Possible molecular detent in the DNA structure at regulatory sequences

Invariant and variable base stacking geometries in B-DNA and A-DNA

We calculated the interatomic distances between all couples of non-hydrogen atoms belonging to the neighboring Watson-Crick base pairs in the available crystal structures of DNA. Their standard deviations revealed remarkably large differences in the variability of the base stacking geometries of the particular steps. In line with experimental studies in solution, (CpA)-(TpG) and (TpA).(TpA) were identified as the most variable or flexible steps in the crystal structures of B-DNA. On the other hand, base stacking geometries of the (ApT).(ApT) steps were the most invariant, which was very surprising because all three steps composed only of C and G were much more flexible. This finding suggests that conformational stability of DNA and the rigidity have different origins. Furthermore, the nucleotide sequence dependence of the flexibility was almost reversed in A-DNA because the most flexible steps in B-DNA were the least flexible in A-DNA. The most invariant steps of B-DNA were variable in A-DNA. The (ApT).(ApT) step was a notable exception to this rule because it belonged to the most rigid steps in both B-DNA and A-DNA. The present results are fully consistent with the properties that poly(dA-dT).poly(dA-dT), poly(dA).poly(dT), poly(dAdC).poly(dG-dT) and poly(dA-dG).poly(dC-dT) exhibit in solution.

Cruciform structures and functions

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

Base-pair opening and spermine binding--B-DNA features displayed in the crystal structure of a gal operon fragment: implications for protein-DNA recognition

A sequence that is represented frequently in functionally important sites involving protein-DNA interactions is GTG/CAC, suggesting that the trimer may play a role in regulatory processes. The 2.5 A resolution structure of d(CGGTGG)/d(CCACCG), a part of the interior operator (OI, nucleotides +44 to +49) of the gal operon, co-crystallized with spermine, is described herein. The crystal packing arrangement in this structure is unprecedented in a crystal of B-DNA, revealing a close packing of columns of stacked DNA resembling a 5-stranded twisted wire cable. The final structure contains one hexamer duplex, 17 water molecules and 1.5 spermine molecules per crystallographic asymmetric unit. The hexamer exhibits base-pair opening and shearing at T.A resulting in a novel non-Watson-Crick hydrogen-bonding scheme between adenine and thymine in the GTG region. The ability of this sequence to adopt unusual conformations in its GTG region may be a critical factor conferring sequence selectivity on the binding of Gal repressor. In addition, this is the first conclusive example of a crystal structure of spermine with native B-DNA, providing insight into the mechanics of polyamine-DNA binding, as well as possible explanations for the biological action of spermine.

Sequence dependence of base-pair opening in a DNA dodecamer containing the CACA/GTGT sequence motif

Proton nuclear magnetic resonance spectroscopy is used to characterize the kinetics and energetics of base-pair opening in two self-complementary DNA dodecamer duplexes: [d(CGCACATGTGCG)]2 and [d(CGCAGATCTGCG)]2. The first dodecamer contains two symmetrical CACA/GTGT motifs; in the second dodecamer, each motif is interrupted by a change of the central C.G base pair to a G.C base pair. The opening rates and the equilibrium constants for formation of the open state of each base pair are obtained from the dependence of the imino proton exchange rates on the concentration of ammonia catalyst. The results indicate that the opening rates of the central three base pairs in the CACA/GTGT motif are 3-8-fold larger than the corresponding ones in the CAGA/GTCT sequence. The activation enthalpies and entropies, and the standard enthalpy and entropy changes for formation of the open state, are obtained from the temperature dependence of the opening rates and equilibrium constants, respectively. The results reveal that enthalpy/entropy compensation exists, for all base pairs in both dodecamers, in activation as well as in the equilibria between closed and open states. As a result, the opening rates and equilibrium constants for opening are maintained, in both dodecamers, within a relatively narrow range of values. Nevertheless, large sequence-induced variations are observed for the activation enthalpies and the standard enthalpy changes for opening. The A.T base pair located between the C.G base pairs in the CACA/GTGT motif has a negative enthalpy change for formation of the activated state during opening. This is the first case in which a negative activation enthalpy is observed for opening of a Watson-Crick base pair in DNA.(ABSTRACT TRUNCATED AT 250 WORDS)

