Sequence specific molecular recognition and binding of a monocationic bis-imidazole lexitropsin to the decadeoxyribonucleotide d-[(GATCCGTATG).(CATACGGATC)]: structural and dynamic aspects of intermolecular exchange studied by 1H-NMR

The non-exchangeable and imino proton NMR resonances of the non self-complementary decadeoxyribonucleotide d-[(GATCCGTATG).(GATACGGATC)] as well as those of the 1:1 complex of the monocatonic bis-imidazole lexitropsin 1 to this sequence have been assigned by using a combination of NOE difference, COSY and NOESY techniques. Confirmation of complete annealing of the two non self-complementary decamer strands to give the duplex decadeoxyribonucleotide is obtained by the detection of ten imino protons. It is established that the sugar-base orientations of all the bases in the duplex decamer are anti. From NOE studies, it is concluded that the duplex oligomer is right-handed and adopts a conformation in solution that belongs to the B family. A population analysis reveals that the sugar moieties exist predominantly in the S-form (2'-endo-3'-exo). Addition of 1 to the DNA solution leads to doubling of the resonances for CH6(4,5), GH8(6), TH6(7) and T-CH3(7). The base, anomeric H1' and imino proton signals for the base sequence 5'-CCGT undergo the most marked drug-induced chemical shift changes. These results provide evidence that the lexitropsin is bound to the sequence 5'-CCGT in the minor groove of the DNA. NOE measurements between the amide protons (NH1 and NH4) and the imino proton (IV and V) signals confirmed the location and orientation of 1 in the 1:1 complex, with the imino terminus oriented to C(4). The specific binding of 1 to the sequence 5'-CCGT-3' deduced in this study is in agreement with the footprinting data obtained using the Hind III/Nci fragment from pBR322 DNA [Kissinger et al. 1987 (13)]. Intramolecular NOEs observed between H4 and H9 of the lexitropsin suggest that the molecule is not planar, but subjected to propeller twisting, in both the free and bound forms. Furthermore, NOE measurements permit assignment of the DNA duplex in the 1:1 complex to the B-form, which is similar to that of the free DNA. The [(T7A8T9).(A12T13A14)] segment of the DNA shows better stacking, by propeller twisting, compared to the rest of the molecule in the free as well as the complex forms. The intermolecular rate of exchange of 1 between the equivalent 5'-CCGT sites, at a concentration of 12 mM, is estimated to be approximately 88s-1 at 308 degrees K with delta G not equal to of 63 +/- 5 KJ mol-1.     

Molecular recognition and binding of a GC site-avoiding thiazole-lexitropsin to the decadeoxyribonucleotide d-[CGCAATTGCG]2: 1H-NMR evidence for thiazole intercalation

The structural and dynamic aspects of the interaction of the thiazole containing lexitropsin (1) with an oligodeoxyribonucleotide were studied by high field 1H-NMR spectroscopy. Complete assignment of the 1H-NMR resonances of lexitropsin 1 was accomplished by 2D-NMR techniques. The complexation-induced chemical shifts and NOE cross peaks in the NOESY map of the 1:1 complex of lexitropsin (1) and d-[CGCAATTGCG]2 reveal that the thiazole ring of the lexitropsin (1) intercalates between dA4.A5 bases and the rest of the ligand resides in the minor groove of the AT rich core of decamer, thus occupying the 5'-AATT sequence on the DNA. Intercalation of the thiazole moiety of the drug has been detected by the presence of intermolecular NOEs both in the major and the minor groove of the decamer helix. The absence of intranucleotide NOEs between base protons and H1'/H2' protons suggested local unwinding of the binding site on the DNA. From COSY and NOESY methods of 2D-NMR, it was established that the N-formyl (amino) terminus of the thiazole lexitropsin (1) is projecting into the major groove towards A5H8 while the amidinium terminus lies in the minor groove towards the T7G8 base pairs of the opposite strand. The expected intranucleotide NOEs confirmed that the decadeoxyribonucleotide in the 1:1 complex exists in a right handed B-conformation. The presence of exchange signals along the binding site 5'-AATT indicated an exchange of the bound drug process wherein the rate of exchange between the two equivalent sites was estimated to be congruent to 130 s-1 at 30 degrees C and with delta G degrees of 62.4 kJ mol-1. Force field and Pi calculations permitted a rationalization of the experimentally observed binding mode in terms of preferred conformation of the ligand and repeat length in lexitropsins compared with the DNA receptor.     

