Mung bean nuclease cleavage of a dA + dT-rich sequence or an inverted repeat sequence in supercoiled PM2 DNA depends on ionic environment

Competitive superhelical transitions involving cruciform extrusion

A DNA molecule under negative superhelical stress becomes susceptible to transitions to alternate structures. The accessible alternate conformations depend on base sequence and compete for occupancy. We have developed a method to calculate equilibrium distributions among the states available to such systems, as well as their average thermodynamic properties. Here we extend this approach to include superhelical cruciform extrusion at both perfect and imperfect inverted repeat (IR) sequences. We find that short IRs do not extrude cruciforms, even in the absence of competition. But as the length of an IR increases, its extrusion can come to dominate both strand separation and B-Z transitions. Although many IRs are present in human genomic DNA, we find that extrusion-susceptible ones occur infrequently. Moreover, their avoidance of transcription start sites in eukaryotes suggests that cruciform formation is rarely involved in mechanisms of gene regulation. We examine a set of clinically important chromosomal translocation breakpoints that occur at long IRs, whose rearrangement has been proposed to be driven by cruciform extrusion. Our results show that the susceptibilities of these IRs to cruciform formation correspond closely with their observed translocation frequencies.

Theoretical analysis of competing conformational transitions in superhelical DNA

We develop a statistical mechanical model to analyze the competitive behavior of transitions to multiple alternate conformations in a negatively supercoiled DNA molecule of kilobase length and specified base sequence. Since DNA superhelicity topologically couples together the transition behaviors of all base pairs, a unified model is required to analyze all the transitions to which the DNA sequence is susceptible. Here we present a first model of this type. Our numerical approach generalizes the strategy of previously developed algorithms, which studied superhelical transitions to a single alternate conformation. We apply our multi-state model to study the competition between strand separation and B-Z transitions in superhelical DNA. We show this competition to be highly sensitive to temperature and to the imposed level of supercoiling. Comparison of our results with experimental data shows that, when the energetics appropriate to the experimental conditions are used, the competition between these two transitions is accurately captured by our algorithm. We analyze the superhelical competition between B-Z transitions and denaturation around the c-myc oncogene, where both transitions are known to occur when this gene is transcribing. We apply our model to explore the correlation between stress-induced transitions and transcriptional activity in various organisms. In higher eukaryotes we find a strong enhancement of Z-forming regions immediately 5′ to their transcription start sites (TSS), and a depletion of strand separating sites in a broad region around the TSS. The opposite patterns occur around transcript end locations. We also show that susceptibility to each type of transition is different in eukaryotes and prokaryotes. By analyzing a set of untranscribed pseudogenes we show that the Z-susceptibility just downstream of the TSS is not preserved, suggesting it may be under selection pressure.

The stresses imposed on DNA within organisms can drive the molecule from its standard B-form double-helical structure into other conformations at susceptible sites within the sequence. We present a theoretical method to calculate this transition behavior due to stresses induced by supercoiling. We also develop a numerical algorithm that calculates the transformation probability of each base pair in a user-specified DNA sequence under stress. We apply this method to analyze the competition between transitions to strand separated and left-handed Z-form structures. We find that these two conformations are both competitive under physiological environmental conditions, and that this competition is especially sensitive to temperature. By comparing its results to experimental data we also show that the algorithm properly describes the competition between melting and Z-DNA formation. Analysis of large gene sets from various organisms shows a correlation between sites of stress-induced transitions and locations that are involved in regulating gene expression.