Transcriptional enhancer related DNA sequences: anomalous 1H NMR NOE crosspeaks

A dynamic heterogeneity which correlates with the function of the operator DNA in the lactose operon of E. coli. was previously observed (1) as a local minimum in the thymine imino proton T1 centered at a GTG/C-CAC sequence. Since this triplet occurs frequently in DNA regulatory regions, it was proposed that these sequences may be part of a structural element for specific protein interaction. We examine here three additional biologically significant 17 base pair duplexes containing GTG/CAC triplets: (1) a sequence from the mouse heavy chain immunoglobulin enhancer, (2) a sequence from the critical core of the Simian Virus 40 (SV40) enhancer, and (3) a sequence from pBR322 plasmid used as control for experiments with the SV40 DNA sequences. The 1H NMR resonance assignment for nearly all the nonexchangeable protons for both eukaryotic enhancer duplexes with the exception of the H5'/H5" protons was accomplished to use for structural analysis of these duplexes. The data presented show several NOE's associated with the GTG/CAC triplets which suggest structural variation from uniform B-DNA. In addition, anomalous broad crosspeaks for the fixed thymine methyl to its own H6 proton in combination with the imino proton kinetics associated with these triplets reinforces the original observation of a sequence dependent dynamic variation.

Base-pairing shift in the major groove of (CA)n tracts by B-DNA crystal structures

the crystal packing of the B-DNA dodecamer d(ACCG-GCGCCACA).d(TGTGGCGCCGGT) is characterized by the reciprocal fit of double helices with specific base-backbone interactions in the major groove. Cooling the crystals below -10 degrees C stabilizes a new conformational state with a long-range sequence-dependent one-step shift in the major-groove base pairing. The tilt of the bases leads to the disruption of the Watson-Crick pairing in the major groove and to the formation of interactions with the 5' neighbour of their complement. This alteration propagates along the helical axis over more than half a turn. As a result, the molecular structure is normal when seen from the minor groove side and mismatched in the major groove. Comparison with a parent isomorphous dodecamer structure corresponding to the codon 10-13 of the c-Ha-ras proto-oncogene show that this new structural feature is sequence dependent and clearly favoured by (CA)n tracts. As(CA)n tracts of DNA are involved both in recombination and in transcription, this new recognition pattern should be considered in the analysis of the various processes involving the reading of the genetic information.

Curved DNA without A-A: experimental estimation of all 16 DNA wedge angles

The principal sequence feature responsible for intrinsic DNA curvature is generally assumed to be runs of adenines. However, according to the wedge model of DNA curvature, each dinucleotide step is associated with a characteristic deflection of the local helix axis. Thus, an important test of a more general view of sequence-dependent DNA curvature is whether sequence elements other than A-A cause the DNA axis to deflect. To address this question, we have applied the wedge model to a large body of experimental data. The axial path of DNA can be described at each step by three Eulerian angles: the helical twist, the deflection angle (wedge angle), and the direction of the deflection. Circularization and gel electrophoretic mobility data on 54 synthetic DNA fragments, both from other laboratories and from our own, were used to compare the theoretical predictions of the wedge model with experiment. By minimizing misfit between calculated and observed DNA curvature, we have found that the stacks AG/CT, CG/CG, GA/TC, and GC/GC, in addition to AA/TT, have large wedge values. We have also synthesized seven sequences without AA/TT elements but with these other wedges correctly phased to cause appreciable predicted curvature. All appear curved as demonstrated by anomalous gel mobilities. The full set of 16 roll and tilt wedge angles is estimated and, together with the known 10 helical twists, these allow prediction of the general sequence-dependent trajectory of the DNA axis.

