The mechanism of cruciform formation in supercoiled DNA: initial opening of central basepairs in salt-dependent extrusion.

There are two alternative pathways by which inverted repeat sequences in supercoiled DNA molecules may extrude cruciform structures, called C-type and S-type. S-type cruciforms, which form the great majority, are characterised by absolute requirement for cations to promote extrusion, which then proceeds at higher temperatures and with lower activation parameters than for C-type cruciforms. The mechanism proposed for S-type extrusion involves an initial opening of basepairs limited to the centre of the inverted repeat, formation of intra-strand basepairing and a four-way junction, and finally branch migration to the fully extruded cruciform. The model predicts that central sequence changes will be more kinetically significant than those removed from the centre. We have studied the kinetics of cruciform extrusion by a series of inverted repeats related to that of pIRbke8 by either one or two mutations in the symmetric unit. We find that mutations in the central 8 to 10 nucleotides may profoundly affect extrusion rates--the fastest being 2000-fold faster than the slowest, whereas mutations further from the centre affect rates to a much smaller extent, typically up to ten-fold. These data support the proposed mechanism for extrusion via central opening.     

Influence of charge and molecular size on membrane stabilization

We have reported that the antihaemolytic effect of low concentrations of chlorpromazine is decreased after enzymic removal of sialopeptides from red cell membranes, suggesting that an interaction between negatively charged sialic acids and positively charged chlorpromazine is involved in its membrane stabilizing effect. We have now investigated the antihaemolytic action of simpler molecules with different charges Removal of membrane sialopeptides did not affect the membrane stabilizing actions of simple aliphatic mono- or diamines nor of similar aliphatic molecules carrying strong positive or negative charges, where those positively charged were more potent than those with negative charges. It appears, therefore, that membrane stabilizing activity is determined primarily by lipophilicity and secondarily by polarity and that it does not depend on interactions with enzymically accessible sialopeptides on the outer surface of biological membranes.     

Effect of magnesium on cruciform extrusion in supercoiled DNA.

Recently, it was reported that Mg2+greatly facilitates cruciform extrusion in the short palindromes of supercoiled DNA, thereby allowing the formation of cruciform structures in vivo. Because of the potential biological importance of this phenomenon, we undertook a broader study of the effect of Mg2+on a cruciform extrusion in supercoiled DNA. The method of two-dimensional gel electrophoresis was used to detect the cruciform extrusion both in the absence and in the presence of these ions. Our results show that Mg2+shifts the cruciform extrusion in the d(CCC(AT)16GGG) palindrome to a higher, rather than to a lower level of supercoiling. In order to study possible sequence-specific properties of the short palindromes for which the unusual cruciform extrusion in the presence Mg2+was reported, we constructed a plasmid with a longer palindromic region. This region bears the same sequences in the hairpin loops and four-arm junction as the short palindrome, except that the short stems of the hairpins are extended. The extension allowed us to overcome the limitation of our experimental approach which cannot be used for very short palindromes. Our results show that Mg2+also shifts the cruciform extrusion in this palindrome to a higher level of supercoiling. These data suggest that cruciform extrusion in the short palindromes at low supercoiling is highly improbable. We performed a thermodynamic analysis of the effect of Mg2+on cruciform extrusion. The treatment accounted for the effect of Mg2+on both free energy of supercoiling and the free energy of cruciform structure per se. Our analysis showed that although the level of supercoiling required for the cruciform extrusion is not reduced by Mg2+, the ions reduce the free energy of the cruciform structure.     