Sequence Specific Molecular Recognition and Binding of a Monocationic Bis-Imidazole Lexitropsin to the Decadeoxyribonucleotide d-[(GATCCGTATG) (CATACGGATC)]: Structural and Dynamic Aspects of Intermolecular Exchange Studied by 1H-NMR

Abstract

The non-exchangeable and imino proton NMR resonances of the non self-complementary decadeoxyribonucleotide d-[(GATCCGTATG) · (GATACGGATC)] as well as those of the 1:1 complex of the monocatonic bis-imidazole lexitropsin 1 to this sequence have been assigned by using a combination of NOE difference, COSY and NOESY techniques. Confirmation of complete annealing of the two non self-complementary decamer strands to give the duplex decadeoxyribonucleotide is obtained by the detection of ten imino protons. It is established that the sugar-base orientations of all the bases in the duplex decamer are anti. From NOE studies, it is concluded that the duplex oligomer is right-handed and adopts a conformation in solution that belongs to the B family. A population analysis reveals that the sugar moieties exist predominantly in the S-form (2′-endo-3′-exo). Addition of 1 to the DNA solution leads to doubling of the resonances for CH6(4,5), GH8(6), TH6(7) and T-CH₃(7). The base, anomeric H1′ and imino proton signals for the base sequence 5′-CCGT undergo the most marked drug-induced chemical shift changes. These results provide evidence that the lexitropsin is bound to the sequence 5′-CCGT in the minor groove of the DNA NOE measurements between the amide protons (NH1 and NH4) and the imino proton (IV and V) signals confirmed the location and orientation of 1 in the 1:1 complex, with the amino terminus oriented to C(4). The specific binding of 1 to the sequence 5′-CCGT-3′ deduced in this study is in agreement with the footprinting data obtained using the Hind III/Nci I fragment from pBR322 DNA [Kissinger et al. 1987 (13)]. Intramolecular NOEs observed between H4 and H9 of the lexitropsin suggest that the molecule is not planar, but subjected to propeller twisting, in both the free and bound forms. Furthermore, NOE measurements permit assignment of the DNA duplex in the 1:1 complex to the B-form, which is similar to that of the free DNA The [(T₇A₈T₉)· (A₁₂T₁₃A₁₄)] segment of the DNA shows better stacking, by propeller twisting, compared to the rest of the molecule in the free as well as the complex forms. The intermolecular rate of exchange of 1 between the equivalent 5′-CCGT sites, at a concentration of 12 mM, is estimated to be ～88s^?1 at 308°K with ΔG≠ of 63±5 K.J mol^?1.     

1H NMR studies on the interaction between distamycin A and a symmetrical DNA dodecamer

High-resolution NMR techniques have been used to examine the structural and dynamical features of the interaction between distamycin A and the self-complementary DNA dodecamer duplex d-(CGCGAATTCGCG)2. The proton resonances of d(CGCGAATTCGCG)2 have been completely assigned by previous two-dimensional NMR studies [Hare, D. R., Wemmer, D. E., Chou, S. H., Drobny, G., & Reid, B. R. (1983) J. Mol. Biol. 171, 319-336]. Addition of the asymmetric drug molecule to the symmetric dodecamer leads to the formation of an asymmetric complex as evidenced by a doubling of DNA resonances over much of the spectrum. In two-dimensional exchange experiments, strong cross-peaks were observed between uncomplexed DNA and drug-bound DNA resonances, permitting direct assignment of many drug-bound DNA resonances from previously assigned free DNA resonances. Weaker exchange cross-peaks between formerly symmetry related DNA resonances indicate that the drug molecule flips head-to-tail on one duplex with half the frequency at which it leaves the DNA molecule completely. In experiments performed in H2O, nuclear Overhauser effects (NOEs) were observed from each drug amide proton to an adenine C2H and a pyrrole H3 ring proton. In two-dimensional nuclear Overhauser experiments performed on D2O solutions, strong intermolecular NOEs were observed between each of the three pyrrole H3 resonances of the drug and an adenine C2H resonance, with weaker NOEs observed between the drug H3 resonances and C1'H resonances. The combined NOE data allow us to position the distamycin A unambiguously on the DNA dodecamer, with the drug spanning the central AATT segment in the minor groove.     

