Communication between segments of DNA during site-specific recombination

Effect of NaeI-L43K mutation on protein dynamics and DNA conformation: Insights from molecular dynamics simulations

Protein-DNA interactions are an important class of biomolecular interactions inside the cell. Delineating the mechanisms of protein-DNA interactions and more specifically, how proteins search and bind to their specific cognate sequences has been the quest of many in the scientific community. Restriction enzymes have served as useful model systems to this end. In this work, we have investigated using molecular dynamics simulations the effect of L43K mutation on NaeI, a type IIE restriction enzyme. NaeI has two domains, the Topo and the Endo domains, each binding to identical strands of DNA sequences (GCCGGC)₂. The binding of the DNA to the Topo domain is thought to enhance the binding and cleavage of DNA at the Endo domain. Interestingly, it has been found that the mutation of an amino acid that is distantly-located from the DNA cleavage site (L43K) converts the restriction endonuclease to a topoisomerase. Our investigations reveal that the L43K mutation not only induces local structural changes (as evidenced by changes in hydrogen bond propensities and differences in the percentage of secondary structure assignments of the residues in the ligase-like domain) but also alters the overall protein dynamics and DNA conformation which probably leads to the loss of specific cleavage of the recognition site. In a larger context, our study underscores the importance of considering the role of distantly-located amino acids in understanding protein-DNA interactions.

Towards effective non-viral gene delivery vector

Despite very good safety records, clinical trials using plasmid DNA failed due to low transfection efficiency and brief transgene expression. Although this failure is both due to poor plasmid design and to inefficient delivery methods, here we will focus on the former. The DNA elements like CpG motifs, selection markers, origins of replication, cryptic eukaryotic signals or nuclease-susceptible regions and inverted repeats showed detrimental effects on plasmids' performance as biopharmaceuticals. On the other hand, careful selection of promoter, polyadenylation signal, codon optimization and/or insertion of introns or nuclear-targeting sequences for therapeutic protein expression can enhance the clinical efficacy. Minimal vectors, which are devoid of the bacterial backbone and consist exclusively of the eukaryotic expression cassette, demonstrate better performance in terms of expression levels, bioavailability, transfection rates and increased therapeutic effects. Although the results are promising, minimal vectors have not taken over the conventional plasmids in clinical trials due to challenging manufacturing issues.

Comparative Genomics of DNA Recombination and Repair in Cyanobacteria: Biotechnological Implications

Cyanobacteria are fascinating photosynthetic prokaryotes that are regarded as the ancestors of the plant chloroplast; the purveyors of oxygen and biomass for the food chain; and promising cell factories for an environmentally friendly production of chemicals. In colonizing most waters and soils of our planet, cyanobacteria are inevitably challenged by environmental stresses that generate DNA damages. Furthermore, many strains engineered for biotechnological purposes can use DNA recombination to stop synthesizing the biotechnological product. Hence, it is important to study DNA recombination and repair in cyanobacteria for both basic and applied research. This review reports what is known in a few widely studied model cyanobacteria and what can be inferred by mining the sequenced genomes of morphologically and physiologically diverse strains. We show that cyanobacteria possess many E. coli-like DNA recombination and repair genes, and possibly other genes not yet identified. E. coli-homolog genes are unevenly distributed in cyanobacteria, in agreement with their wide genome diversity. Many genes are extremely well conserved in cyanobacteria (mutMS, radA, recA, recFO, recG, recN, ruvABC, ssb, and uvrABCD), even in small genomes, suggesting that they encode the core DNA repair process. In addition to these core genes, the marine Prochlorococcus and Synechococcus strains harbor recBCD (DNA recombination), umuCD (mutational DNA replication), as well as the key SOS genes lexA (regulation of the SOS system) and sulA (postponing of cell division until completion of DNA reparation). Hence, these strains could possess an E. coli-type SOS system. In contrast, several cyanobacteria endowed with larger genomes lack typical SOS genes. For examples, the two studied Gloeobacter strains lack alkB, lexA, and sulA; and Synechococcus PCC7942 has neither lexA nor recCD. Furthermore, the Synechocystis PCC6803 lexA product does not regulate DNA repair genes. Collectively, these findings indicate that not all cyanobacteria have an E. coli-type SOS system. Also interestingly, several cyanobacteria possess multiple copies of E. coli-like DNA repair genes, such as Acaryochloris marina MBIC11017 (2 alkB, 3 ogt, 7 recA, 3 recD, 2 ssb, 3 umuC, 4 umuD, and 8 xerC), Cyanothece ATCC51142 (2 lexA and 4 ruvC), and Nostoc PCC7120 (2 ssb and 3 xerC).

Optical Pushing: A Tool for Parallelized Biomolecule Manipulation

The ability to measure and manipulate single molecules has greatly advanced the field of biophysics. Yet, the addition of more single-molecule tools that enable one to measure in a parallel fashion is important to diversify the questions that can be addressed. Here we present optical pushing (OP), a single-molecule technique that is used to exert forces on many individual biomolecules tethered to microspheres using a single collimated laser beam. Forces ranging from a few femtoNewtons to several picoNewtons can be applied with a submillisecond response time. To determine forces exerted on the tethered particles by the laser, we analyzed their measured Brownian motion using, to our knowledge, a newly derived analytical model and numerical simulations. In the model, Brownian rotation of the microspheres is taken into account, which proved to be a critical component to correctly determine the applied forces. We used our OP technique to map the energy landscape of the protein-induced looping dynamics of DNA. OP can be used to apply loading rates in the range of 10(-4)-10(6) pN/s to many molecules at the same time, which makes it a tool suitable for dynamic force spectroscopy.

