DNA supercoiling and gene expression

A high throughput single molecule platform to study DNA supercoiling effect on protein-DNA interactions

DNA supercoiling significantly influences DNA metabolic pathways. To examine its impact on DNA-protein interactions at the single-molecule level, we developed a highly efficient and reliable protocol to modify plasmid DNA at specific sites, allowing us to label plasmids with fluorophores and biotin. We then induced negative and positive supercoiling in these plasmids using gyrase and reverse gyrase, respectively. Comparing supercoiled DNA with relaxed circular DNA, we assessed the effects of supercoiling on CRISPR-Cas9 and mismatch repair protein MutS. We found that negative DNA supercoiling exacerbates off-target effects in DNA unwinding by Cas9. For MutS, we observed both negative and positive DNA supercoiling enhances the binding interaction between MutS and a mismatched base pair but does not affect the rate of ATP-induced sliding clamp formation. These findings not only underscore the versatility of our protocol but also opens new avenues for exploring the intricate dynamics of protein-DNA interactions under the influences of supercoiling.

Electrophoretic Analysis of the DNA Supercoiling Activity of DNA Gyrase

Most bacterial cells have a motor enzyme termed DNA gyrase, which is a type-2 topoisomerase that reduces the linking number (Lk) of DNA. The supercoiling energy generated by gyrase is essential to maintain the bacterial chromosome architecture and regulate its DNA transactions. This chapter describes the use of agarose-gel electrophoresis to detect the unconstrained supercoiling of DNA generated by gyrase or other gyrase-like activities. Particular emphasis is made on the preparation of a relaxed plasmid as initial DNA substrate, on the distinction of constrained and unconstrained DNA supercoils, and on the measurement of the DNA supercoiling density achieved by gyrase activity.

Topical Docosahexaenoic Acid (DHA) Accelerates Skin Wound Healing in Rats and Activates GPR120

BACKGROUND

The development of methods for improving skin wound healing may have an impact on the outcomes of a number of medical conditions. The topical use of polyunsaturated fatty acids (PUFAs) can accelerate skin wound healing through mechanisms that involve, at least in part, the modulation of inflammatory activity.

PURPOSE

We evaluated whether G-protein-coupled receptor 120 (GPR120), a recently identified receptor for docosahexaenoic acid (DHA) with anti-inflammatory activity, is expressed in the skin and responds to topical DHA.

METHOD

Male Wistar rats were submitted to an 8.0-mm wound on the back and were immediately administered a topical treatment of a solution containing 30 μM of DHA once a day. The healing process was photodocumented, and tissues were collected on Days 5, 9, and 15 for protein and RNA analyses and histological evaluation.

RESULTS

GPR120 was expressed in the intact skin and in the wound. Keratinocytes expressed the most skin GPR120, while virtually no expression was detected in fibroblasts. Upon DHA topical treatment, wound healing was significantly accelerated and was accompanied by the molecular activation of GPR120, as determined by its association with β-arrestin-2. In addition, DHA promoted a reduction in the expression of interleukin (IL) 1β and an increase in the expression of IL-6. Furthermore, there was a significant increase in expression of transforming growth factor β (TGF-β) and the keratinocyte marker involucrin.

DISCUSSION

Topical DHA improved skin wound healing. The activation of GPR120 is potentially involved in this process.

Hypothalamic stearoyl-CoA desaturase-2 (SCD2) controls whole-body energy expenditure

BACKGROUND/OBJECTIVES

Stearoyl-CoA desaturase-2 (SCD2) is the main δ9 desaturase expressed in the central nervous system. Because of its potential involvement in controlling whole-body adiposity, we evaluated the expression and function of SCD2 in the hypothalami of mice.

SUBJECTS/METHODS

Male mice of different strains were used in real-time PCR, immunoblot and metabolic experiments. In addition, antisense oligonucleotides and lentiviral vectors were used to reduce and increase the expression of SCD2 in the hypothalamus.