Mechanisms of mutagenesis in the Escherichia coli mutator mutD5: role of DNA mismatch repair

To investigate the mechanisms of spontaneous mutation in the Escherichia coli mutD5 mutator strain, 502 mutations generated in this strain in the N-terminal part of the lacI gene were sequenced (i-d mutations). Since the mutator strength of this strain depends on the medium in which it grows, mutations were analyzed in both minimal medium (moderate mutator activity) and rich medium (high mutator activity). In either case, 95% of all mutations were base substitutions and 5% were single-base deletions. However, the nature and site distribution of the base substitutions differed dramatically for the two conditions. In minimal medium (mutation frequency, 480-fold above background), a majority (62%) were transversions, notably A.T----T.A at three 5'-GTGG-3' sequences. Most (64%) of the transitions under this condition occurred at specific sequences that are suggestive of a "dislocation" type of mutagenesis. In rich medium (mutation frequency, 37,000-fold above background), 90% of the base substitutions were transitions. These observations suggest that different modes of mutagenesis operate under the two conditions. mutD5 cells have been reported to be defective in exonucleolytic proofreading during DNA replication. The present data suggest that mutD cells in rich medium also suffer a defect in mutHLS-encoded mismatch correction. This hypothesis was confirmed by the direct measurement of mismatch repair in mutD5 cells by transfection of M13mp2 heteroduplex DNA.

Solution conformations of DNAs containing binding sites of the catabolite gene activator protein and lac repressor protein: characterization by Raman spectroscopy

Raman spectra from three subfragments of the Escherichia coli lactose promoter region were obtained in 0.1 M NaCl. The three DNAs are 21, 40, and 62 bp in length. The 21 and 62 bp DNAs contain the binding site for the catabolite gene activator protein (CAP). The 40 bp DNA contains the binding site for the lac repressor. A quantitative analysis of Raman band characteristics indicates an overall B-type conformation for these gene regulatory sites. Bands which correspond to A-family (807 cm-1) and B-family (834 cm-1) deoxyribose phosphate vibrations have the same intensities as bands found in heterogeneous DNAs. The spectra of the 21 bp CAP site have, however, a small band at 867 cm-1 and several other small differences similar to some characteristics observed in C-DNA spectra. Several dG nucleosides in the CAP site appear to be altered from the conventional C2'-endo/anti conformation. At 45 degrees C, well below the melting region of these DNAs, small changes occur in the spectra of the 40 bp lac repressor site which are not observed in the other DNAs. A weak band occurs at 705 cm-1, and intensity changes are observed at 497, 682, and 792 cm-1. The changes suggest that the conformations of several dG nucleosides are altered and that a small region may exist with characteristics of an A-family backbone. This conformational change at 45 degrees C coincides with previous NMR observations indicating an enhanced imino proton exchange rate at a GTG sequence within the lac operator site.

Conserved elements in the transcription initiation regions preceding highly expressed structural genes of methanogenic archaebacteria

The sequences of the intergenic regions of the strongly expressed genes encoding methyl CoM reductase in three different methanogenic archaebacteria were determined and the 5'-ends of the transcripts were mapped. After alignment, consensus sequences were found which are located both upstream and downstream of the transcription starts. They correspond, in part, to those previously characterized as putative elements of archaebacterial promoter sequences. In addition, bending of the DNA in front of the transcription start sites was shown in two cases and a characteristic common DNA structure immediately downstream of the 5'-end of the transcript was discovered. This structure was also found in the corresponding regions of previously described genes in methanogens. Our results suggest that both sequence and structural information may have roles in the initiation of transcription of protein encoding genes of these archaebacteria.

The potentially Z-DNA-forming sequence d(GTGTACAC) crystallizes as A-DNA

(GT)n/(CA)n sequences have stimulated much interest because of their frequent occurrence in eukaryotic DNA and their potential for forming the left-handed Z-DNA structure. We here report the X-ray crystal structure of a self-complementary octadeoxynucleotide, d(GTGTACAC), at 2.5 A resolution. The molecule adopts a right-handed double-helical conformation belonging to the A-DNA family. In this alternating purine-pyrimidine DNA minihelix the roll and twist angles show alternations qualitatively consistent with Calladine's rules. The average tilt angle of 9.3 degrees is between the values found in A-DNA (19 degrees) and B-DNA (-6 degrees) fibers. It is envisaged that such intermediate conformations may render diversity to genomic DNA. The base-pair tilt angles and the base-pair displacements from the helix axis are found to be correlated for the known A-DNA double-helical fragments.