Functional analysis of three topoisomerases that regulate DNA supercoiling levels in Chlamydia

Chlamydia is a medically important bacterium that infects eukaryotic cells. Temporal expression of chlamydial genes during the intracellular infection is proposed to be regulated by changes in DNA supercoiling levels. To understand how chlamydial supercoiling levels are regulated, we purified and analyzed three putative Chlamydia trachomatis topoisomerases. As predicted by sequence homology, CT189/190 are the two subunits of DNA gyrase, whereas CT643 is a topoisomerase I. CT660/661 have been predicted to form a second DNA gyrase, but the reconstitute holoenzyme decatenated and relaxed DNA, indicating that the proteins are subunits of topoisomerase IV. Promoter analysis showed that each topoisomerase is transcribed from its own operon by the major chlamydial RNA polymerase. Surprisingly, all three topoisomerase promoters had higher activity from a more supercoiled DNA template. This supercoiling-responsivesness is consistent with negative feedback control of topoisomerase I and topoisomerase IV expression, which is typical of other bacteria. However, activation of the chlamydial gyrase promoter by increased supercoiling is unorthodox compared with the relaxation-induced transcription of gyrase in other bacteria. We present a model in which supercoiling levels during the intracellular chlamydial developmental cycle are regulated by unusual positive feedback control of the gyrase promoter and the temporal expression of three topoisomerases.

Exogenous enzymes upgrade transgenesis and genetic engineering of farm animals

Transgenic farm animals are attractive alternative mammalian models to rodents for the study of developmental, genetic, reproductive and disease-related biological questions, as well for the production of recombinant proteins, or the assessment of xenotransplants for human patients. Until recently, the ability to generate transgenic farm animals relied on methods of passive transgenesis. In recent years, significant improvements have been made to introduce and apply active techniques of transgenesis and genetic engineering in these species. These new approaches dramatically enhance the ease and speed with which livestock species can be genetically modified, and allow to performing precise genetic modifications. This paper provides a synopsis of enzyme-mediated genetic engineering in livestock species covering the early attempts employing naturally occurring DNA-modifying proteins to recent approaches working with tailored enzymatic systems.

Folded DNA in action: hairpin formation and biological functions in prokaryotes

Structured forms of DNA with intrastrand pairing are generated in several cellular processes and are involved in biological functions. These structures may arise on single-stranded DNA (ssDNA) produced during replication, bacterial conjugation, natural transformation, or viral infections. Furthermore, negatively supercoiled DNA can extrude inverted repeats as hairpins in structures called cruciforms. Whether they are on ssDNA or as cruciforms, hairpins can modify the access of proteins to DNA, and in some cases, they can be directly recognized by proteins. Folded DNAs have been found to play an important role in replication, transcription regulation, and recognition of the origins of transfer in conjugative elements. More recently, they were shown to be used as recombination sites. Many of these functions are found on mobile genetic elements likely to be single stranded, including viruses, plasmids, transposons, and integrons, thus giving some clues as to the manner in which they might have evolved. We review here, with special focus on prokaryotes, the functions in which DNA secondary structures play a role and the cellular processes giving rise to them. Finally, we attempt to shed light on the selective pressures leading to the acquisition of functions for DNA secondary structures.

Dissecting protein-induced DNA looping dynamics in real time

Many proteins that interact with DNA perform or enhance their specific functions by binding simultaneously to multiple target sites, thereby inducing a loop in the DNA. The dynamics and energies involved in this loop formation influence the reaction mechanism. Tethered particle motion has proven a powerful technique to study in real time protein-induced DNA looping dynamics while minimally perturbing the DNA-protein interactions. In addition, it permits many single-molecule experiments to be performed in parallel. Using as a model system the tetrameric Type II restriction enzyme SfiI, that binds two copies of its recognition site, we show here that we can determine the DNA-protein association and dissociation steps as well as the actual process of protein-induced loop capture and release on a single DNA molecule. The result of these experiments is a quantitative reaction scheme for DNA looping by SfiI that is rigorously compared to detailed biochemical studies of SfiI looping dynamics. We also present novel methods for data analysis and compare and discuss these with existing methods. The general applicability of the introduced techniques will further enhance tethered particle motion as a tool to follow DNA-protein dynamics in real time.

Enhancer-independent Mu transposition from two topologically distinct synapses

Transposition of Mu is strictly dependent on a specific orientation of the left (L) and right (R) ends of Mu and a distant enhancer site (E) located on supercoiled DNA. Five DNA crossings are trapped in the three-site synapse, two of which are contributed by the interwrapping of L and R. To determine the contribution of E to the interwrapping of Mu ends, we examined the topology of the LR synapse under two different enhancer-independent reaction conditions. One of these conditions, which also alleviates the requirement for a specific orientation of Mu ends, revealed two topologically distinct arrangements of the ends. In their normal relative orientation, L and R were either plectonemically interwrapped or aligned by random collision. Addition of the enhancer to this system channeled synapsis toward the interwrapped pathway. When the ends were in the wrong relative orientation, synapsis occurred exclusively by random collision. In the second enhancer-independent condition, which retains the requirement for a specific orientation of Mu ends, synapsis of L and R was entirely by interwrapping. The two distinct kinds of synapses also were identified by gel electrophoresis. We discuss these results in the context of the "topological filter" model and consider the many contributions the enhancer makes to the biologically relevant interwrapped synapse.

Real-time observation of DNA looping dynamics of Type IIE restriction enzymes NaeI and NarI

Many restriction enzymes require binding of two copies of a recognition sequence for DNA cleavage, thereby introducing a loop in the DNA. We investigated looping dynamics of Type IIE restriction enzymes NaeI and NarI by tracking the Brownian motion of single tethered DNA molecules. DNA containing two endonuclease recognition sites spaced a few 100 bp apart connect small polystyrene beads to a glass surface. The position of a bead is tracked through video microscopy. Protein-mediated looping and unlooping is then observed as a sudden specific change in Brownian motion of the bead. With this method we are able to directly follow DNA looping kinetics of single protein–DNA complexes to obtain loop stability and loop formation times. We show that, in the absence of divalent cations, NaeI induces DNA loops of specific size. In contrast, under these conditions NarI mainly creates non-specific loops, resulting in effective DNA compaction for higher enzyme concentrations. Addition of Ca²⁺ increases the NaeI-DNA loop lifetime by two orders of magnitude and stimulates specific binding by NarI. Finally, for both enzymes we observe exponentially distributed loop formation times, indicating that looping is dominated by (re)binding the second recognition site.