Sequence specific molecular recognition and binding by a GC recognizing Hoechst 33258 analogue to the decadeoxyribonucleotide d-[CATGGCCATG]2: structural and dynamic aspects deduced from high field 1H-NMR studies.

The non-exchangeable and imino proton NMR resonances have been assigned of the 1:1 complex of an analogue 2 of Hoechst 33258 1 bound to the decadeoxyribonuycleotide d-[CATGGCCATG]2 by a combination of NOE difference, COSY and NOESYPH techniques. In contrast to Hoechst 33258 which recognizes 5'-AATT sequences exclusively, analogue 2 possesses structural features designed to permit the recognition of GC sites. The NOESY and 1D-NOE experiments place the drug in the minor groove and it is located on the 5'-CCAT sequence. The orientation of the drug in the groove is such as to place the N-methylpiperazine terminus at a GC site. Cross-correlation peaks in the NOESY experiment show that the DNA duplex retains its right-handed B form, similar to that in the free decamer. Specific NOEs locate the benzoxazole moiety on the 5'-CCAT and are consistent with the pyridine nitrogen forming a new hydrogen bond to G(4)-2NH2 at 5'-CCAT. The drug appears to undergo rotation around the C9-C10 bond, at a rate comparable with NMR time scale, even after binding. Variable temperature 1H-NMR studies established that the DNA is thermally stabilized as a result of the drug binding. The drug binding is a dynamic process involving exchange between the equivalent 5'-CCAT sites at approximately 60s-1 with delta G degree of 65 kJ mol-1 at 308K. The experimental evidence is in accord with a slide-swing mechanism for this process.     

Structural and dynamic aspects of binding of a prototype lexitropsin to the decadeoxyribonucleotide d(CGCAATTGCG)2 deduced from high-resolution 1H NMR Studies

Structural and dynamic properties of the self-complementary decadeoxyribonucleotide d(CGCAATTGCG)2 and the interaction between a prototype lexitropsin, or information-reading oligopeptide, and the decadeoxyribonucleotide are deduced by using high-resolution 1H NMR techniques. The nonexchangeable and imino proton resonances of d(CGCAATTGCG)2 have been completely assigned by two-dimensional NMR studies. The decadeoxyribonucleotide exists as a right-handed B-DNA. In the 1H NMR spectrum of the 1:1 complex, the selective chemical shifts and removal of degeneracy of AH2(4), AH2(5), T-CH3(6), and T-CH3(7) due to the anisotropy effects of the heterocyclic moieties of the ligand, and with lesser effects at the flanking base sites C(3) and G(8), locate the drug centrally in the decadeoxyribonucleotide. This conclusion is supported by plots of individual chemical shift changes across the decadeoxyribonucleotide. Similarly, imino protons IV and V experience larger shifts and II and III smaller shifts in accord with this conclusion while drug complexation permits the detection of imino proton I. Strong nuclear Overhauser effects (NOEs) between pyrrole H5 and AH2(5), and weaker NOEs to AH1'(5), TH3'(6), and AH2'(5), firmly locate the ligand in the minor groove. Intraligand NOEs between the adjacent heterocyclic moieties indicate that the lexitropsin is subject to propeller twisting about the N6-C9 bond in both the bound and free forms. Nuclear Overhauser effect spectroscopy (NOESY) and correlated spectroscopy (COSY) experiments also indicate that the removal of degeneracy of the C16 methylene protons upon complexation may arise from restricted rotation about the C15-N9, C15-C16, and C16-C17 bonds. Specific hydrogen bonds between amide NH groups on the concave face of the ligand (N4H, N6H, N9H) and adenine N3 or thymine O2 on the floor of the minor groove are in accord with displacement of the hydration shell by the drug. NOE measurements on the decadeoxyribonucleotide in the 1:1 complex confirm it exists as a right-handed helix and belongs to the B family. Exchange NMR effects permit an estimate of a rate of approximately equal to 44 s-1 for the two-site exchange of the lexitropsin between two equivalent sites on the decamer with delta G++ approximately equal to 70 +/- 5 kJ mol-1 at 294 K. Alternative mechanisms for this exchange process are considered.     