Characterization of a periplasmic S1-like nuclease coded by the Mesorhizobium loti symbiosis island

DNA sequences encoding hypothetical proteins homologous to S1 nuclease from Aspergillus oryzae are found in many organisms including fungi, plants, pathogenic bacteria, and eukaryotic parasites. One of these is the M1 nuclease of Mesorhizobium loti which we demonstrate herein to be an enzymatically active, soluble, and stable S1 homolog that lacks the extensive mannosyl-glycosylation found in eukaryotic S1 nuclease homologs. We have expressed the cloned M1 protein in M. loti and purified recombinant native M1 to near homogeneity and have also isolated a homogeneous M1 carboxy-terminal hexahistidine tag fusion protein. Mass spectrometry and N-terminal Edman degradation sequencing confirmed the protein identity. The enzymatic properties of the purified M1 nuclease are similar to those of S1. At acidic pH M1 is 25 times more active on single-stranded DNA than on double-stranded DNA and 3 times more active on single-stranded DNA than on single-stranded RNA. At neutral pH the RNase activity of M1 exceeds the DNase activity. M1 nicks supercoiled RF-I plasmid DNA and rapidly cuts the phosphodiester bond across from the nick in the resultant relaxed RF-II plasmid DNA. Therefore, M1 represents an active bacterial S1 homolog in spite of great sequence divergence. The biochemical characterization of M1 nuclease supports our sequence alignment that reveals the minimal 21 amino acid residues that are necessarily conserved for the structure and functions of this enzyme family. The ability of M1 to degrade RNA at neutral pH implies previously unappreciated roles of these nucleases in biological systems.

Enzymatic mutation detection technologies

Mutation is as necessary for life as fidelity is in DNA replication. The study of mutations reveals the normal functions of genes, messages, proteins, the causes of many diseases, and the variability of responses among individuals. Indeed, recent mutations that have not yet become polymorphisms are often deleterious and pertinent to the disease history of afflicted individuals. This review discusses the principles behind a variety of methods for the detection of mutations and factors that should be considered in future methods design. One enzymatic approach in particular using orthologs of the CEL I nuclease that show high specificity for all mismatches, appears to be easy and robust. Further developments of this and other methods will allow mutation detection to become an integral component of individualized medicine.

Stability and strand asymmetry in the non-B DNA structure at the bcl-2 major breakpoint region

The t(14;18) translocation involving the Ig heavy chain locus and the BCL-2 gene is the single most common chromosomal translocation in human cancer. Recently we reported in vitro and in vivo chemical probing data indicating that the 150-bp major breakpoint region (Mbr), which contains three breakage subregions (hotspots) (known as peaks I, II, and III), has single-stranded character and hence a non-B DNA conformation. Although we could document the non-B DNA structure formation at the bcl-2 Mbr, the structural studies were limited to chemical probing. Therefore, in the present study, we used multiple methods including circular dichroism to detect the non-B DNA at the bcl-2 Mbr. We established a new gel shift method to detect the altered structure at neutral pH on shorter DNA fragments containing the bcl-2 Mbr and analyzed the fine structural features. We found that the single-stranded region in the non-B DNA structure observed is stable for days and is asymmetric with respect to the Watson and Crick strands. It could be detected by oligomer probing, a bisulfite modification assay, or a P1 nuclease assay. We provide evidence that two different non-B conformations exist at peak I in addition to the single one observed at peak III. Finally we used mutagenesis and base analogue incorporation to show that the non-B DNA structure formation requires Hoogsteen pairing. These findings place major constraints on the location and nature of the non-B conformations assumed at peaks I and III of the bcl-2 Mbr.

Single-strand-specific nucleases

Single-strand-specific nucleases are multifunctional enzymes and widespread in distribution. Their ability to act selectively on single-stranded nucleic acids and single-stranded regions in double-stranded nucleic acids has led to their extensive application as probes for the structural determination of nucleic acids. Intracellularly, they have been implicated in recombination, repair and replication, whereas extracellular enzymes have a role in nutrition. Although more than 30 single-strand-specific nucleases from various sources have been isolated till now, only a few enzymes (S1 nuclease from Aspergillus oryzae, P1 nuclease from Penicillium citrinum and nucleases from Alteromonas espejiana, Neurospora crassa, Ustilago maydis and mung bean) have been characterized to a significant extent. Recently, some of these enzymes have been cloned, their crystal structures solved and their interactions with different substrates have been established. The detection, purification, characteristics, structure-function correlations, biological role and applications of single-strand-specific nucleases are reviewed.