RESULTS

The level of SCD2 in the hypothalamus is similar to other regions of the central nervous system and is ~10-fold higher than in any other region of the body. In the arcuate nucleus, SCD2 is expressed in proopiomelanocortin and neuropeptide-Y neurons. Upon high fat feeding, the level of hypothalamic SCD2 increases. Inhibition of hypothalamic SCD2 as accomplished by two distinct approaches, an antisense oligonucleotide or a short-hairpin RNA delivered by a lentivirus, resulted in reduced body mass gain mostly due to increased energy expenditure and increased spontaneous activity. Increasing hypothalamic SCD2 by a lentivirus approach resulted in no change in body mass and food intake.

CONCLUSIONS

Thus, SCD2 is highly expressed in the hypothalami of rodents and its knockdown reduces body mass due to increased whole-body energy expenditure.

Cellular strategies for regulating DNA supercoiling: a single-molecule perspective

Entangling and twisting of cellular DNA (i.e., supercoiling) are problems inherent to the helical structure of double-stranded DNA. Supercoiling affects transcription, DNA replication, and chromosomal segregation. Consequently the cell must fine-tune supercoiling to optimize these key processes. Here, we summarize how supercoiling is generated and review experimental and theoretical insights into supercoil relaxation. We distinguish between the passive dissipation of supercoils by diffusion and the active removal of supercoils by topoisomerase enzymes. We also review single-molecule studies that elucidate the timescales and mechanisms of supercoil removal.

Fast dynamics of supercoiled DNA revealed by single-molecule experiments

The dynamics of supercoiled DNA play an important role in various cellular processes such as transcription and replication that involve DNA supercoiling. We present experiments that enhance our understanding of these dynamics by measuring the intrinsic response of single DNA molecules to sudden changes in tension or torsion. The observed dynamics can be accurately described by quasistatic models, independent of the degree of supercoiling initially present in the molecules. In particular, the dynamics are not affected by the continuous removal of the plectonemes. These results set an upper bound on the hydrodynamic drag opposing plectoneme removal, and thus provide a quantitative baseline for the dynamics of bare DNA.

Measurement of the linking number change in transcribing chromatin

The in vivo-initiated, transcribing simian virus 40 (SV40) minichromosome was analyzed to determine its DNA linking number change, i.e. the difference between the linking number of the minichromosomal DNA and that of relaxed bare DNA. As part of this measurement, the linking number change due to the in vivo-initiated RNA polymerase II was determined, the first time a value for this quantity has been reported. The topological contribution of the polymerase was combined with values determined for constrained and non-constrained linking number contributions from the native transcription complex chromatin to yield the linking number change for the complex. The linking number change of the native non-transcribed SV40 minichromosome was independently determined and was found to be virtually the same as that for the chromatin of the transcription complex. This indicates that there is little difference between the two structures. The plausibility of several current models for the contribution of chromatin structure to transcription regulation is discussed in light of this finding.

Effects of histone acetylation on chromatin topology in vivo

Recently a model for eukaryotic transcriptional activation has been proposed in which histone hyperacetylation causes release of nucleosomal supercoils, and this unconstrained tension in turn stimulates transcription (V. G. Norton, B. S. Imai, P. Yau, and E. M. Bradbury, Cell 57:449-457, 1989; V. G. Norton, K. W. Marvin, P. Yau, and E. M. Bradbury, J. Biol. Chem. 265:19848-19852, 1990). These studies analyzed the effect of histone hyperacetylation on the change in topological linking number which occurs during nucleosome assembly in vitro. We have tested this model by determining the effect of histone hyperacetylation on the linking number change which occurs during assembly in vivo. We find that butyrate treatment of cells infected with simian virus 40 results in hyperacetylation of the histones of the extracted viral minichromosome as expected. However, the change in constrained supercoils of the minichromosome DNA is minimal, a result which is inconsistent with the proposed model. These results indicate that the proposed mechanism of transcriptional activation is unlikely to take place in the cell.