Helix stability and the mechanism of cruciform extrusion in supercoiled DNA molecules

The kinetic properties of cruciform extrusion in supercoiled DNA molecules fall into two main classes. C-type cruciforms extrude in the absence of added salt, at relatively low temperatures, with large activation energies, while S-type cruciforms exhibit no extrusion in the absence of salt, and maximal rates at 50 mM NaCl, with activation energies about one quarter those of the C-type. These diverse properties are believed to reflect two distinct pathways for the extrusion process, and are determined by the nature of the sequences which form the context of the inverted repeat. C-type kinetics are conferred by A + T rich sequences, implying a role of helix stability in the selection. In this study we have shown that: 1. Helix-destabilising solvents (dimethyl formamide and formamide) facilitate extrusion by normally S-type molecules at low temperatures in the absence of salt. 2. C-type extrusion is strongly suppressed by low concentrations (2-4 microM) distamycin, at which concentrations S-type extrusion is enhanced. 3. Some extrusion occurs in a C-type construct in the presence of 50 mM NaCl. This is increased by addition of 3 microM distamycin, under which conditions extrusion becomes effectively S-type. Thus S-type constructs can behave in a quasi-C-type manner in the presence of helix-destabilising solvents, and C-type extrusion is suppressed by binding a compound which stabilises A + T rich regions of DNA. Helix destabilisation leads to C-type behaviour, while helix stabilisation results in S-type properties. These studies demonstrate the influence of contextual helix stability on the selection of kinetic mechanism of cruciform extrusion.     

Real-time detection of cruciform extrusion by single-molecule DNA nanomanipulation

During cruciform extrusion, a DNA inverted repeat unwinds and forms a four-way junction in which two of the branches consist of hairpin structures obtained by self-pairing of the inverted repeats. Here, we use single-molecule DNA nanomanipulation to monitor in real-time cruciform extrusion and rewinding. This allows us to determine the size of the cruciform to nearly base pair accuracy and its kinetics with second-scale time resolution. We present data obtained with two different inverted repeats, one perfect and one imperfect, and extend single-molecule force spectroscopy to measure the torque dependence of cruciform extrusion and rewinding kinetics. Using mutational analysis and a simple two-state model, we find that in the transition state intermediate only the B-DNA located between the inverted repeats (and corresponding to the unpaired apical loop) is unwound, implying that initial stabilization of the four-way (or Holliday) junction is rate-limiting. We thus find that cruciform extrusion is kinetically regulated by features of the hairpin loop, while rewinding is kinetically regulated by features of the stem. These results provide mechanistic insight into cruciform extrusion and help understand the structural features that determine the relative stability of the cruciform and B-form states.     

Detection of cruciform extrusion in DNA by temperature-gradient gel electrophoresis

Repetitive sequences in DNA molecules, some of which are palindromic, tend to form stable cruciforms. These are frequently located in promoter regions of a specific operon and origin of replication. Temperature gradient gel electrophoresis can be used to distinguish among various supercoiled DNA topoisomers and to ascertain whether or not the cruciform motif has been extruded. In the current study, this technique is implemented for the first time to address the role of temperature in cruciform extrusion from plasmids.     

Influence of complex charge and size on the uptake of 99mTc-diphosphonates in osteogenic tissue

The biodistributions of six chromatographically pure ^99mTc-HEDP complexes have been determined in soft tissues, normal bone and osteogenic lesions (induced with a Walker 256 tumor) in Fisher 344 rats. The physical properties of each ^99mTc-HEDP complex including anionic charge, partial molar volume, molecular weight and spectral characteristics are known; thus allowing structure-activity relationships to be drawn. The results indicate that the smallest, low charged, mononuclear ^99mTc-HEDP complexes have the greatest uptake in bone lesions, and the highest lesion to muscle and lesion to normal bone ratios.     

Influence of DNA sequence and supercoiling on the process of cruciform formation

We have studied some of the effects of DNA sequence and negative superhelicity on the rate of cruciform formation. Replacing the sequence AATT at the center of a perfect 68 base-pair palindromic sequence with the sequence CCCGGG decreases the rate of cruciform formation by a factor of at least 100. The logarithm of the rate constant of cruciform formation was found to increase linearly with linking difference. For the 68 base-pair perfect palindrome in a 4400 base-pair plasmid, each additional negative superhelical turn increased the rate of cruciform formation by a factor of 1.6. These results are consistent with a mechanism in which cruciform formation is initiated by the formation of a single-stranded bubble, 10 base-pairs in length, near the center of the palindromic sequence. In addition, we have examined the effect of introducing an asymmetric insertion into the palindromic sequence.     