Sequence specific molecular recognition by a monocationic lexitropsin of the decadeoxyribonucleotide d-[CATGGCCATG]2: structural and dynamic aspects deduced from high field 1H-NMR studies.

All 1H-NMR resonances of d-[CATGGCCATG]2 and the 1:1 complex of lexitropsin 1 and the DNA were assigned by the NOE difference, COSY and NOESY methods. Addition of 1 causes the base and imino protons for the sequence 5'-CCAT to undergo the most marked drug-induced chemical shift changes, thereby indicating that 1 is located in this base pair sequence. NOEs confirmed the location and orientation of the drug in the 1:1 complex, with the amino terminus oriented to C(6). The van der Waals interaction between H12a,b of 1 and AH2(8) may be responsible for reading of the 3' A.T base pair in the 5'-CCAT sequence. Exchange NMR effects allow an estimate of approximately equal to 62 s-1 for the intramolecular "slide-swing" exchange of the lexitropsin between two equivalent binding sites with delta G = 58 +/- 5 kJ mol-1 at 301 degrees K.     

A 1H-NMR study of the DNA binding characteristics of thioformyldistamycin, an amide isosteric lexitropsin.

The interaction of thioformyldistamycin, an amide isostere of the naturally occurring antibiotic distamycin A, with a self-complementary decadeoxynucleotide duplex, d(CGCAATTGCG)2, has been examined using a variety of high-field 1H-NMR techniques. The ligand exhibits two forms in solution arising from geometric isomerism due to restricted rotation around the thioformamide bond. Only the thermodynamically more stable Z-form is shown to bind to the oligonucleotide along its minor groove at the central 5'-AATT segment with the end groups of the ligand extending into the flanking GC regions but without any close contact at the amidinium terminus. Cross-peaks involving characteristic intra- and interresidue proton connectivities in the 2D experiments (COSY and NOESY) were employed to assign individual resonances of both strands in the asymmetric DNA-drug complex. The solution structure of the complex was constructed by molecular mechanics calculations based upon initial estimates of drug-DNA NOE contacts and further refined through energy minimization. These results complement previous structural studies on distamycin and other lexitropsins with oligonucleotides. The exchange of the ligand between two equivalent binding sites on the DNA sequence was estimated to occur at 40 s-1 with a free energy of activation of 16.5 kcal.mol-1 at 321-326 K. There was no evidence of formation of a 2:1 drug-oligomer complex, in contrast to the case of the natural product, which is attributed to steric demands of the larger sulfur atom.     

Molecular recognition between oligopeptides and nucleic acids. Specificity of binding of a monocationic bis-furan lexitropsin to DNA deduced from footprinting and 1H NMR studies