Effects of histone acetylation on chromatin topology in vivo

Recently a model for eukaryotic transcriptional activation has been proposed in which histone hyperacetylation causes release of nucleosomal supercoils, and this unconstrained tension in turn stimulates transcription (V. G. Norton, B. S. Imai, P. Yau, and E. M. Bradbury, Cell 57:449-457, 1989; V. G. Norton, K. W. Marvin, P. Yau, and E. M. Bradbury, J. Biol. Chem. 265:19848-19852, 1990). These studies analyzed the effect of histone hyperacetylation on the change in topological linking number which occurs during nucleosome assembly in vitro. We have tested this model by determining the effect of histone hyperacetylation on the linking number change which occurs during assembly in vivo. We find that butyrate treatment of cells infected with simian virus 40 results in hyperacetylation of the histones of the extracted viral minichromosome as expected. However, the change in constrained supercoils of the minichromosome DNA is minimal, a result which is inconsistent with the proposed model. These results indicate that the proposed mechanism of transcriptional activation is unlikely to take place in the cell.

Regulation of exoprotein expression in Staphylococcus aureus by a locus (sar) distinct from agr

A single insertion of transposon Tn917LTV1 into the chromosome of a Staphylococcus aureus clinical isolate, strain DB, resulted in a pleiotropic effect on the expression of a number of extracellular and cell-wall-associated proteins. Detailed comparison of phenotypes associated with the mutant, 11D2, and the parent, DB, indicated that the chromosomal locus inactivated as a result of transposon mutagenesis differs from the S. aureus accessory gene regulator locus (agr). In particular, the expression of alpha-hemolysin, which is not detectable in Agr- mutants, was enhanced in mutant 11D2, while it remained at a low level in strain DB. Likewise, protease activity was significantly enhanced in 11D2 compared with DB. In addition, most of the cell-bound proteins were expressed at lower levels in the mutant than the parent strain. This pattern is contrary to that found in switching from Agr+ to Agr- phenotypes. Southern blot hybridization with an agr probe indicated that the inactivated chromosomal locus is distinct from agr. Transduction experiments demonstrated that the phenotypes associated with mutant 11D2 could be transferred to the parental strain DB as well as to RN450, an S. aureus strain with a genetic background similar to strain 8325-4. This locus on the S. aureus chromosome, possibly regulatory in nature, has been designated sar for staphylococcal accessory regulator.

Enhancer-activated plasmid transcription complexes contain constrained supercoiling

It has been proposed that transcriptionally active chromatin contains totally unconstrained supercoiling. The results of recent studies have raised the possibility that this topological state is the property of highly transcribed genes. Since the transcription rate of RNA polymerase II genes can be dramatically increased by the presence of an enhancer, we have determined if the transcription complex of an enhancer-activated plasmid contains totally unconstrained supercoils. Following transfection into COS7 cells, the topology of the transcription complex DNA was determined directly by agarose gel electrophoresis. We find that an enhancer-activated plasmid transcription complex is supercoiled, and these supercoils remain following topoisomerase I treatment. Thus the transcribing complexes contain constrained supercoils, and the level of supercoiling suggests a nucleosome-like organization. However, we cannot rule out the possibility that unconstrained supercoils exist in addition to these constrained supercoils in the transcription complex in the cell.