Sequence-specific assignments and their use in NMR studies of DNA structure

There has been a surge of recent interest, reflected by a sharp increase in the number of publications, in the area of high-resolution nuclear magnetic resonance (NMR) studies of DNA. The goal of many of these studies is to monitor the structure of biologically important DNA sequences directly in solution; the impetus for such studies was the realization, from early single-crystal X-ray structures, that nearest-neighbor context effects are a major determinant of local structure in short double-helical DNAs (Dickerson & Drew, 1981; Dickerson, 1983). Thus, instead of the previously assumed regular averaged structure of the double helix derived from fibre diffraction analysis, the more interesting concept emerged that specific sequence-dependent distortions from ‘classical’ DNA structure might be responsible for the recognition of such sequences by a variety of ligands such as repressors, polymerases, drugs, etc.

DNA and RNA: NMR studies of conformations and dynamics in solution

The early NMR research on nucleic acids was of a qualitative nature and was restricted to partial characterization of short oligonucleotides in aqueous solution. Major advances in magnet design, spectrometer electronics, pulse techniques, data analysis and computational capabilities coupled with the availability of pure and abundant supply of long oligonucleotides have extended these studies towards the determination of the 3-D structure of nucleic acids in solution.

A common structural feature in promoter sequences of E. coli

We have searched promoter regions of E. coli, structural genes of the same organism, and computer-generated random sequence DNA for the occurrence of common structural features. This is done by converting the base sequence to a series of numbers representing the sequence of helix twist angles and examining these numerical sequences statistically. Common structural features are shared by the promoter regions with a much higher frequency than are found in structural genes or in random sequences. These structures appear to be scattered randomly throughout the promoters, both in terms of the number of such structures per promoter and in terms of location within each promoter. One particular structure consisting of five successive helix twist angles is reported, along with a list of 60 different hexanucleotide sequences that share this structure. The locations of these structural elements in 61 E. coli promoters are also tabulated.

Partial overlapping of binding sequences for steroid hormone receptors and DNaseI hypersensitive sites in the rabbit uteroglobin gene region

Four DNaseI hypersensitive (HS) chromatin regions were found in the uteroglobin locus located at -3.7, -2.4, -0.1 and +4.1 kb with respect to the transcription start site of the gene. The three sites upstream of the gene are only detected in the hormonally stimulated endometrium and disappear after hormone withdrawal, whereas the site at +4.1 is also found in tissues that do not express uteroglobin. In the -2.4 HS region, which is strictly dependent on progesterone treatment, three DNaseI sites are clustered within a 240 bp DNA segment that contains 20 imperfect repeats of an octanucleotide motif. Upstream of the uteroglobin gene there are three regions containing binding sites for the glucocorticoid and the progesterone receptors, located at -3.7, -2.6/-2.7 and -2.4. The -2.4 region contains two binding sites for the hormone receptors flanking the central HS site. In footprinting experiments with naked DNA binding of the receptor also renders this site more susceptible towards digestion with DNaseI. The -2.6/-2.7 region contains three binding sites for the hormone receptors located 140 bp upstream of the HS -2.4. While the -3.7 HS is also located within a receptor binding fragment, there is no binding of the hormone receptors to the promoter region. Thus, interaction of the receptor with DNA sequences far upstream from the promoter alters the chromatin conformation of neighbouring sequences and results in transcriptional activation.

Preferential nucleosome placement on pBR322 restriction fragments

Two restriction fragments of DNA containing the regulatory feature GTG/CAC were experimentally associated with core histones. The reconstituted DNA-histone complexes consisted of different forms of mononucleosomes. Lambda exonuclease and Fnu4HI were used to probe the structure of each distinct nucleoprotein complex. For each of the DNA fragments, one form of particle was produced that showed preferred placement of the core octamer on the DNA. The GTG/CAC base triplets may play some role in determining the final histone core positions in these reconstitutes.