Purification and protein composition of PM2, the first lipid-containing bacterial virus to be isolated

The marine, icosahedral bacteriophage PM2 was isolated in the late 1960s. It was the first phage for which lipids were firmly demonstrated to be part of the virion structure and it has been classified as the type organism of the Corticoviridae family. The host, Pseudoalteromonas espejiana BAL-31, belongs to a common group of marine bacteria. We developed a purification method producing virions with specific infectivity approximately as high as that of the lipid-containing phages PRD1 and φ6. The sensitivity of the virus to normally used purification media such as those containing sucrose is demonstrated. We also present an alternative host, a pseudoalteromonad, that allows enhanced purification of the virus under reduced salt conditions. We show, using N-terminal amino acid sequencing and comparison with the genomic sequence, that there are at least eight structural proteins in the infectious virus.

The complete genome sequence of PM2, the first lipid-containing bacterial virus To Be isolated

Bacteriophage PM2 was isolated from the Pacific Ocean off the coast of Chile in the late 1960s. It was a new virus type, later classified as Corticoviridae, and also the first bacterial virus for which it was demonstrated that lipids are part of the virion structure. Here we report the determination and analysis of the 10, 079-bp circular dsDNA genome sequence. Noteworthy discoveries are the replication initiation system, which is related to the rolling circle mechanism described for phages such as φX174 and P2, and a 1.2-kb sequence that is similar to the maintenance region of a plasmid found in a marine Pseudoalteromonas sp. strain A28.

Mutation detection using a novel plant endonuclease

We have discovered a useful new reagent for mutation detection, a novel nuclease CEL I from celery. It is specific for DNA distortions and mismatches from pH 6 to 9. Incision is on the 3'-side of the mismatch site in one of the two DNA strands in a heteroduplex. CEL I-like nucleases are found in many plants. We report here that a simple method of enzyme mutation detection using CEL I can efficiently identify mutations and polymorphisms. To illustrate the efficacy of this approach, the exons of the BRCA1 gene were amplified by PCR using primers 5'-labeled with fluorescent dyes of two colors. The PCR products were annealed to form heteroduplexes and subjected to CEL I incision. In GeneScan analyses with a PE Applied Biosystems automated DNA sequencer, two independent incision events, one in each strand, produce truncated fragments of two colors that complement each other to confirm the position of the mismatch. CEL I can detect 100% of the sequence variants present, including deletions, insertions and missense alterations. Our results indicate that CEL I mutation detection is a highly sensitive method for detecting both polymorphisms and disease-causing mutations in DNA fragments as long as 1120 bp in length.

TTA.TAA triplet repeats in plasmids form a non-H bonded structure

CTG.CAG, CGG.CCG, and AAG.CTT triplet repeats proximal to or in disease genes expand by a non-Mendelian genetic process to cause several human hereditary syndromes. As part of our physical, biological, and genetic studies on the 10 possible triplet repeats, we discovered that the TTA.TAA repeat, isolated from the upstream region of the variant surface glycoprotein gene of Trypanosoma brucei, shows a propensity to adopt a non-H bonded structure under appropriate conditions. The other nine triplet repeat sequences do not exhibit this property. (TTA.TAA)n, where n = 90, 60, 30, and 18, cloned into pUC19 was studied by chemical and enzymatic probes as well as two-dimensional gel electrophoretic analyses under a variety of conditions. The helix opening was observed for all four inserts in supercoiled plasmids as a function of temperature, pH, metal ions, and buffer conditions using OsO4, diethyl pyrocarbonate, and chloroacetaldehyde probes. This unusual property of the TTA.TAA repeat suggests that it plays a different role from the other nine triplet repeats in gene expression.