Topological properties of bovine papillomavirus type 1 (BPV-1) DNA in episomal nucleoprotein complexes: a model system for chromatin organization in higher eukaryotes

Sedimentation analysis of isolated episomal bovine papillomavirus type 1 (BPV-1) nucleoprotein complexes in sucrose gradients and subsequent separation of the purified DNA in chloroquine gels revealed different classes of molecules, varying in their degree of superhelicity. Since torsionally stressed DNA favors the adoption of secondary structures, we employed the single-strand-specific S1 nuclease to detect such structural alterations in both naked DNA and native chromatin. Direct examination of nuclease digestion products in chloroquine gels showed that neither the naked DNA nor the BPV-1 nucleoprotein complexes in isolated nuclei were cleaved randomly by the enzyme. Instead, there was a strict dependence on nuclease susceptibility and the degree of supercoiling, strongly suggesting that the structural features detected by S1 nuclease are due to the occurrence of torsionally stressed viral chromatin. Mapping analysis using the indirect end-labeling method demonstrated an S1-nuclease cleavage site adjacent to 20 homopurine residues known to be hypersensitive to S1 attack. Furthermore, direct methylation experiments with viral chromatin in isolated nuclei indicated that only circular, covalently closed nucleoprotein complexes served as substrate, whereas linearized BPV-1 chromatin was not susceptible to exogenously added Hhal methylase. This observation raises the possibility that the modulation of topology in nucleosomally organized DNA might also play a role in eukaryotic DNA methylation.

Computer simulation of DNA supercoiling

Major goals of this research are to comprehend and visualize the detailed three-dimensional arrangements of supercoiled DNA. Attention has been focused in the initial stages on mathematical procedures to generate the spatial coordinates of the B-DNA double helix constrained to specific spatial pathways and on simple energy models of chain conformation. The new treatment of superhelical DNA in terms of parametric curves is an important first step in being able to generate and examine tertiary structure systematically. The location of every residue is implicitly determined by the equation of the closed curve, with the number of computational variables sharply reduced compared to the number required for explicit specification of all chain units. Furthermore, the constraints of ring closure in cyclic chains and/or the end-to-end limitations on constrained open chains are automatically satisfied by the formulations (cubic B-splines and finite Fourier series) chosen in this work. The predicted conformations of elastic DNA do not appear to be tied to either the form of chain representation or the computer simulation method. Significantly, two very different minimization and modeling approaches come to the same structural conclusions. The most stable configurations of the closed circular elastic DNA model are found to be interwound superhelices that are critically dependent on the specified linking number difference. The total elastic energy is proportional to the imposed linking number difference, and beyond the critical linking number difference separating the circular and figure-eight forms, the writhing number of the DNA superhelices is directly proportional to delta Lk. The measured proportionality constant between Wr and delta Lk, however, is somewhat greater than that deduced from experimental observations of plectonemically interwound DNA chains and an assumed structural model. Furthermore, at large delta Lk, the interwound structures appear to curve. The treatment of the DNA double helix as an ideal elastic rod is clearly incorrect. The chain cannot bend with the same ease in all directions. The degree of bending observed in atomic level models is also tied to the angular twist so that the presumed partitioning of bending and twisting components is in error. Furthermore, the local chain bending and twisting are base sequence dependent, with certain residues able to flex more symmetrically than others. The polyelectrolyte character of the DNA is additionally expected to govern the overall folding of the chain and to influence the local secondary structure. The next step in this work is to compare the properties of such "real" DNA with conventional elastic models.(ABSTRACT TRUNCATED AT 400 WORDS)

Topoisomerase I cleavage sites identified and mapped in the chromatin of Dictyostelium ribosomal RNA genes