Influence of global DNA topology on cruciform formation in supercoiled DNA

DNA supercoiling plays an important role in many genetic processes such as replication, transcription, and recombination. Supercoiling provides energy for helix un-pairing and drives the formation of alternative DNA structural transitions, like cruciforms. Supercoiling also allows distant DNA regions to be brought into close proximity through the formation of inter-wound supercoils. Recently, we showed that the inverted repeat-to-cruciform transition acts as a molecular switch, influencing the global topology of a topological plasmid domain. As alternative DNA structures can affect global topology, a corollary hypothesis might be that the localization of a specific DNA sequence within a topological domain may affect the energetics required for formation of an alternative DNA structure. Here, we test this hypothesis and show that the localization of an inverted repeat to an apical position increases the rate of cruciform formation and reduces the superhelical energy required to drive the transition. For this, we created a series of plasmids containing an inverted repeat and an A-tract bent DNA sequence. The A-tract forms a permanent 180 degrees bend irrespective of DNA topology. The inverted repeat and the bent sequence were placed either at six o'clock or nine o'clock positions with respect to each other. Using 2D agarose gel electrophoresis, we show that the six o'clock construct extrudes the cruciform at a lower superhelical density than a control plasmid without the bend. Atomic force microscopy shows that the nine o'clock construct has the propensity to form branched molecules with the cruciform at the end of one branch. These results demonstrate that the localization of sequences within specific regions of a topological domain can affect the energetics of structural transitions as well as the branching structure of the domain. As structural transitions can be involved in biological processes, localization of alternative conformation-forming sequences to specific locations within a domain provides an additional means for gene regulation.

DNA supercoiling enables the type IIS restriction enzyme BspMI to recognise the relative orientation of two DNA sequences

Many proteins can sense the relative orientations of two sequences at distant locations in DNA: some require sites in inverted (head-to-head) orientation, others in repeat (head-to-tail) orientation. Like many restriction enzymes, the BspMI endonuclease binds two copies of its target site before cleaving DNA. Its target is an asymmetric sequence so two sites in repeat orientation differ from sites in inverted orientation. When tested against supercoiled plasmids with two sites 700 bp apart in either repeated or inverted orientations, BspMI had a higher affinity for the plasmid with repeated sites than the plasmid with inverted sites. In contrast, on linear DNA or on supercoiled DNA with sites 1605 bp apart, BspMI interacted equally with repeated or inverted sites. The ability of BspMI to detect the relative orientation of two DNA sequences thus depends on both the topology and the length of the intervening DNA. Supercoiling may restrain the juxtaposition of sites 700 bp apart to a particular alignment across the superhelical axis, but the juxtaposition of sites in linear DNA or far apart in supercoiled DNA may occur without restraint. BspMI can therefore act as a sensor of the conformational dynamics of supercoiled DNA.

A unique right end-enhancer complex precedes synapsis of Mu ends: the enhancer is sequestered within the transpososome throughout transposition

Assembly of the Mu transpososome is dependent on interactions of transposase subunits with the left (L) and right (R) ends of Mu and an enhancer (E). We have followed the order and dynamics of association of these sites within a series of transpososomes prior to and during formation of a three-site complex (LER), engagement of Mu ends by the transposase active site (type 0 complex), cleavage of the ends (type I complex) and their transfer to target DNA (type II complex). LER appears to be preceded by a two-site complex (ER) where E and R are interwrapped twice, as in the mature transpososome. At each stage thereafter, the overall topology of five DNA supercoils is retained: two between E and R, one between E and L and two between L and R. However, L-R interactions within LER appear to be flexible. Unexpectedly, the enhancer was seen to persist within the transpososome through cleavage and strand transfer of Mu ends to target DNA.

The Mu enhancer is functionally asymmetric both in cis and in trans. Topological selectivity of Mu transposition is enhancer-independent

Mu DNA transposition from a negatively supercoiled DNA substrate requires interaction of an enhancer element with the left (attL) and right (attR) ends of Mu. The orientation of the L and R ends with respect to each other (inverted) and with respect to the enhancer is normally inviolate. We show that when the enhancer is provided in trans as a linear fragment, the head to head orientation of the L/R ends is still required. Each functional half of the linear enhancer maintains the same "cross-wise" interaction with the subsites L1 and R1, when present in cis or in trans. In reactions catalyzed by an enhancer-independent variant of the Mu transposase, the need for negative supercoiling of the substrate and the inverted orientation of L and R ends is not relaxed. These results show that the orientation specificity of the enhancer is not determined by its topological linkage to the Mu ends. There is a functional asymmetry inherent to the enhancer. Furthermore, the enhancer does not directly impose topological constraints on the transposition reaction or specify the reactive orientation of the Mu ends.

A cruciform structural transition provides a molecular switch for chromosome structure and dynamics

The interaction between specific sites along a DNA molecule is often crucial for the regulation of genetic processes. However, mechanisms regulating the interaction of specific sites are unknown. We have used atomic force microscopy to demonstrate that the structural transition between cruciform conformations can act as a molecular switch to facilitate or prevent communication between distant regions in DNA. Cruciform structures exist in vivo and they are critically involved in the initiation of replication and the regulation of gene expression in different organisms. Therefore, structural transitions of the cruciform may play a key role in these processes.

The McrBC endonuclease translocates DNA in a reaction dependent on GTP hydrolysis

McrBC specifically recognizes and cleaves methylated DNA in a reaction dependent on GTP hydrolysis. DNA cleavage requires at least two recognition sites that are optimally separated by 40-80 bp, but can be spaced as far as 3 kb apart. The nature of the communication between two recognition sites was analyzed on DNA substrates containing one or two recognition sites. DNA cleavage of circular DNA required only one methylated recognition site, whereas the linearized form of this substrate was not cleaved. However, the linearized substrate was cleaved if a Lac repressor was bound adjacent to the recognition site. These results suggest a model in which communication between two remote sites is accomplished by DNA translocation rather than looping. A mutant protein with defective GTPase activity cleaved substrates with closely spaced recognition sites, but not substrates where the sites were further apart. This indicates that McrBC translocates DNA in a reaction dependent on GTP hydrolysis. We suggest that DNA cleavage occurs by the encounter of two DNA-translocating McrBC complexes, or can be triggered by non-specific physical obstacles like the Lac repressor bound on the enzyme's path along DNA. Our results indicate that McrBC belongs to the general class of DNA "motor proteins", which use the free energy associated with nucleoside 5'-triphosphate hydrolysis to translocate along DNA.

