DNA looping and the helical repeat in vitro and in vivo: effect of HU protein and enhancer location on Hin invertasome assembly.

Site-specific DNA inversion by the Hin recombinase requires the formation of a multicomponent nucleo-protein structure called an invertasome. In this structure, the two recombination sites bound by Hin are assembled together at the Fis-bound recombinational enhancer with the requisite looping of the intervening DNA segments. We have analyzed the role of the HU protein in invertasome assembly when the enhancer is located at variable positions close to one of the recombination sites. In the absence of HU in vitro and in hupA hupB mutant cells in vivo, invertasome assembly is very inefficient when there is < 104 bp of DNA between the enhancer and recombination site. Invertasome assembly in the presence of HU in vitro or in vivo displayed a periodicity beginning with 60 bp of intervening DNA that reflected its helical repeat. The average helical repeat for this DNA region was calculated by autocorrelation and Fourier transformation to be 11.2 bp per turn for supercoiled DNA both in the presence of HU in vitro and in hup+ cells in vivo. HU is the only protein in Escherichia coli that can promote invertasome formation with short DNA lengths between the enhancer and recombination sites. However, the presence of certain polyamines and a protein activity present in HeLa nuclear extracts can efficiently substitute for HU in invertasome assembly. These data support a model in which HU binds non-specifically to the DNA between the enhancer and recombination site to facilitate DNA looping.     

Cooperative DNA looping by PRC2 complexes

Polycomb repressive complex 2 (PRC2) is an essential protein complex that silences gene expression via post-translational modifications of chromatin. This paper combined homology modeling, atomistic and coarse-grained molecular dynamics simulations, and single-molecule force spectroscopy experiments to characterize both its full-length structure and PRC2-DNA interactions. Using free energy calculations with a newly parameterized protein-DNA force field, we studied a total of three potential PRC2 conformations and their impact on DNA binding and bending. Consistent with cryo-EM studies, we found that EZH2, a core subunit of PRC2, provides the primary interface for DNA binding, and its curved surface can induce DNA bending. Our simulations also predicted the C2 domain of the SUZ12 subunit to contact DNA. Multiple PRC2 complexes bind with DNA cooperatively via allosteric communication through the DNA, leading to a hairpin-like looped configuration. Single-molecule experiments support PRC2-mediated DNA looping and the role of AEBP2 in regulating such loop formation. The impact of AEBP2 can be partly understood from its association with the C2 domain, blocking C2 from DNA binding. Our study suggests that accessory proteins may regulate the genomic location of PRC2 by interfering with its DNA interactions.     

DNA topology: dynamic DNA looping

The DNA in repressive loops is often tightly bent. DNA flexibility imposes significant constraints on their topology suggesting that they may exist as perturbations in plectonemic DNA.     

Physical properties of DNA in vivo as probed by the length dependence of the lac operator looping process

Plasmid constructs containing a wild-type (O+) lac operator upstream of an operator-constitutive (Oc) lac control element exhibit a length-dependent, oscillatory pattern of repression of expression of the regulated gene as interoperator spacing is varied from 115 to 177 base pairs (bp). Both the length dependence and the periodicity of repression are consistent with a thermodynamic model involving a stable looped complex in which bidentate lac repressor interacts simultaneously with both O+ and Oc operators. The oscillatory pattern of repression with distance occurs with a period approximating the helical repeat of DNA and presumably reflects the necessity for proper alignment of interacting operators along the helical face of the DNA. In the length regime examined, the presence of the upstream operator enhances repression between 6-fold and 50-fold depending upon phasing. This reflects a torsional rigidity of DNA in vivo that is consistent with in vitro measurements. The oscillatory pattern of repression is best fit with a period of either 9.0 or 11.7 bp/cycle but not 10.5 bp/cycle. This periodicity is interpreted as reflecting the average helical repeat of the 40-bp interoperator region of plasmid DNA in vivo, suggesting that the local helical repeat of DNA in vivo may differ significantly from 10.5 bp/turn. The apparent persistence length needed to fit the data (aapp) is only one-fifth the standard in vitro value. This low value of aapp may be due in part to DNA bending induced by catabolite activator protein (CAP) bound to its site between the interacting operators.(ABSTRACT TRUNCATED AT 250 WORDS)     

DNA damage induced in vivo in various tissues by nitrochlorobenzene derivatives

Mono-, di-, and trinitrochlorobenzenes were injected i.p. into albino Swiss CD1 mice. Their effects were evaluated, in brain, liver and kidney, as single-strand DNA breaks.DNA damage was recognizable 4 h after administration in vivo, and its increment seemed to be related to the number of nitro groups contained in the chlorobenzene molecule.The simple and accurate microfluorometric procedure for DNA assay associated to the alkaline elution technique improved the application in vivo, avoiding the radiolabeling of DNA.     