TGTG, G clustering and other signals near non-mammalian vertebrate mRNA 3' termini: some implications

Analysis of non-mammalian vertebrate DNA sequences in the 500 nucleotides preceding and 200 nucleotides following mRNA 3' termini yields some distinct signals. In addition to the well known AATAAA sequence, TGTG recurs very frequently further downstream. GGGG, TGGG, GGAG and GAGG are frequent in this region too. It is suggested that unlike the AATAAA mRNA cleavage/processing signal, the other signals noted above are signals on the DNA, i.e. they are signals for mRNA termination. An asymmetric distribution of some complementary sequences, e.g. TGTG vs. CACA, GGGG vs. CCCC, on the same DNA strand is noted as well. A few other signals are also observed.

Sequence signals which may be required for efficient formation of mRNA 3' termini

It has been known for sometime that AATAAA (Proudfoot and Brownlee, 1976) is often required for 3' mRNA processing. More recently, McLauchlan et al. (1985) have shown the high incidence of YGTGTTYY (Y is a pyrimidine) downstream from the poly (A) addition site. Our results fully support their findings. There have been indications that additional sequences are required either for transcription termination of mRNA or for its cleavage/processing. Here I present the results of detailed analysis of mammalian DNA sequences around the 3' ends of mRNAs. The distributions of 256 quartets and some pentamers have been studied. Except for the AATAAA several additional signals emerge, namely, the homooligomers A4-5, T4-5 and C4-5, C3-4 interspersed with a single T, alternations of T and G, TTCTT and GGAGG. These are highly regular sequences which may exhibit unique conformations. The results also show a clear-cut asymmetry in the distribution of complementary oligomers on the same DNA strand. The possibility that at least some of these signals are recognized on the DNA and thus play a role in the termination process is discussed.

NMR studies of DNA recognition sequences and their interaction with proteins. The phage lambda OR1 operator, a symmetric lac operator and their specific complexes with cro protein and lac repressor "headpiece"

The phage lambda operator OR1 and a 18 base pair symmetric lac operator have been studied by high resolution NMR. The imino proton resonances and the resonances of the unexchangeable protons (except the 5' and 5" sugar proton resonances) have been assigned by one- and two-dimensional NOE techniques. The imino proton resonances of OR1 and the symmetric lac operator have been used to monitor changes induced in the operator structure by the formation of a specific complex with the phage lambda cro protein and with the lac repressor N-terminal DNA binding domain ("headpiece"). Two regions within the OR1 sequence could be identified, where changes in the imino proton resonance positions occur: The central part around base pairs CG 9 and 10 and the region around base pairs AT 5 and CG 5. The TA base pair 6 is the only position in the symmetric lac operator, where the complex formation with headpiece induces a change.

Some guidelines for identification of recognition sequences: regulatory sequences frequently contain (T)GTG/CAC(A), TGA/TCA and (T)CTC/GAG(A)

Inspection of many proposed recognition signal sequences shows that TGTG/CACA, GAGA/TCTC or their triplet subsets, and TGA/TCA occur frequently. These repeated elements, conserved in recognition sequences from evolutionarily distant organisms, are likely to possess unique structural characteristics. Recurrence of these oligomers may aid in identification of further regulatory sequences in upstream or other regions. Another class of recognition sequences is GC-rich. At present there are only a few examples of this class. It is likely that these sequences function via a different mechanism.

Sequence signals in eukaryotic upstream regions

In eukaryotes, as in prokaryotes, evidence is accumulating showing that transcription factors recognize and bind to certain promoter elements. Sequence and chromatin structure perturbation specify the transcription initiation site and govern its efficiency. Two oligomers have been implicated in these processes: the TATAAATA and CCAAT. In the present work, all mammalian, non-mammalian vertebrate and invertebrate sequences accumulated in the database have been aligned by their mRNA start positions and scanned for recurrences of the 32 complementary triplets. The more significant signals are summarized here. In particular, TAT/ATA recurs very frequently further upstream, at -275, in addition to the 'classical' -40 position. Downstream their level is very low. The CAAT box complementary triplet components are not among the more striking signals. Closer examination of the -275 region indicates that to a large extent the signal is due to both the ATAT and the TATA quartets. Comparison of the frequencies of these quartets at -275 with the CAAT quartet at -80 suggests that the former signal is twice the strength of the latter. The oligomers' distribution charts support notions that several components are involved in recognition, making the regulatory regions more robust and less sensitive to mutations.