Targeted melting and binding of a DNA regulatory element by a transactivator of c-myc

A far upstream element (FUSE) of c-myc stimulates promoter activity when bound by a newly identified trans-acting protein, which is expressed in cycling cells. Since FUSE binding protein (FBP) binds only the noncoding strand (NCS) of its regulatory element in a sequence-specific manner, and not double-stranded (ds) DNA, formation of the protein DNA complex in vivo first requires unwinding of the DNA helix. In this report, we show evidence that FBP forces strand separation of short stretches of linear dsDNA. Because FUSE is contained within a region of helical instability that is partially unwound in negatively supercoiled DNA, it is a target for more extensive duplex strand separation by FBP, which first exposes and then selectively binds its NCS cognate sequence. In contrast, other single-stranded DNA binding proteins (SSBs) do not demonstrate this FUSE targeting activity. The novel linkage of regional dsDNA melting with cis-element binding by a transcriptional activator has broad implications in the regulation of eukaryotic gene expression.

Easily unwound DNA sequences and hairpin structures in the Epstein-Barr virus origin of plasmid replication

The Epstein-Barr virus (EBV) origin of plasmid replication (oriP) includes two known cis-acting components, the dyad symmetry region and the family of repeats. We used P1 nuclease, a single-strand-specific endonuclease, to probe EBV oriP for DNA sequences that are intrinsically easy to unwind on a negatively supercoiled plasmid. Selective nuclease hypersensitivity was detected in the family of repeats on an oriP-containing plasmid and in the dyad symmetry region on a plasmid that lacks the family of repeats, indicating that the DNA in both cis-acting components is intrinsically easy to unwind. The hierarchy of nuclease hypersensitivity indicates that the family of repeats is more easily unwound than the dyad symmetry region, consistent with the hierarchy of helical stability predicted by computer analysis of the DNA sequence. A specific subset of the family of repeats is nuclease hypersensitive, and the DNA structure deduced from nucleotide-level analysis of the P1 nuclease nicks is a cruciform near a single-stranded bubble. The dyad symmetry region unwinds to form a broad single-stranded bubble containing hairpins in the 65-bp dyad sequence. We propose that the intrinsic ease of unwinding the dyad symmetry region, the actual origin of DNA replication, is an important component in the mechanism of initiation.

DNA helical stability accounts for mutational defects in a yeast replication origin

Earlier studies on the H4 autonomously replicating sequence (ARS) identified a DNA unwinding element (DUE), a required sequence that is hypersensitive to single-strand-specific nucleases and serves to facilitate origin unwinding. Here we demonstrate that a DUE can be identified in the C2G1 ARS, a chromosomal replication origin, by using a computer program that calculates DNA helical stability from the base sequence. The helical stability minima correctly predict the location and hierarchy of the nuclease-hypersensitive sites in a C2G1 ARS plasmid. Nucleotide-level mapping shows that the nuclease-hypersensitive site at the ARS spans a 100-base-pair sequence in the required 3'-flanking region. Mutations that stabilize the DNA helix in the broad 3'-flanking region reduce or abolish ARS-mediated plasmid replication, indicating that helical instability is required for origin function. The level of helical instability is quantitatively related to the replication efficiency of the ARS mutants. Multiple copies of either a consensus-related sequence present in the C2G1 ARS or the consensus sequence itself in synthetic ARS elements contribute to DNA helical instability. Our findings indicate that a DUE is a conserved component of the C2G1 ARS and is a major determinant of replication origin activity.

Purification and properties of nuclease SP

Single-strand-specific nucleases are a diverse and important group of enzymes that are able to cleave a variety of DNA structures present in duplex molecules. Nuclease SP, an enzyme from spinach, has been purified to apparent homogeneity, allowing for the unambiguous characterization of a number of its physical properties as well as its DNA strand cleavage specificities. The effects of ionic strength, pH, divalent metal cations, and temperature on nuclease SP activity have been examined in detail. Nuclease SP was found to be quite thermostable and could be stimulated by Co2+. In addition, the cleavage of UV-damaged and undamaged supercoiled plasmid substrates under a variety of conditions suggests that at least two types of structures are recognized and processed by nuclease SP: UV photoproduct-induced distortions and unwound "nuclease hypersensitive sites". These studies indicate that nuclease SP is functionally related to other single-strand-specific nucleases and is a potential enzymatic tool for probing and manipulating various types of DNA structures.

