles support this interpretation. The results indicate that the relaxed circles consist of a population containing one interruption in either of the two strands of the duplex jointly representing the two "nicks" contained in Hershey circles (in which the cohesive ends are annealed). These molecules could result from the inability of the maturation function to make the required staggered endonucleolytic cuts when the DNA substrate is a monomeric circle rather than a multimeric linear molecule. Alternatively, this interruption could be the result of an endonucleolytic cutting event critical to DNA replication.