Detection of single base-pair mismatches in DNA by chemical modification followed by electrophoresis in 15% polyacrylamide gel

We have developed a method for distinguishing fragments of DNA that contain single-base mismatches from their perfectly paired homologues. Single-stranded regions within a duplex fragment are accessible to 1-cyclohexyl-3-(2-[4-(4-methyl)morpholinyl]ethyl)carbodiimide, which reacts with unpaired guanidylate and thymidylate residues in DNA. Intact linear duplex DNA molecules do not react with carbodiimide, whereas DNA molecules containing single-base mismatches react quantitatively. After carbodiimide reaction, the DNA molecules are electrophoresed in high-percentage polyacrylamide gels so that modified and unmodified fragments can be resolved. Application of this technique should make it possible to locate and purify DNA fragments that exhibit sequence differences from those that do not; these might be used to signal phenotypic variation as well as to diagnose inherited disease.

Structural wrinkles and the genomic regulatory sites of eukaryotes

Calculations of DNA angular parameters in 50 eukaryotic sequences reveal regions of large conformational deviations from ideal DNA around regulatory sites. Frequently, discrete peaks of structural variation are present upstream of genes. Known regulatory regions often include variants of consensus sequences. Thus, imprecise sequences and structures are recognized within large genomic stretches. The existence of structurally "wrinkled" regions in the vicinity of regulatory sequences is likely to facilitate greatly their recognition by proteins and enzymes.

Conformation, dynamics, and structural transitions of the TATA box region of self-complementary d[(C-G)n-T-A-T-A-(C-G)n] duplexes in solution

Structural and kinetic features of the TATA box located in the center of the alternating self-complementary d(C-G-C-G-T-A-T-A-C-G-C-G) duplex (TATA 12-mer) and d(C-G-C-G-C-G-T-A-T-A-C-G-C-G-C-G) duplex (TATA 16-mer) have been probed by high-resolution proton and phosphorus NMR spectroscopy in aqueous solution. The imino exchangeable Watson-Crick protons and the nonexchangeable base protons in the TATA box of the TATA 12-mer and TATA 16-mer duplexes have been assigned from intra and inter base pair nuclear Overhauser effect (NOE) measurements. Imino proton line-width and hydrogen exchange saturation recovery measurements demonstrate that the dA X dT base pairs in the TATA box located in the center of the TATA 12-mer and TATA 16-mer duplexes are kinetically more labile than flanking dG X dC base pairs. The proton and phosphorus NMR parameters of the TATA 12-mer monitor a cooperative premelting transition in the TATA box prior to the onset of the melting transition to unstacked strands. Phosphorus NMR studies have been unable to detect any indication of a right-handed B DNA to a left-handed Z DNA transition for the TATA 12-mer duplex in saturated NaCl solution. By contrast, we do detect the onset of the B to Z transition for the TATA 16-mer in saturated NaCl solution. Proton and phosphorus NMR studies demonstrate formation of a loop conformation with chain reversal at the TATA segment for the TATA 12-mer and TATA 16-mer duplexes on lowering the DNA and counterion concentration. The imino protons (10-11 ppm) and phosphorus resonances (3.5-4.0 ppm; 4.5-5.0 ppm) of the loop segment fall in spectral windows well resolved from the corresponding markers in fully paired segments so tha it should be possible to identify loops in longer DNA helixes. The equilibrium between the loop and fully paired duplex conformations of the TATA 12-mer and TATA 16-mer is shifted toward the latter on addition of moderate salt.