Local supercoil-stabilized DNA structures

The DNA double helix exhibits local sequence-dependent polymorphism at the level of the single base pair and dinucleotide step. Curvature of the DNA molecule occurs in DNA regions with a specific type of nucleotide sequence periodicities. Negative supercoiling induces in vitro local nucleotide sequence-dependent DNA structures such as cruciforms, left-handed DNA, multistranded structures, etc. Techniques based on chemical probes have been proposed that make it possible to study DNA local structures in cells. Recent results suggest that the local DNA structures observed in vitro exist in the cell, but their occurrence and structural details are dependent on the DNA superhelical density in the cell and can be related to some cellular processes.

Paranemic structures of DNA and their role in DNA unwinding

A DNA structure is defined as paranemic if the participating strands can be separated without mutual rotation of the opposite strands. The experimental methods employed to detect paranemic, unwound, DNA regions is described, including probing by single-strand specific nucleases (SNN), conformation-specific chemical probes, topoisomer analysis, NMR, and other physical methods. The available evidence for the following paranemic structures is surveyed: single-stranded DNA, slippage structures, cruciforms, alternating B-Z regions, triplexes (H-DNA), paranemic duplexes and RNA, protein-stabilized paranemic DNA. The problem of DNA unwinding during gene copying processes is analyzed; the possibility that extended paranemic DNA regions are transiently formed during replication, transcription, and recombination is considered, and the evidence supporting the participation of paranemic DNA forms in genes committed to or undergoing copying processes is summarized.

Hypersensitive mung bean nuclease cleavage sites in Plasmodium knowlesi DNA

Nucleotide sequences of Plasmodium knowlesi DNA that are cleaved by mung bean nuclease (Mbn) at low enzyme concentration (0.2 units enzyme per micrograms DNA) are listed. They are tandemly repeated purine/pyrimidine (RpY) stretches of DNA with (ApT) dimers predominating. Most cut sites are within almost 100% RpY tracts. The enzyme cleaves at many points within the RpY stretch and usually hydrolyzes the 5'-ApT-3' linkage. These alternating RpY target sites are flanked by homopurine and homopyrimidine stretches. At least one Mbn target site lies next to an in vivo transcribed region.

The DNA unwinding element: a novel, cis-acting component that facilitates opening of the Escherichia coli replication origin

We have discovered that DNA supercoiling, in the absence of replication proteins, induces localized unwinding in the Escherichia coli replication origin (oriC) at the same sequence opened by the dnaA initiator protein. The DNA helix at the tandemly repeated, 13mer sequence is thermodynamically unstable, as evidenced by hypersensitivity to single-strand-specific nuclease in a negatively supercoiled plasmid, and demonstrated by stable DNA unwinding seen after two-dimensional gel electrophoresis of topoisomers. A replication-defective oriC mutant lacking the leftmost 13mer shows no nuclease hypersensitivity in two remaining 13mers and no detectable DNA unwinding on two-dimensional gels. The replication defect in the oriC mutant can be corrected by inserting a dissimilar DNA sequence with reduced helical stability in place of the leftmost 13mer. Thus, the helical instability of the leftmost 13mer, not the specific 13mer sequence, is essential for origin function. The rightmost 13mer exhibits helical instability but differs from the leftmost 13mer in its strict sequence conservation among related bacterial origins. The repeated 13mer region appears to serve two overlapping functions: protein recognition and helical instability. We propose that the cis-acting sequence whose helical instability is required for origin function be called the DNA unwinding element (DUE).