Electrostatic-undulatory theory of plectonemically supercoiled DNA

We present an analytical calculation of the electrostatic interaction in a plectonemic supercoil within the Poisson-Boltzmann approximation. Undulations of the supercoil strands arising from thermal motion couple nonlinearly with the electrostatic interaction, giving rise to a strong enhancement of the bare interaction. In the limit of fairly tight winding, the free energy of a plectonemic supercoil may be split into an elastic contribution containing the bending and torsional energies and an electrostatic-undulatory free energy. The total free energy of the supercoil is minimized according to an iterative scheme, which utilizes the special symmetry inherent in the usual elastic free energy of the plectoneme. The superhelical radius, opening angle, and undulation amplitudes in the radius and pitch are obtained as a function of the specific linking difference and the concentration of monovalent salt. Our results compare favorably with the experimental values for these parameters of Boles et al. (1990. J. Mol. Biol. 213:931-951). In particular, we confirm the experimental observation that the writhe is a virtually constant fraction of the excess linking number over a wide range of superhelical densities. Another important prediction is the ionic strength dependence of the plectonemic parameters, which is in reasonable agreement with the results from computer simulations.

DNA-sequence asymmetry directs the alignment of recombination sites in the FLP synaptic complex

The FLP recombinase promotes site-specific recombination in the 2 micrometer circle of Saccharomyces cerevisiae. FLP recognizes a 48 bp target site (FLP recombination target, or FRT) consisting of three 13 bp protein binding sites, or symmetry elements, flanking an 8 bp spacer region. Efficient recombination also occurs with DNA substrates that have minimal FRT sites, consisting only of the spacer and two surrounding 13 bp symmetry elements arranged in inverse orientation; thus, the wild-type spacer sequence is the main asymmetric feature of the minimal recombination site. FLP carries out recombination with many minimal target sites bearing symmetric or asymmetric mutant spacer sequences; however, the overall directionality of recombination defined in terms of inversion or excision of a DNA domain is determined by spacer-sequence asymmetry. In order to evaluate the potential influence of spacer-sequence asymmetry on structures formed during early steps in recombination, we used electron microscopy to investigate the structure of the FLP synaptic complex, which is the intermediate protein-DNA complex involved in site pairing and strand exchange. Using linear substrate DNAs that have minimal FRTs with wild-type spacer sequences, we find that 85 to 90% of the FLP synaptic complexes examined contain the two FRTs aligned in parallel. This strong preference for parallel site alignment stands in contrast with prevailing models for lambda integrase-class recombination systems, which postulate antiparallel site alignment, and results from biophysical studies on synthetic, immobile four-way DNA junctions. Our results show that the strong preference for parallel alignment can be attributed to conformational preferences of Holliday junctions present in the synaptosome.

Minicircle: an improved DNA molecule for in vitro and in vivo gene transfer

Minicircles are a new form of supercoiled DNA molecule for nonviral gene transfer which have neither bacterial origin of replication nor antibiotic resistance marker. They are thus smaller and potentially safer than the standard plasmids currently used in gene therapy. They were obtained in E. coli by att site-specific recombination mediated by the phage lambda integrase, which was used to excise the expression cassette from the unwanted plasmid sequences. We produced two minicircles containing the luciferase or beta-galactosidase gene under the control of the strong human cytomegalovirus immediate-early enhancer/promoter. Comparing maximal differences, these minicircles gave 2.5 to 5.5 times more reporter gene activity than the unrecombined plasmid in the NIH3T3 cell line and rabbit smooth muscle cells. Moreover, injection in vivo into mouse cranial tibial muscle, or human head and neck carcinoma grafted in nude mice resulted in 13 to 50 times more reporter gene expression with minicircles than with the unrecombined plasmid or larger plasmids. Histological analysis in muscle showed there were more transfected myofibers with minicircles than with unrecombined plasmid.

Gyrase and Topo IV modulate chromosome domain size in vivo

In bacteria, DNA supercoil movement is restricted to subchromosomal regions or 'domains.' To elucidate the nature of domain boundaries, we analysed reaction kinetics for gammadelta site-specific resolution in six chromosomal intervals ranging in size from 14 to 90 kb. In stationary cultures of Salmonella typhimurium, resolution kinetics were rapid for both short and long intervals, suggesting that random stationary barriers occur with a 30% probability at approximately 80 kb intervals along DNA. To test the biochemical nature of domain barriers, a genetic screen was used to look for mutants with small domains. Rare temperature-sensitive alleles of DNA gyrase and Topo IV (the two essential type II topoisomerases) had more supercoil barriers than wild-type strains in all growth states. The most severe gyrase mutants were found to have twice as many barriers in growing cells as wild type throughout a 90 kb interval of the chromosome. We propose that knots and tangles in duplex DNA restrain supercoil diffusion in living bacteria.

Cooperative binding properties of restriction endonuclease EcoRII with DNA recognition sites

EcoRII is a member of the expanding group of type IIe restriction endonucleases that share the distinguishing feature of requiring cooperativity between two recognition sites in their substrate DNA. To determine the stoichiometry of the active DNA-enzyme complex and the mode of cooperative interaction, we have investigated the dependence of EcoRII cleavage on the concentration of EcoRII dimers. Maximal restriction was observed at dimer/site ratios of 0.25 and 0. 5. The molecular weight of the DNA-enzyme complex eluted from a gel filtration column also corresponds to a dimeric enzyme structure bound to two substrate sites. We conclude that one EcoRII dimer is sufficient to interact cooperatively with two DNA recognition sites. A Lac repressor "barrier" bound between two normally reactive EcoRII sites did not inhibit restriction endonuclease activity, indicating that cooperativity between EcoRII sites is achieved by bending or looping of the intervening DNA stretch. Comparative cleavage of linear substrates with differently spaced interacting sites revealed an inverse correlation between cleavage rate and site distance. At the optimal distance of one helical turn, EcoRII cleavage is independent of the orientation of the recognition sequence in the DNA double strand.