Entropy loss in long-distance DNA looping

The entropy loss due to the formation of one or multiple loops in circular and linear DNA chains is calculated from a scaling approach in the limit of long chain segments. The analytical results allow us to obtain a fast estimate for the entropy loss for a given configuration. Numerical values obtained for some examples suggest that the entropy loss encountered in loop closure in typical genetic switches may become a relevant factor in comparison to both k(B)T and typical bond energies in biopolymers, which has to be overcome by the released bond energy between the looping contact sites.     

Quantitative comparison of DNA looping in vitro and in vivo: chromatin increases effective DNA flexibility at short distances

The probability that two sites on a linear DNA molecule will contact each other by looping depends on DNA flexibility. Although the flexibility of naked DNA in vitro is well characterized, looping in chromatin is poorly understood. By extending existing theory, we present a single equation that describes DNA looping over all distances. We also show that DNA looping in vitro can be measured accurately by FLP recombination between sites from 74 bp to 15 kb apart. In agreement with previous work, a persistence length of 50 nm was determined. FLP recombination of the same substrates in mammalian cells showed that chromatin increases the flexibility of DNA at short distances, giving an apparent persistence length of 27 nm.     

ATP‐dependent looping of DNA by ISWI

Snf2 related chromatin remodelling enzymes possess an ATPase subunit similar to that of the SF‐II helicases which hydrolyzes ATP to track along DNA. Translocation and any resulting torque in the DNA could drive chromatin remodeling. To determine whether the ISWI protein can translocate and generate torque, tethered particle motion experiments and atomic force microscopy have been performed using recombinant ISWI expressed in E. coli. In the absence of ATP, ISWI bound to and wrapped DNA thereby shortening the overall contour length measured in atomic force micrographs. Although naked DNA only weakly stimulates ATP hydrolysis by ISWI, both atomic force microscopy and tethered particle motion data indicate that the protein generated loops in the presence of ATP. The duration of the looped state of the DNA measured using tethered particle motion was ATP‐dependent. Finally, ISWI relaxed positively supercoiled plasmids visualized by atomic force microscopy. While other chromatin remodeling ATPases catalyze either DNA wrapping or looping, both are catalyzed by ISWI. (© 2008 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Statistical-mechanical theory of DNA looping

The lack of a rigorous analytical theory for DNA looping has caused many DNA-loop-mediated phenomena to be interpreted using theories describing the related process of DNA cyclization. However, distinctions in the mechanics of DNA looping versus cyclization can have profound quantitative effects on the thermodynamics of loop closure. We have extended a statistical mechanical theory recently developed for DNA cyclization to model DNA looping, taking into account protein flexibility. Notwithstanding the underlying theoretical similarity, we find that the topological constraint of loop closure leads to the coexistence of multiple classes of loops mediated by the same protein structure. These loop topologies are characterized by dramatic differences in twist and writhe; because of the strong coupling of twist and writhe within a loop, DNA looping can exhibit a complex overall helical dependence in terms of amplitude, phase, and deviations from uniform helical periodicity. Moreover, the DNA-length dependence of optimal looping efficiency depends on protein elasticity, protein geometry, and the presence of intrinsic DNA bends. We derive a rigorous theory of loop formation that connects global mechanical and geometric properties of both DNA and protein and demonstrates the importance of protein flexibility in loop-mediated protein-DNA interactions.     

DNA repair synthesis and chromosomal aberrations induced in vivo by triethylenemelamine

The alkylating agent, triethylenemelamine (TEM), was studied for its ability to induce unscheduled DNA (repair) synthesis (UDS) in vivo in rat lymphocytes. Somatic cytogenetic alterations were analyzed (in bone marrow) and compared with UDS as a function of TEM dosage. UDS was evaluated through the use of autoradiography; cytogenetic alterations were studied in metaphase bone marrow chromosome preparations.Data indicated that the degree of UDS is a direct function of TEM dosage up to a rate-limiting concentration, at which point it ceases to be dose dependent. Except for a deviation at the highest dose level tested, the extent of cytogenetic damage was directly and linearly related to TEM dose. Between the control and intermediate (0.2 mg/kg) dose levels, UDS response increased II-fold while cytogenetic damage showed only a 4-fold increase; this disparity diminished with increasing TEM dose. In the lower dose levels, therefore, the greater relative sensitivity of UDS evaluation in the detection of genetic activity may be indicated. Patterns of UDS response observed through the in vivo assay developed in this study were found to be analogous to those established in in vitro studies.