The kinetic properties of cruciform extrusion are determined by DNA base-sequence.

The extrusion kinetics of two cruciforms derived from unrelated DNA sequences differ markedly. Kinetic barriers exist for both reactions, necessitating elevated temperatures before extrusion proceeds at measureable speeds, but the dependence upon temperature and ionic strength is quite different for the two sequences. One, the ColE1 inverted repeat, exhibits a remarkably great temperature dependence of reaction rate and is suppressed by moderate amounts of NaCl or MgCl2. In contrast, the other, a synthetic inverted repeat present in pIRbke8, shows more modest temperature dependence and has a requirement for the presence of salt, with optimal concentrations being 50 mM NaCl or 100 microM MgCl2. Under optimal conditions, cruciform extrusion rates are fast (t1/2 less than 60m) at 37 degrees C for both sequences at native superhelix densities. In 50 mM NaCl the pIRbke8 inverted repeat is characterised by an Arrhenius activation energy of 42.4 +/- 3.2 kcal mole -1. The differences in kinetic properties between the two sequences indicate that DNA base sequence is itself an important factor in determining cruciform kinetics, and possibly even in the selection of the mechanistic pathway.     

Flanking AT-rich sequences may lower the activation energy of cruciform extrusion in supercoiled DNA

In the absence of flanking AT-rich segments, cruciform transition energies of DNA palindromic sequences of random base composition are high and mainly dependent upon the base-stacking and -pairing parameters of the palindromic segment. When AT-rich sequences adjoin palindromes, the transition energy of cruciform extrusion is significantly lowered. An inverse relationship exists between the length of the AT-rich stretch and the cruciform transition energy. Long stretches lower the transition energies more than short stretches. At physiological salt and temperature conditions, equilibrium between cruciform extrusion and absorption for the inverted repeat sequences IRS-B and IRS-C of pBR322 derived plasmids is reached in less than five minutes.     

Influence of quaternary cation compound on the size of the Escherichia coli small multidrug resistance protein,EmrE

EmrE is a member of the small multidrug resistance (SMR) protein family in Escherichia coli. It confers resistance to a wide variety of quaternary cation compounds (QCCs) as an efflux transporter driven by the transmembrane proton motive force. We have expressed hexahistidinyl (His₆) – myc epitope tagged EmrE, extracted it from membrane preparations using the detergent n-dodecyl-β-D-maltopyranoside (DDM), and purified it using nickel-affinity chromatography. The size of the EmrE protein, in DDM environment, was then examined in the presence and absence of a range of structurally different QCC ligands that varied in their chemical structure, charge and shape. We used dynamic light scattering and showed that the size and oligomeric state distributions are dependent on the type of QCC. We also followed changes in the Trp fluorescence and determined apparent dissociation constants (K_d). Overall, our in vitro analyses of epitope tagged EmrE demonstrated subtle but significant differences in the size distributions with different QCC ligands bound.     

Dynamics of cruciform extrusion in supercoiled DNA: use of a synthetic inverted repeat to study conformational populations.

An inverted repeat has been created in a plasmid by ligation of two 13 nucleotide synthetic oligonucleotides into the cloning vector pAT153. The resulting recombinant plasmid, pIRbke8, is hypersensitive to cleavage by the single-strand-specific nuclease S1, and to modification by the single-strand-selective reagent bromoacetaldehyde, when the plasmid is negatively supercoiled. The new inverted repeat is a stronger S1 site than those derived from pBR322, but, in contrast to the ColE1 and phi X174 RF inverted repeats, these repeats share a similar temperature dependence. The kinetics of EcoRI cleavage at the centre of the synthetic inverted repeat have been studied in supercoiled and linear molecules. It is found that in the supercoiled molecule this target is not refractory to EcoRI cleavage to an extent which is greater than the resolution of the experiment. We conclude that in this molecule the cruciform is in a dynamic equilibrium with the regular duplex, in which the cruciform constitutes a relatively small subpopulation of conformational species.     