Communications between distant sites on supercoiled DNA from non-exponential kinetics for DNA synapsis by resolvase

To determine how distant sites on supercoiled DNA communicate with each other, the mechanism of site-specific recombination by resolvase was analysed by using a rapid-reaction quench-flow device to study the kinetics of individual steps in the reaction pathway. Three sets of measurements revealed the rates for: (1) the initial binding of the protein to its target sites on the DNA; (2) the synapsis of the two DNA-protein complexes; (3) the overall process of recombination. The binding of the protein to the DNA was complete within 50 milliseconds while recombination required 500 seconds. Surprisingly, synapsis spanned this entire time range: some DNA molecules gave synaptic complexes within ten milliseconds after the initial binding, while others took over 100 seconds. The departure from exponential behaviour may be due to each molecule of DNA having to undergo different conformational fluctuations in order to juxtapose the recombinational sites. From polymer physics theory, the rate of synapsis ought to vary with either the size of the DNA molecule or the length of DNA between the recombinational sites, depending on the nature of the fluctuations, but plasmids of different sizes and with different spacings between the sites all gave the same rates for synapsis. This observation cannot be reconciled with current models for encounters of distant sites on supercoiled DNA. However, the superhelical axis in the DNA molecules used here will be branched at one or more positions and the encounters may arise from the motion of a single branch relative to the remainder of the chain. Alternatively, the non-exponential kinetics for synapsis may be due to multiple re-arrangements of non-productive complexes following DNA juxtaposition.

Nested DNA inversion as a paradigm of programmed gene rearrangement

Programmed gene rearrangements are employed by a variety of microorganisms, including viruses, prokaryotes, and simple eukaryotes, to control gene expression. In most instances in which organisms mediate host evasion by large families of homologous gene cassettes, the mechanism of variation is not thought to involve DNA inversion. Here we report that Campylobacter fetus, a pathogenic Gram-negative bacterium, reassorts a single promoter, controlling surface-layer protein expression, and one or more complete ORFs strictly by DNA inversion. Rearrangements were independent of the distance between sites of inversion. These rearrangements permit variation in protein expression from the large surface-layer protein gene family and suggest an expanding paradigm of programmed DNA rearrangements among microorganisms.

Visualization of supercoiled DNA with atomic force microscopy in situ

Tertiary structure of supercoiled DNA is a significant factor in a number of genetic functions and is apparently affected by environmental conditions. We applied atomic force microscopy (AFM) for imaging the supercoiled DNA deposited at different ionic conditions. We have employed a technique for the sample preparation that permits high-resolution AFM imaging of DNA bound to the surface in buffer solutions without drying the sample (AFM in situ). The AFM data show that at low ionic strength, DNA molecules are loosely interwound supercoils with an irregular shape. Plectonemic superhelices are formed in high-concentration, near-physiological salt solutions. At such ionic conditions, superhelical loops are typically separated by regions of close helix-helix contacts. The data obtained show directly and unambiguously that overall geometry of supercoiled DNA depends dramatically on ionic conditions. This fact and the formation of close contacts between DNA helices are important features of supercoiled DNA related to its biological functions.

Cruciform structures and functions

In this paper, a structure-function analysis of B-DNA self-fitting is reviewed in the light of recent oligonucleotide crystal structures. Their crystal packings provided a high-resolution view of B-DNA helices closely and specifically fitted by groove-backbone interaction, a natural and biologically relevant manner to assemble B-DNA helices. In revealing that new properties of the DNA molecule emerge during condensation, these crystallographic studies have pointed to the biological importance of DNA—DNA interactions.

Transcription regulation by inflexibility of promoter DNA in a looped complex

The gal operon of Escherichia coli is negatively regulated by repressor binding to bipartite operators separated by 11 helical turns of DNA. Synergistic binding of repressor to separate sites on DNA results in looping, with the intervening DNA as a topologically closed domain containing the two promoters. A closed DNA loop of 11 helical turns, which is in-flexible to torsional changes, disables the promoters either by resisting DNA unwinding needed for open complex formation or by impeding the processive DNA contacts by an RNA polymerase in flux during transcription initiation. Interaction between two proteins bound to different sites on DNA modulating the activity of the intervening segment toward other proteins by allostery may be a common mechanism of regulation in DNA-multiprotein complexes.

Analysis of the mechanism of DNA recombination using tangles

The DNA of all organisms has a complex and essential topology. The three topological properties of naturally occurring DNA are supercoiling, catenation, and knotting. Although these properties are denned rigorously only for closed circular DNA, even linear DNAin vivocan have topological properties because it is divided into topologically separate subdomains (Drlica 1987; Roberge & Gasser, 1992). The essentiality of topological properties is demonstrated by the lethal consequence of interfering with topoisomerases, the enzymes that regulate the level of DNA supercoiling and that unlink DNA during its replication (reviewed in Wang, 1991; Bjornsti, 1991; Drlica, 1992; Ullspergeret al. 1995).