Plasticity of DNA conformation around the Drosophila melanogaster alcohol dehydrogenase gene under torsional stress

Genomic DNA of eukaryotes is thought to be organized into multiple topological domains whose conformation can be independently regulated by torsional stress. We have demonstrated the formation of altered DNA structures around the Drosophila melanogaster alcohol dehydrogenase (Adh) gene by sensitivity to endonucleases and by binding single-strand binding (SSB) protein. Several altered DNA structures were detected only on torsionally stressed DNA at specific sites. Some corresponded to the two initiation cap sites and the poly(A) addition sites and others were found in the 5'-flanking regions of both the adult and larval cap sites and in the 3'-flanking region of the Adh gene. In particular, the 5'-flanking regions both exhibited a plasticity of DNA conformation according to the strength of torsional stress and the concentration of Mg2+. SSB protein bound preferentially to the non-coding regions of the Adh gene only on torsionally stressed DNA and not on relaxed or linear DNA. The observed binding preference appeared to correspond to the thermodynamic stability of the base-pairs involved. These results suggest that DNA conformation is specifically organized around the Adh gene for gene function. The plasticity of DNA may play a role in the regulation of transcriptional activation.

Stable DNA unwinding, not "breathing," accounts for single-strand-specific nuclease hypersensitivity of specific A+T-rich sequences

A long A+T-rich sequence in supercoiled pBR322 DNA is hypersensitive to single-strand-specific nucleases at 37 degrees C but not at reduced temperature. The basis for the nuclease hypersensitivity is stable DNA unwinding as revealed by (i) the same temperature dependence for hypersensitivity and for stable unwinding of plasmid topoisomers after two-dimensional gel electrophoresis, (ii) preferential nuclease digestion of stably unwound topoisomers, and (iii) quantitative nicking of stably unwound topoisomers in the A+T-rich region. Nuclease hypersensitivity of A+T-rich sequences is hierarchical, and either deletion of the primary site or a sufficient increase in the free energy of supercoiling leads to enhanced nicking at an alternative A+T-rich site. The hierarchy of nuclease hypersensitivity reflects a hierarchy in the free energy required for unwinding naturally occurring sequences in supercoiled DNA. This finding, along with the known hypersensitivity of replication origins and transcriptional regulatory regions, has important implications for using single-strand-specific nucleases in DNA structure-function studies.

Sensitivity of intergenic regions of yeast mitochondrial DNA to single-strand-specific nucleases

The reactivity of mitochondrial DNA (mtDNA) sequences from Torulopsis glabrata and Saccharomyces cerevisiae towards single-strand-specific nucleases has been examined. AT-rich stretches located in intergenic sequences from both yeasts were cleaved by nucleases when the sequences were contained in supercoiled plasmid DNA. In particular ori/rep sequences from the mtDNA of S. cerevisiae were shown to be sensitive to the single-strand-specific nucleases. The locations of the sensitive sites were related to the organisation of the sequence domains of ori/rep and the superhelicity of the DNA, as well as the presence of particular sequences. It is proposed that distortions of the DNA duplex could be generated in mtDNA molecules in vivo and that these distortions may provide a substrate for enzymes involved in transmission, recombination and/or transcription of mtDNA.

Binding of BAL 31 RNA polymerase to PM2 DNA as determined by electron microscopy and protection against restriction endonuclease cleavage

Specific binding sites of BAL 31 RNA polymerase on PM2 DNA have been mapped by protection against HincII and HindIII cleavage and by observation of enzyme-DNA complexes by electron microscopy. Nine specific binding sites were observed at map units 0.19, 0.20, 0.28, 0.54, 0.63, 0.65, 0.71, 0.72, and 0.75 by the first method. All these sites were confirmed by electron microscopy which, in addition, revealed another site at 0.05 map unit. Published nucleotide sequences of the region surrounding sites at 0.71 and 0.75 map units show the presence of consensus sequences for procaryotic promoters.