Long-range structural effects in supercoiled DNA: statistical thermodynamics reveals a correlation between calculated cooperative melting and contextual influence on cruciform extrusion

We have previously described [K. M. Sullivan and D. M. J. Lilley (1986) Cell 47, 817-827] a set of sequences, called C-type inducing sequences, which cause cruciform extrusion by adjacent inverted repeats to occur by an abnormal kinetic pathway involving a large denatured region of DNA. In this paper we apply statistical thermodynamic DNA helix melting theory to these sequences. We find a marked correlation between the ability of sequences to confer C-type cruciform character experimentally and their calculated propensity to undergo cooperative melting, and no exceptions have been found. The correlations are both qualitative and quantitative. Thus the ColE1 flanking sequences behave as single melting units, while the DNA of the S-type plasmid pIRbke8 exhibits no propensity to melt in the region of the bke cruciform. The results of the calculations are also fully consistent with the following experimental observations: 1. the ability of the isolated colL and colR fragments of the ColE1 flanking sequences, as well as the short sequence col30, to confer C-type character; 2. C-type induction by an A + T rich Drosophila sequence; 3. low-temperature cruciform extrusion by an (AT)34 sequence; 4. the effect of changing sequences at a site 90 base pairs (bp) removed from the inverted repeat; 5. the effects of systematic deletion of the colL sequence; and 6. the effects of insertion of various sequences in between the colL sequence and the xke inverted repeat. These studies show that telestability effects on thermal denaturation as predicted from equilibrium helix melting theory of linear DNA molecules may explain all the features that are revealed by studying the extrusion of cruciforms in circular DNA molecules subjected to superhelical stress.     

Self-catalyzed site-specific depurination of G residues mediated by cruciform extrusion in closed circular DNA plasmids

A major variety of "spontaneous" genomic damage is endogenous generation of apurinic sites. Depurination rates vary widely across genomes, occurring with higher frequency at "depurination hot spots." Recently, we discovered a site-specific self-catalyzed depurinating activity in short (14-18 nucleotides) DNA stem-loop-forming sequences with a 5'-G(T/A)GG-3' loop and T·A or G·C as the first base pair at the base of the loop; the 5'-G residue of the loop self-depurinates at least 10(5)-fold faster than random "spontaneous" depurination at pH 5. Formation of the catalytic intermediate for self-depurination in double-stranded DNA requires a stem-loop to extrude as part of a cruciform. In this study, evidence is presented for self-catalyzed depurination mediated by cruciform formation in plasmid DNA in vitro. Cruciform extrusion was confirmed, and its extent was quantitated by digestion of the plasmid with single strand-specific mung bean endonuclease, followed by restriction digestion and sequencing of resulting mung bean-generated fragments. Appearance of the apurinic site in the self-depurinating stem-loop was confirmed by digestion of plasmid DNA with apurinic endonuclease IV, followed by primer extension and/or PCR amplification to detect the endonuclease-generated strand break and identify its location. Self-catalyzed depurination was contingent on the plasmid being supercoiled and was not observed in linearized plasmids, consistent with the presence of the extruded cruciform in the supercoiled plasmid and not in the linear one. These results indicate that self-catalyzed depurination is not unique to single-stranded DNA; rather, it can occur in stem-loop structures extruding from double-stranded DNA and therefore could, in principle, occur in vivo.     

Influence of charge and size of terminal amino-acid residues on local conformational states and shape of alanine-based peptides