Involvement of ArgR and PepA in the pairing of ColE1 dimer resolution sites

Dimer formation and associated copy number depression is an important cause of multicopy plasmid instability. Natural multicopy plasmids employ site-specific recombination to convert dimers to monomers, thus maximizing the number of independently segregating molecules at cell division. Resolution of dimers of Escherichia coli plasmid ColE1 requires the plasmid cer site and at least four chromosome-encoded proteins: the XerC and XerD recombinases, and accessory factors ArgR and PepA. It has been suggested that ArgR has a role in the initial pairing of recombination sites and we describe here an attempt to detect this process in vivo. Our approach exploits a previous observation that a cer-like site known as the type II hybrid supports inter-molecular recombination and causes extensive multimerization of plasmids. We report that type-II-mediated multimerization can be repressed by a cer site in cis or in trans and propose that this is due to a physical interaction between the sites. If this hypothesis is correct, suppression of multimer formation provides an assay of site pairing. Our results demonstrate that the putative pairing interaction is independent of the topological relationship of the sites and that both PepA and ArgR are involved. Although most recombination-deficient mutant derivatives of ArgR are unable to pair recombination sites, we have found two (ArgR110 and ArgR115) which retain pairing activity. The validity of the pairing hypothesis is discussed in the light of alternative explanations for our data.

Complete transposition requires four active monomers in the mu transposase tetramer

A tetramer of Mu transposase (MuA) cleaves and joins multiple DNA strands to promote transposition. Derivatives of MuA altered at two acidic residues that are conserved among transposases and retroviral integrases form tetramers but are defective in both cleavage and joining. These mutant proteins were used to analyze the contribution of individual monomers to the activity of the tetramer. The performance of different protein combinations demonstrates that not all monomers need to be catalytically competent for the complex to promote an individual cleavage or joining reaction. Furthermore, the results indicate that each pair of essential residues is probably donated to the active complex by a single monomer. Although stable, tetramers composed of a mixture of mutant and wild-type MuA generate products cleaved at only one end and with only one end joined to the target DNA. The abundance of these abortive products and the ratios of the two proteins in complexes stalled at different steps indicate that the complete reaction requires the activity of all four monomers. Thus, each subunit of MuA appears to use the conserved acidic amino acids to promote one DNA cleavage or one DNA joining reaction.

Regulation of int gene expression in bacteriophage P2

The int gene of bacteriophage P2 is the only viral gene necessary for the integration of P2 into the Escherichia coli host chromosome. This gene is situated between the phage attachment site, attP, and the repressor C gene, and is cotranscribed with C from the Pc promoter, towards attP. The Pc promoter is negatively controlled by the cox gene, which is the first gene of the early operon. In vitro recombination assays have indicated that in P2 an overproduction of Int is deleterious to the integrative process. We report here that the level of int expression is affected by several different mechanisms after transcriptional initiation. First, a partial transcription termination signal located between the int and C genes reduces the the transcriptional readthrough by about 30%. Second, the ribosome binding site and AUG codon of the int gene are located in a putative stem-loop structure, which may inhibit the initiation of translation. The nip1 mutation (a G to A substitution at the 22nd coding nucleotide of int which results in an increased efficiency of excision) is shown to relieve this inhibition, possible through the formation of an alternative mRNA secondary structure. However, the third and probably most important control of int expression in P2 seems to be that of posttranscriptional autoregulation. The binding site of the Int protein on int gene mRNA is shown to extend into the ribosome binding site of int, supporting our earlier proposed model of competitive binding between Int and ribosomes.

Stereoselectivity of DNA catenane fusion by resolvase

Communications between distant sites on DNA often depend on the way in which the sites are connected. For example, site-specific recombination catalysed by Tn3 resolvase is most efficient when the 114-base-pair res recombination sites are directly repeated in the same DNA molecule. In vitro a supercoiled plasmid substrate containing two directly repeated res sites gives a resolution product in which the two recombinant circles are topologically linked as a simple (two-noded) catenane (Fig. 1a). Resolvase is highly selective in forming this product rather than unlinked circles or more complex catenanes. It does not catalyse recombination between sites on separate supercoiled molecules, or between inverted sites in the same supercoiled molecule. Tn3 resolution removes four negative supercoils from the substrate, an energetically favourable change which may drive the reaction: in relaxed or nicked circular substrates, resolution is incomplete and slower. Resolvase can catalyse fusion of the circles of a nicked or relaxed catenane, giving a single unknotted circular product. The fusion is the precise topological reversal of resolution, introducing four negative supercoils into a relaxed catenane substrate, and should therefore not proceed if the catenane is already negatively supercoiled. Here we study recombination between res sites in non-supercoiled DNA circles linked into simple catenanes. We used (+2) and (-2) catenanes, which differ only in the direction in which one circle is threaded through the other (Fig. 2a). Although stereoselectivity is a feature of enzyme catalysis, it is not obvious how resolvase can distinguish between these subtly different catenane diastereomers. A model for the intertwining of the res site DNA in the catalytically active complex predicts that only the (-2) catenane will recombine, giving unknotted and 4-noded knot circular products. We have confirmed this prediction for the Tn3 and Tn21 resolvases.

Formation of a cleavasome: enhancer DNA-2 stabilizes an active conformation of NaeI dimer

Cleavage of DNA by NaeI-type restriction enzymes is stimulated by a DNA element with affinity for the activator site of the enzyme: a cleavage-enhancer DNA element. Measurements of the mobility of NaeI activity in comparison with protein standards on gel permeation columns and glycerol gradients demonstrated that NaeI, without enhancer, can form a 70,000 MW dimer. The dimer, however, is inactive: it could not cleave the "resistant" NaeI site in M13mp18 DNA in the absence of enhancer. In cleavage assays, enhancer stimulated either DNA nicking or DNA cleavage, depending upon NaeI concentration, and reduced the NaeI concentration required for the transition from nicking to cleavage activity. A gel mobility-shift assay of the interaction of NaeI with enhancer showed the formation of two complexes. Results using different sized DNAs and different percentage acrylamide gels for gel mobility-shift analysis implied that the two complexes were caused by NaeI monomer and dimer structures rather than one and two DNA binding. Dimer formation increased with the affinity of enhancer for NaeI. UV cross-linking "captured" the NaeI-enhancer complex; electrophoretic analysis of the cross-linked products showed NaeI dimer bound to enhancer. These results imply a model for cleavage enhancement in which enhancer binding stabilizes an active NaeI dimer conformation ("cleavasome") that cleaves both DNA strands before dissociating.