Sites of an endogenous activity that has the properties of a DNA topoisomerase I have been identified on the palindromic ribosomal RNA genes of the slime mould Dictyostelium discoideum. This was done in vitro, by treating isolated nuclei with sodium dodecyl sulphate, which denatures topoisomerase during its cycle of nicking, strand passing and resealing, and hence reveals the DNA cleavages. It was also done in vivo using the drug camptothecin, which is believed to stabilize the cleavable complex of topoisomerase I plus DNA, hence increasing the chances of cleavage when sodium dodecyl sulphate is subsequently added. The cleavages in vitro and in vivo were mapped by indirect end-labelling. Both treatments cause what appear to be strong double-stranded cleavages at 200 and 2200 base-pairs and at 17 X 10(3) base-pairs upstream from the rRNA transcription start. The cleavage at 200 base-pairs was analysed in greater detail using RNA hybridization probes specific for single DNA strands. The cleavage is in fact composed of three closely spaced nicks on each DNA strand. The DNA sequence at each of the nicks is strongly homologous across 15 base-pairs. Sodium dodecyl sulphate-induced cleavage by eukaryotic topoisomerase I is known to yield enzyme covalently attached to the 3' cut end of the DNA. We show that protein-linked DNA restriction fragments with their 3' ends at the cleavage sites are selectively retarded on denaturing gels, which provides strong evidence that the unusual cluster of cleavages is caused by a topoisomerase I. Additionally, the camptothecin results revealed cleavages not only at the specific upstream sites, but also across the transcribed region. Interestingly, the zone of camptothecin-assisted cleavage does not extend as far at the 3' end of the gene as the zone of endogenous nuclease sensitivity.

Transcription elements and factors of RNA polymerase B promoters of higher eukaryotes

The promoter for eukaryotic genes transcribed by RNA polymerase B can be divided into the TATA box (located at -30) and startsite (+1), the upstream element (situated between -40 and about -110), and the enhancer (no fixed position relative to the startsite). Trans-acting factors, which bind to these elements, have been identified and at least partially purified. The role of the TATA box is to bind factors which focus the transcription machinery to initiate at the startsite. The upstream element and the enhancer somehow modulate this interaction, possibly through direct protein-protein interactions. Another class of transcription factors, typified by viral proteins such as the adenovirus EIA products, do not appear to require binding to a particular DNA sequence to regulate transcription. The latest findings in these various subjects are discussed.

Localization of specific topoisomerase I interactions within the transcribed region of active heat shock genes by using the inhibitor camptothecin

Camptothecin stabilizes the topoisomerase I-DNA covalent intermediate that forms during the relaxation of torsionally strained DNA. By mapping the position of the resultant DNA nicks, we analyzed the distribution of the covalent intermediates formed on heat shock genes in cultured Drosophila melanogaster cells. Topoisomerase I was found to interact with the transcriptionally active genes hsp22, hsp23, hsp26, and hsp28 after heat shock but not with the inactive genes before heat shock. The interaction occurred predominantly within the transcribed region, with specific sites occurring on both the transcribed and nontranscribed strands of the DNA. Little interaction was seen with nontranscribed flanking sequences. Camptothecin only partially inhibited transcription of the hsp28 gene during heat shock, causing a reduced level of transcripts which were nonetheless full length. Topoisomerase I also interacted with the DNA throughout the transcriptionally active hsp83 gene, including an intron, in both heat-shocked and non-heat-shocked cells. The results point to a dynamic set of interactions at the active locus.

Topological characterization of the simian virus 40 transcription complex

We have used sedimentation analysis as well as agarose gel electrophoresis to characterize the topological state of the DNA of the Simian Virus 40 (SV40) transcription complex. We found that the complex DNA contained constrained topological tension, presumably resulting from nucleosome-like structures, but no detectable unconstrained (i.e., relaxable) topological tension. These results contradict previous conclusions that the SV40 transcription complex contains only unconstrained topological tension. Our findings are also the opposite of what has been proposed to be the case for the 5S gene analyzed in Xenopus oocytes. Thus the proposal that expression from the 5S gene is associated with substantial topological tension is not valid for expression from the SV40 late gene.

Localization of specific topoisomerase I interactions within the transcribed region of active heat shock genes by using the inhibitor camptothecin

Camptothecin stabilizes the topoisomerase I-DNA covalent intermediate that forms during the relaxation of torsionally strained DNA. By mapping the position of the resultant DNA nicks, we analyzed the distribution of the covalent intermediates formed on heat shock genes in cultured Drosophila melanogaster cells. Topoisomerase I was found to interact with the transcriptionally active genes hsp22, hsp23, hsp26, and hsp28 after heat shock but not with the inactive genes before heat shock. The interaction occurred predominantly within the transcribed region, with specific sites occurring on both the transcribed and nontranscribed strands of the DNA. Little interaction was seen with nontranscribed flanking sequences. Camptothecin only partially inhibited transcription of the hsp28 gene during heat shock, causing a reduced level of transcripts which were nonetheless full length. Topoisomerase I also interacted with the DNA throughout the transcriptionally active hsp83 gene, including an intron, in both heat-shocked and non-heat-shocked cells. The results point to a dynamic set of interactions at the active locus.