Conformation and dynamics of the Pribnow box region of the self-complementary d(C-G-A-T-T-A-T-A-A-T-C-G) duplex in solution

Nuclear magnetic resonance (NMR) has been used to monitor the conformation and dynamics of the d(C1-G2-A3-T4-T5-A6-T6-A5-A4-T3-C2-G1) self-complementary dodecanucleotide duplex (henceforth called Pribnow 12-mer), which contains a TATAAT Pribnow box and a central core of eight dA X dT base pairs. The exchangeable imino and nonexchangeable base protons have been assigned from one-dimensional intra and inter base pair nuclear Overhauser effect (NOE) measurements. Premelting conformational changes are observed at all the dA X dT base pairs in the central octanucleotide core in the Pribnow 12-mer duplex with the duplex to strand transition occurring at 55 degrees C in 0.1 M phosphate solution. The magnitude of the NOE measurements between minor groove H-2 protons of adjacent adenosines demonstrates that the base pairs are propeller twisted with the same handedness as observed in the crystalline state. The thymidine imino proton hydrogen exchange at the dA X dT base pairs has been measured from saturation recovery measurements as a function of temperature. The exchange rates and activation barriers show small variations among the four different dA X dT base pairs in the Pribnow 12-mer duplex.(ABSTRACT TRUNCATED AT 250 WORDS)

Periodic structurally similar oligomers are found on one side of the axes of symmetry in the lac, trp, and gal operators

Three well-defined E. coli operator regions were examined for recurring conformational deviation from a regular B-DNA helix. All three, the lac, trp, and gal, show repeats of the same set of neighboring helical twist angles. These angles recur with a periodicity equal to the helix periodicity on one side of the operator's axes of symmetry. The probability that their occurrence is random was found to be extremely small. Therefore, we propose that in addition to specific bases, repeating twist angles patterns are likely to be among the local parameters involved in repressor-operator recognition.

Effect of environment, conformation, sequence and base substituents on the imino proton exchange rates in guanine and inosine-containing DNA, RNA, and DNA-RNA duplexes

High-resolution 1H nuclear magnetic resonance in H2O has been used to study the effect of sequence, conformation, environmental factors and base substituents on the exchange behavior of the hydrogen-bonded imino protons of guainine X cytosine and inosine X cytosine base-pairs in DNA, RNA, and DNA-RNA duplexes. The exchange rates were determined by measurement of the spin-lattice relaxation rates of the imino protons as a function of temperature. The exchange was not altered by the presence of high concentrations of salt, and the inability of phosphate to catalyze the exchange indicates that the exchange is limited by formation of a solvent-accessible "open" state. The exchange behavior depends on the duplex conformation and sequence. Exchange from the Z form polymers was orders of magnitude slower than the corresponding duplexes in the B conformation, and the A form RNA duplexes exchanged more slowly than the B form DNA polymers with the same sequence. The exchange behavior of the DNA-RNA hybrids was dependent on whether the purine or the pyrimidine strand contained the deoxyribose sugar. For both the guanine and inosine-containing duplexes, the homopolymer duplexes exchange more slowly than the more stable alternating copolymers. For the alternating duplexes, substitution of cytosine with 5-bromo- or 5-methylcytosine slowed the exchange and increased the activation energy for exchange. The inosine-containing duplexes exchanged more rapidly than the guanosine-containing duplexes, but both showed similar changes in exchange behavior in response to changes in sequence and base substituents. The activation energies for base-pair opening in B form DNA are correlated with the van der Waals contribution to the base-base interaction energy, suggesting that the purine base is partially unstacked in the open state. Using the relaxation measurements to set an upper limit on the exchange rate in poly(dG-dC) and the tritium exchange behavior at low temperature, we find that even though Z-DNA exchanges very slowly, the activation energy is similar to that observed in the A and B form duplexes, suggesting that exchange occurs from a similar open state.

Correlation of lac operator DNA imino proton exchange kinetics with its function

The kinetics for imino hydrogen exchange, at individual base pairs in the DNA sequence corresponding to the lactose operon operator of Escherichia coli, has been examined by NMR saturation recovery measurements as a function of temperature. Three 17-base-pair subsections of the lac operator DNA were chemically synthesized for these studies. The results support our previous observations in the 36-base-pair complete lac operator DNA fragment that has been used in our previous NMR studies. The results indicate faster opening kinetics at a GTG/CAC that is also the site of operator mutations leading to the highest level of constitutive beta-galactosidase synthesis. The GTG/CAC sequence occurs frequently and often symmetrically in prokaryotic and eukaryotic DNA sites where one anticipates specific protein interaction for gene regulation or recombination.