Mung bean nuclease exhibits a generalized gene-excision activity upon purified Plasmodium falciparum genomic DNA

A novel set of reaction conditions for mung bean nuclease has been described in which Plasmodium genes were specifically excised as intact fragments from purified DNA. We have now determined that under the new conditions mung bean nuclease cleaves precisely at sites outside of the coding region of every P. falciparum gene for which the extent of the protein coding region in genomic DNA is known. We conclude that this enzyme activity is probably a general one for P. falciparum genes. Introns are not specifically cleaved, although one gene contained a cleavage site within an intron. There is no direct relationship between dA.dT-richness and sites of cleavage under these conditions. Also contrary to the expectations of a model based on cleavage at denaturation bubbles, there was no general relationship between the concentration of the DNA denaturant, formamide, and the size of the resulting gene-containing fragments. Thus, the data strongly suggest the involvement of an altered DNA structure near gene boundaries in determining the recognition sites for this enzyme activity.

Supercoiling response of E. coli promoters with different spacer lengths

The effect of negative supercoiling on a series of synthetic Escherichia coli promoters has been investigated. These promoters carry perfect consensus sequences at the -35 and -10 regions, but with different spacer lengths (Aoyama, T. et al. (1983) Nucleic Acids Res. 11, 5855-5864). Topoisomeric plasmids carrying these synthetic promoters were constructed, and their activities were compared by detecting in vitro transcripts with the probe-hybridization method. In the relaxed state, the one with 17 basepairs (bp) spacing showed the highest activity, and the activity steeply decreased both sides of the optimal spacing. Similar results have been observed by run-off transcription. By introducing negative superhelicity, the 17 bp spacing promoter showed a relatively little response to supercoiling. In contrast, the activities of those with 16 and 18 bp spacings were markedly stimulated by supercoiling, with the mean, negative superhelical density (-sigma) which gave the maximum activity being about the same for the 16-18 bp spacing promoters (-sigma = 0.03 to 0.04). The promoter with 19 bp spacing, which showed no activity in the relaxed state, exhibited a significant activity at higher superhelicities (-sigma = 0.06). Even the 20 bp spacing promoter showed some activity by increasing superhelicity, while the 15 bp spacing promoter did not. On the basis of these observations, possible mechanisms by which negative supercoiling of DNA stimulates the protomer activity are discussed.

The ease of DNA unwinding as a determinant of initiation at yeast replication origins

We have localized the DNA sequence that facilitates unwinding of a yeast replication origin, the H4 ARS. The readily unwound sequence lies adjacent to the previously characterized consensus core sequence of the ARS. Unwinding is detected through the formation of a single-strand-specific nuclease hypersensitive site in H4 ARS mutant derivatives present on supercoiled plasmids. Linker-scanning and linker-deletion derivatives exhibit wild-type nuclease hypersensitivity and ARS function, while large external deletions reduce or eliminate nuclease detectable unwinding and origin function. ARS unwinding and origin function can be rescued in the deletion mutants by inserting a biologically unrelated sequence with DNA unwinding properties similar to a functional ARS. The data clarify the nature of DNA sequence requirements in the ARS by suggesting that small substitutions, insertions, and deletions are tolerated in the region flanking the consensus core sequence because they do not significantly alter the unwinding properties of the region.

Yeast regulatory sequences preferentially adopt a non-B conformation in supercoiled DNA

Mung bean nuclease was used to probe for DNA unwinding in torsionally-stressed chimeric plasmids containing two micron plasmid sequences and the yeast LEU2 gene in a pBR322 vector. The yeast sequences are cleaved at only two sites, both of which map to regulatory regions: (1) the autonomously replicating sequence (ARS), an origin of DNA replication, of the two micron plasmid and (2) the transcription terminator region of the LEU2 gene. Nucleotide level analysis of the nuclease cleavage pattern shows that an A + T-rich structure, distinct from other non-B DNA conformations, is recognized. A computer analysis reveals that A + T content alone is not sufficient to explain the preferential occurrence of the A + T-rich structure in the ARS over other sequences of equal A + T content. The A + T-rich structure detected in the ARS maps to sequences required for DNA replication. Our findings demonstrate the DNA conformational flexibility of certain yeast regulatory regions and provide support for the hypothesis that the A + T-rich sequence in the ARS plays a role in DNA unwinding during the initiation of DNA replication.