We present results of conformational studies by Circular dichroism and NMR spectroscopy, differential scanning calorimetry, and molecular dynamics, of three alanine-based peptides: Ac-KK-(A)(7)-KK-NH(2) (KAK), Ac-OO-(A)(7)-DD-NH(2) (OAD), and Ac-KK-(A)(7)-EE-NH(2) (KAE), where A, K, O, D, and E, denote alanine, lysine, ornithine, aspartic acid, and glutamic acid residues, respectively. For OAD and KAE, canonical MD simulations with time-averaged NMR-derived restraints demonstrate the presence of an ensemble of structures with a variety of conformational states (polyproline II, alpha-helical, alpha', and extended, turn); for KAK the conformational states are predominantly polyproline II and extended. The OAD peptide exhibits a bent shape with its ends close to each other, whereas KAK and KAE are more extended. The bent shape was also observed in our earlier study of the Ac-XX-(A)(7)-OO-NH(2) (XAO) peptide, where X denotes the diaminobutyric acid residue; therefore, the shape seems to depend on the size of the charged side chains at the ends of the alanine sequence and not on their kind. This suggests that the bent shape of the alanine sequence is formed to enable screening of this nonpolar sequence from the solvent by sufficiently short charged side chains. As in our previous study of the XAO peptide, no long polyproline II segments were observed.     

Monovalent cation size and DNA conformational stability

The effect of monovalent cations on the thermal stability of a small model DNA hairpin has been measured by capillary electrophoresis, using an oligomer with 16 thymine residues as an unstructured control. The melting temperature of the model hairpin increases approximately linearly with the logarithm of increasing cation concentration in solutions containing Na(+), K(+), Li(+), NH(4)(+), Tris(+), tetramethylammonium (TMA(+)), or tetraethylammonium (TEA(+)) ions, is approximately independent of cation concentration in solutions containing tetrapropylammonium (TPA(+)) ions, and decreases with the logarithm of increasing cation concentration in solutions containing tetrabutylammonium (TBA(+)) ions. At constant cation concentration, the melting temperature of the DNA model hairpin decreases in the order Li(+) ～ Na(+) ～ K(+) > NH(4)(+) > TMA(+) > Tris(+) > TEA(+) > TPA(+) > TBA(+). Isothermal studies indicate that the decrease in the hairpin melting temperature with increasing cation hydrophobicity is not due to saturable, site-specific binding of the cation to the random coil conformation, but to the concomitant increase in cation size with increasing hydrophobicity. Larger cations are less effective at shielding the charged phosphate residues in B-form DNA because they cannot approach the DNA backbone as closely as smaller cations. By contrast, larger cations are relatively more effective at shielding the phosphate charges in the random coil conformation, where the phosphate-phosphate distance more closely matches cation size. Hydrophobic interactions between alkylammonium ions interacting electrostatically with the phosphate residues in the coil may amplify the effect of cation size on DNA thermal stability.     

Influence of the intracellular and extracellular cation concentration on monovalent cation efflux of resealed human erythrocyte ghosts

Tracer efflux measurements (⁸⁶Rb⁺ and²NaNa⁺) were performed on resealed human erythrocyte ghosts at different intra- and extracellular NaCI concentrations. Using a modified Goldman equation the observed alterations of the rate constants could be explained by taking into account the transmembrane and surface potentials, at constant permeability coefficient . These results emphasize the importance of membrane surface potentials in triggering ion transport across biological membranes.     

Influence of membrane-cortex linkers on the extrusion of membrane tubes

The cell membrane is an inhomogeneous system composed of phospholipids, sterols, carbohydrates, and proteins that can be directly attached to underlying cytoskeleton. The protein linkers between the membrane and the cytoskeleton are believed to have a profound effect on the mechanical properties of the cell membrane and its ability to reshape. Here, we investigate the role of membrane-cortex linkers on the extrusion of membrane tubes using computer simulations and experiments. In simulations, we find that the force for tube extrusion has a nonlinear dependence on the density of membrane-cortex attachments: at a range of low and intermediate linker densities, the force is not significantly influenced by the presence of the membrane-cortex attachments and resembles that of the bare membrane. For large concentrations of linkers, however, the force substantially increases compared with the bare membrane. In both cases, the linkers provided membrane tubes with increased stability against coalescence. We then pulled tubes from HEK cells using optical tweezers for varying expression levels of the membrane-cortex attachment protein Ezrin. In line with simulations, we observed that overexpression of Ezrin led to an increased extrusion force, while Ezrin depletion had a negligible effect on the force. Our results shed light on the importance of local protein rearrangements for membrane reshaping at nanoscopic scales.