Knotting of a DNA chain during ring closure

The formation of knotted species on random ring closure of two DNAs that are 5.6 kilobase pairs (kbp) and 8.6 kbp in length was measured, and these data were used to calculate the effective DNA helix diameter as a function of sodium ion and magnesium ion concentration. In the presence of more than 50 mM magnesium ion, interactions between DNA segments appear to be attractive rather than repulsive. The free energy of formation of relaxed trefoil and figure-eight DNA knots and of supercoiled trefoil DNA knots was also evaluated.

International Commission for Protection against Environmental Mutagens and Carcinogens. Recombination and gene conversion

Recombination is an important aspect of DNA metabolism. It leads to rearrangements of DNA sequences within genomes. Such genome rearrangements seem to be ubiquitous, since they play a role in evolution, human health and biotechnology. In medicine one important aspect of recombination is its role as one possible step in the multistep process of carcinogenesis. Since recombination may occur as a cellular response to DNA damage, the protection of cells from recombination-inducing agents, so-called recombinagen, should eliminate possible deleterious effects resulting from damage-induced DNA recombination. During the last few years, the awareness of the importance of recombination phenomena has substantially increased and the development of assay systems detecting recombinagens has progressed. The need for considering recombinagenic effects as a safety aspect of chemicals has gained ground in the field of genetic toxicology. This paper summarizes present knowledge concerning the occurence, inducibility, detection and toxicological interpretation of DNA recombination.

Switch recombination breakpoints are strictly correlated with DNA recognition motifs for immunoglobulin S gamma 3 DNA-binding proteins

The deletion looping out model of switch (S) recombination predicts that the intervening DNA between switch regions will be excised as a circle. Circular excision products of immunoglobulin switch recombination have been recently isolated from lipopolysaccharide (LPS)-stimulated spleen cells. The recombination breakpoints in these large circles were found to fall within switch regions. Since switch recombination is clearly focused on switch regions, we hypothesized that some DNA-binding protein factor might be involved in specifically recognizing and facilitating the alignment of switch regions before recombination. Two DNA-binding proteins that specifically interact with two discrete regions of the S gamma 3 tandem repeat have been identified in crude and partially purified nuclear extracts derived from LPS- and dextran sulfate (DxS)-activated splenic B cells. The first factor has been found indistinguishable from NF-kappa B by mobility shift assays, methylation interference, competition binding studies, and supershift analysis using an antiserum specific for the p50 component. The second appears to be composed of two closely traveling mobilities that do not separate upon partial purification. This second complex is unique and specific for S gamma 3 by methylation interference assays and competition-binding analysis. The sites at which recombination occurs in the S gamma 3 switch region have been analyzed and found to strictly correlate with the binding sites of the S gamma 3 switch binding proteins.

The Mu transpositional enhancer can function in trans: requirement of the enhancer for synapsis but not strand cleavage

The phage Mu transpositional enhancer has been previously shown to stimulate the initial rate of the Mu DNA strand transfer reaction by a factor of 100. We now show that the Mu enhancer can function in trans on an unlinked DNA molecule. This activity is greatly facilitated by the presence of a free DNA end proximal to the enhancer element. Function of the enhancer in trans does not alter either the requirement for donor DNA supercoiling or for the two Mu ends to be in their proper orientation on the donor plasmid. An important consequence of these findings is that we have been able to evaluate directly the step in the transposition reaction for which the enhancer is required. We show that the role of the enhancer is limited to promoting productive synapsis; efficient strand cleavage can occur in the absence of the enhancer.

Activation of restriction endonuclease EcoRII does not depend on the cleavage of stimulator DNA

The restriction endonuclease EcoRII is unable to cleave DNA molecules when recognition sites are very far apart. The enzyme, however can be activated in the presence of DNA molecules with a high frequency of EcoRII sites or by oligonucleotides containing recognition sites: Addition of the activator molecules stimulates cleavage of the refractory substrate. We now show that endonucleolysis of the stimulator molecules is not a necessary prerequisite of enzyme activation. A total EcoRII digest of pBR322 DNA or oligonucleotide duplexes with simulated EcoRII ends (containing the 5' phosphate group), as well as oligonucleotide duplexes containing modified bases within the EcoRII site, making them resistant to cleavage, are all capable of enzyme activation. For activation EcoRII requires the interaction with at least two recognition sites. The two sites may be on the same DNA molecule, on different oligonucleotide duplexes, or on one DNA molecule and one oligonucleotide duplex. The efficiency of functional intramolecular cooperation decreases with increasing distance between the sites. Intermolecular site interaction is inversely related to the size of the stimulator oligonucleotide duplex. The data are in agreement with a model whereby EcoRII simultaneously interacts with two recognition sites in the active complex, but cleavage of the site serving as an allosteric activator is not necessary.

Alignment of recombination sites in Hin-mediated site-specific DNA recombination

The Hin site-specific recombination system normally promotes inversion of DNA between two recombination sites in inverted orientation. We show that the rate of deletion of DNA between two directly repeated recombination sites is 10-300 times slower than inversion between sites in their native configuration as measured in vivo and in vitro, respectively. In vitro studies have shown that the deletion reaction has the same requirement for Fis, a recombinational enhancer, and DNA supercoiling as the inversion reaction. These requirements, together with the finding that the deletion products are interlinked once suggest that the deletion synaptic complex is similar to the invertasome intermediate that generates inversion. The inefficiency of the deletion reaction is not a function of a reduced ability to recognize or synapse recombination sites in direct orientation. Not only do these substrates support an efficient knotting reaction, but directly repeated recombination sites with symmetric core sequences also invert efficiently. These findings demonstrate that the recombination sites are preferentially assembled into the invertasome structure with the sites aligned in the configuration for inversion regardless of their starting orientation. We propose that the dynamics of a supercoiled DNA molecule biases the geometric assembly of specific intermediates. In the case of Hin-mediated recombination, inversion is overwhelmingly preferred over deletion because DNA supercoiling favors a specific alignment of DNA strands in the synaptic complex.