Mechanisms determining aerobic or anaerobic growth in the facultative anaerobe Salmonella typhimurium

We isolated mutant strains of the facultative anaerobe Salmonella typhimurium that grow either aerobically or anaerobically. Strict anaerobic mutants contained a defective DNA topoisomerase I gene (topI), while strict aerobic mutants contained a defective DNA gyrase subunit A gene (gyrA, also nalA). Topoisomerase I activity was detected in cell-free extracts of strict aerobic mutants but not of strict anaerobic mutant strains, whereas gyrase activity was detected in extracts of strict anaerobic mutants but not of strict aerobic mutants. Furthermore, extracts of wild-type cells, cultured under vigorous aerobic condition, contain topoisomerase I activity but no significant gyrase activity. In contrast, the extracts of anaerobically cultured wild-type cells contain gyrase activity but no significant topoisomerase I activity. Sucrose gradient centrifugation with ethidium bromide showed that chromosomal DNA in strict aerobic mutants and aerobically grown wild-type cells was relaxed, while the chromosomal DNA of strict anaerobic mutants and anaerobically grown wild-type cells was more supercoiled. Aerobic cultures of wild type and strict aerobic mutants produced both superoxide dismutase and catalase, whereas anaerobic cultures of wild type and strict anaerobic mutants did not. These results lead us to conclude that activity of topoisomerase I, associated with relaxation of chromosomal DNA, is necessary for expression of genes required for aerobic growth, whereas activity of gyrase, associated with supercoiling of chromosomal DNA, is necessary for expression of genes required for anaerobic growth.

Torsional stress promotes the DNAase I sensitivity of active genes

Active genes are known to have an altered chromatin structure that is preferentially sensitive to digestion with DNAase I. We find that when chicken red blood cells are incubated in media containing the topoisomerase II inhibitor novobiocin, the preferential DNAase I sensitivity of the active beta-globin genes is reversed in vivo with as little as 20 min of drug treatment. Control experiments suggest that inhibition of a topoisomerase II is responsible for this alteration in active gene conformation. Reversal of DNAase I sensitivity can also be induced in vitro by partial cleavage of the nuclear DNA with staphylococcal nuclease. We propose that the altered structure around active genes is maintained by continuous DNA supercoiling and that in the absence of this superhelical tension active chromatin reverts to a less DNAase I-sensitive ground state.

Chromatin structure of the molecular ends of Oxytricha macronuclear DNA: phased nucleosomes and a telomeric complex

Oxytricha macronuclear DNA exists as approximately 24 X 10(6) gene-sized molecules terminating with a C4A4 repeat. DNA-protein interactions at the ends of bulk macronuclear molecules were probed with micrococcal nuclease and methidiumpropyl-EDTA X Fe(II) (MPE X Fe[II]). The ends were indirectly labeled by hybridizing with (C4A4)2. Alternatively, a novel method using MPE X FE(II) as a probe and directly labeling the 3' ends with terminal transferase was implemented. A terminal complex involving approximately 100 bp with nucleosomes phased inward from the complex was found to be characteristic of most or all of the ends. Analysis of two specific genes confirmed the pattern and showed that the special structure was on both ends of each molecule. We conclude that a DNA-protein complex involving 100 bp and terminating with the C4A4 repeat can be sufficient to provide the fundamental functions of telomeres, allowing linear DNA replication and conferring stability of linear DNA.