Altered DNA conformations in the gene regulatory region of torsionally-stressed SV40 DNA

We used mung bean nuclease to probe the SV40 genome for DNA unwinding and unpairing. Cleavage occurred at a limited number of specific sites in supercoiled, but not relaxed DNA. The number and location of cleavage sites depended upon Mg2+ concentration. Without Mg2+, cutting occurred mainly in one early denaturation region located 3' to the t antigen gene and within the T antigen gene intron. With Mg2+, cleavage occurred at a number of alternative sites in the genome. Certain Mg2+ concentrations favored cleavage in the gene regulatory region. These cleavages were mapped at single nucleotide resolution and occurred in both transcriptional enhancers and upstream from the start of major late gene transcription. The cleavages occurred between 5 bp inverted repeat sequences, consistent with the recognition of unusually small cruciform structures.

Specific cleavage of kinetoplast minicircle DNA from Leishmania tarentolae by mung bean nuclease and identification of several additional minicircle sequence classes

Multiple sequence classes of kinetoplast minicircle DNA from Leishmania tarentolae were cleaved by mung bean nuclease in the presence of formamide, yielding unit length linear molecules which retained the anomalous electrophoretic mobility in acrylamide characteristic of minicircle DNA. No specific cleavage site sequence common to all minicircle sequence classes was apparent, although the main region of nuclease cleavage was localized approximately 350 bp from the unique SmaI restriction site of the conserved region found in all minicircle sequence classes. Covalent closure of the minicircle substrate was not a requirement for cleavage, as linearized network-derived or cloned minicircles were also cleaved by mung bean nuclease at similar locations. The partial sequences of several new minicircle sequence classes released from the network by mung bean nuclease are also reported.

Nuclease recognition of an alternating structure in a d(AT)14 plasmid insert

The nuclease reactivity and specificity of a cloned tract of poly X (dA-dT) X poly(dA-dT) has been explored. Digestion with DNAse I, Mung Bean nuclease, S1 nuclease, DNAse II, and copper (1,10-phenanthroline)2 on a 256 base pair restriction fragment containing d(AT)14A revealed a dinucleotide repeat structure for the alternating sequence. Furthermore, conditions which wind or unwind the linear DNA had little effect on the reactivity of the AT insert. These preferred cleavages offer insights to structural alterations within the DNA helix which differ from A, B, or Z-DNA. Nucleation into flanking sequences by this structural alteration was not observed.

Altered DNA conformations detected by mung bean nuclease occur in promoter and terminator regions of supercoiled pBR322 DNA

Mung bean nuclease was used to probe for recognizable DNA unwinding and unpairing in the plasmid pBR322. In negatively supercoiled DNA, but not relaxed DNA, cleavages occurred preferentially in non-coding regions of the genome. The types of nucleotide sequences cleaved and which non-coding regions were cleaved depended upon environmental conditions. At 37 degrees C, cleavages occurred in an 84 bp A+T-rich sequence in the terminator region of the ampicillin-resistance gene. Recognition is likely based on a novel DNA conformation which occurs in the longest, most dA+dT-rich region of pBR322. In the presence of 1 mM Mg2+, cleavages occurred in inverted repeated sequences in the promoter regions of the RNA primer for DNA replication and ampicillin- and tetracycline-resistance genes as well as the terminator of RNA-1. Potential loops of hairpin (cruciform) structures were cleaved. At 27 degrees C, cleavages occurred near a promoter activated by cAMP receptor protein in vitro and in the 3' non-coding region of the tetracycline-resistance gene. Thus, in supercoiled pBR322 DNA, recognizable DNA unwinding and unpairing occurs preferentially in regulatory regions for transcription and DNA replication.