Dynamics of long-range interactions on DNA: the speed of synapsis during site-specific recombination by resolvase

A noninvasive method for monitoring communications on DNA was developed from the specificity of resolvase for the arrangement of its recombinational sites. Constraints in DNA structure, caused by interactions between distant sites, can be detected by resolvase as they arise. The method was used to follow the formation and decay of synaptic intermediates during site-specific recombination by resolvase. Synaptic complexes were formed very rapidly, at a rate limited by the initial association of the protein with DNA rather than the physical motion of DNA segments. The recombinational sites seem to encounter each other by an ordered motion, perhaps dictated by DNA supercoiling instead of random collisions, so that the first encounter produces the active complex.

Detection of conformational and net charge differences in DNA-protein complexes by quantitative electrophoresis on polyacrylamide-agarose copolymer gels

The Galactosidase repressor (GalR) of Escherichia coli modulates the expression of the gal operon by binding to two DNA operators, OE and O1. The OE and O1 elements are 16 bp pallindromic DNA sequences, differing in four of the base pairs. OE and O1 DNA fragments, both free and complexed with repressor, were analyzed by "quantitative gel electrophoresis". By the criteria of that method, applied to the linear Ferguson plots of both DNA fragments and the linear ranges of those of the DNA-GalR complexes, it was shown that the apparent size of DNA increases upon repressor binding. Moreover, this size increase is greater for the complex with the O1 operator than for the complex with the OE operator in the case that GalR is located in the center of a 155 bp DNA fragment. This is not the case when GalR is located in a peripheral position. By contrast with their size differences, the centrally located GalR-O1 and GalR-OE complexes appear to possess indistinguishable net surface charge densities as judged from the intercepts with the mobility axis. The larger size of the complex with centrally located O1 fragment, as compared with that bearing the OE fragment, is interpreted as being due to bending of the DNA-protein complex, since an authentically bent fragment of a plasmid with bent upstream activator sequence also exhibits a larger slope of the Ferguson plot, and thus the larger size, than predicted on the basis of its DNA chain length (bp).(ABSTRACT TRUNCATED AT 250 WORDS)

DNA looping between sites for transcriptional activation: self-association of DNA-bound Sp1

The Sp1 protein activates transcription from many eukaryotic promoters. Sp1 can act in vivo from enhancer sites that are distal to the promoter and exhibit synergistic interaction with promoter-proximal binding sites. To investigate possible protein-protein interactions between DNA-bound Sp1 molecules, we have used electron microscopy to visualize the DNA-protein complexes. At the SV40 promoter, we observed the expected localized interaction at the Sp1 sites; in addition, we found that DNA-bound Sp1 served to associate two or more DNA molecules. At a modified thymidine kinase promoter, we observed a localized interaction at each of two binding locations that were separated by 1.8 kbp; in addition, we noted a substantial fraction of DNA molecules in which the distant binding regions were joined by a DNA loop. As judged by studies with mutant Sp1 proteins, the distant interactions depended on the glutamine-rich regions of Sp1 required for transcriptional activation. We conclude that DNA-bound Sp1 can self-associate, bringing together distant DNA segments. From the correlation between DNA looping in vitro and synergistic activation of the modified thymidine kinase promoter shown previously in vivo, we suggest that Sp1 exerts its transcriptional synergism by a direct protein-protein association that loops the intervening DNA. Our experiments support the DNA-looping model for the function of transcriptional enhancers.

Different mechanisms inferred from sequences of human mitochondrial DNA deletions in ocular myopathies

We have sequenced the deletion borders of the muscle mitochondrial DNA from 24 patients with heteroplasmic deletions. The length of these deletions varies from 2.310 bp to 8.476 bp and spans from position 5.786 to 15.925 of the human mitochondrial genome preserving the heavy chain and light chain origins of replication. 12 cases are common deletions identical to the mutation already described by other workers and characterized by 13 bp repeats at the deletion boundaries, one of these repeats being retained during the deletion process. The other cases (10 out of 12) have shown deletions which have not been previously described. All these deletions are located in the H strand DNA region which is potentially single stranded during mitochondrial DNA replication. In two cases, the retained Adenosine from repeat closed to the heavy strand origin of replication would indicate slippage mispairing. Furthermore in one patient two mt DNA molecules have been cloned and their sequences showed the difference of four nucleotides in the breakpoint of the deletion, possibly dued to slippage mispairing. Taken together our results suggest that deletions occur either by slippage mispairing or by internal recombination at the direct repeat level. They also suggest that different mechanisms account for the deletions since similarly located deletions may display different motives at the boundaries including the absence of any direct repeat.

Transcriptional enhancers can act in trans

Enhancers have been defined operationally as cis-regulatory sequences that can stimulate transcription of RNA polymerase-II-transcribed genes over large distances and even when located downstream of the gene. Recently, it has become evident that enhancers can also stimulate transcription in trans if they are brought into close proximity to the promoter/gene. These reports provide clues to the mechanism of remote enhancer action. In addition, the findings, together with genetic studies in Drosophila, strongly suggest that enhancer action in trans could underlie phenomena such as 'transvection', where one chromosome affects gene expression in the paired homolog.

The Hin invertasome: protein-mediated joining of distant recombination sites at the enhancer

The Hin protein binds to two cis-acting recombination sites and catalyzes a site-specific DNA inversion reaction that regulates the expression of flagellin genes in Salmonella. In addition to the Hin protein and the two recombination sites that flank the invertible segment, a third cis-acting recombinational enhancer sequence and the Fis protein, which binds to two sites within the enhancer, are required for efficient recombination. Intermediates of this reaction were trapped during DNA strand cleavage and analyzed by gel electrophoresis and electron microscopy in order to determine their structure and composition. The analyses demonstrate that the recombination sites are assembled at the enhancer into a complex nucleo-protein structure (termed the invertasome) with the looping of the three segments of intervening DNA. Antibody studies indicated that Fis physically interacts with Hin and that both proteins are intimately associated with the invertasome. In order to achieve this protein-protein interaction and assemble the invertasome, the substrate DNA must be supercoiled.