MPE-Fe(EDTA) footprinting of a novel monocationic bis-furan lexitropsin 6 on a HindIII/EcoRI restriction fragment of pBR322 DNA revealed a series of four-base binding sites (all 5'----3') of (primary) TGTA, TGAA, AAAT, ACAA, TTAT, and (secondary) CTAA, TCGT, TGTA, GTCA, and GGTT. Thus 6 can accept a GC pair at positions 1, 2 or 3 of the binding site with a strict 3' (4 position) AT requirement. Marked enhancement of cleavage, particularly at GC rich sequences, is observed at regions flanking or even up to 18 base pairs remote from a given binding site. The non-exchangeable and imino 1H NMR resonances of the 1:1 complex and d-[CATGGCCATG]2 were assigned using a combination of NOE differences, NOESY and COSY techniques. 1H NMR studies (ligand induced chemical shifts and NOE differences) of Lexitropsin 6 with d-[CATGGCCATG]2 show unambiguously the location and orientation of the N to C termini of 6 on the sequence 5'-G5C6C7A8-3', with the C terminus oriented to A8. This orientation of 6 in the minor groove of 5'-GCCA is confirmed by an NOE observed between H1 2a of 6 and AH8(8). This preference for binding of 6 to the sequence 5'-GCCA when challenged with d-[CATGGCCATG]2 is in accord with the conclusions of the footprinting experiments wherein GC base pairs can be accepted in the first three positions and with a strict 3' terminus AT reading requirement. Collectively the data support the inference of a GC recognizing capacity for a 2,5-substituted furan moiety within a lexitropsin. The 1H NMR data indicate that the decadeoxyribonucleotide duplex exists in the B conformation in both the 1:1 complex and the free form. The apparent binding constant of 6 to calf thymus DNA is 1.68 X 10(5) M-1 whereas netropsin under similar conditions gives a value of 1.85 X 10(7) M-1. This suggests that if advantage is to be taken of the GC recognizing property of a 2,5-substituted furan in longer lexitropsins it should be flanked by more strongly bound moieties.     

Interactions between a symmetrical minor groove binding compound and DNA oligonucleotides: 1H and 19F NMR studies

High-resolution NMR techniques (proton and 19F) have been used to study the interactions between several DNA oligonucleotides with varying length of AT base pairs and the synthetic pyrrole-containing compound (P1-F4S-P1), which has properties similar to the DNA minor groove binding drug distamycin A. When this two-fold symmetrical DNA binding molecule is added to the self-complementary DNA oligomers, the resulting complex exhibits an NMR spectrum without any doubling of individual resonances, consistent with a two-fold symmetry of the complex. This is in contrast to all other complexes studied so far. The minimum length of an AT stretch for specific ligand binding is judged to be greater than 4 base pairs. Inter-molecular proton nuclear Overhauser effects between the ligand molecule and a DNA dodecamer d(CGCAAATTTGCG) provide evidence that P1-F4S-P1 binds DNA in the minor groove and interacts with the middle AT base pairs. The presence of a specific interaction between P1-F4S-P1 and DNA is conclusively demonstrated by 19F NMR studies, in which four previously chemically equivalent fluorine nuclei in the free molecule become two non-equivalent pairs (yielding an AB quartet pattern) upon the binding of P1-F4S-P1 to DNA duplex. A sequence-dependent binding behavior of P1-F4S-P1 is evident by comparing the 19F NMR spectra of the complexes between P1-F4S-P1 and two different but related DNA dodecamers, d(CGCAAATTTGCG) and d(CGCTTTAAAGCG). P1-F4S-P1 binds more strongly to the former dodecamer with an association constant of approximately 1 X 10(3) M-1.     

Structural and dynamic aspects of the sequence specific binding of netropsin and its bis-imidazole analogue on the decadeoxyribonucleotide d-[CGCAATTGCG]2

High field 1H-NMR techniques have been used to examine the sequence dependent binding of a lexitropsin, the bis-imidazole analogue of netropsin 1, to the decadeoxyribonucleotide d-[CGCAATTGCG]2. The non-exchangeable and imino protons of the 1:1 lexitropsin:DNA complex are assigned by 1D-NOE difference and COSY methods. Addition of 1 to the DNA resulted in marked drug induced chemical shift changes of both the non-exchangeable and imino protons of A(4,5) and T(6,7). These results suggest that the lexitropsin is located in the minor groove along A(4) to T(7) of the DNA. Weaker chemical shift changes are observed for C(3) and G(8) which suggest that the bisimidazole moiety of 1 can also accept G.C sites. Specific NOEs seen between the lexitropsin (H2, H14 and H15) and DNA (AH2(4) and AH2(5] confirmed that the N to C-terminii of 1 is, on average, bound centrally to the sequence in the direction 5'-AATT-3'. However, netropsin 2 is shown to bind tightly only to the AATT sequence. Exchange NMR effects permit the estimate of the rate of exchange of the lexitropsin 1 between the two equivalent sites on the DNA to be approximately 160s and 24s for netropsin under comparable conditions. Several factors contributing to the sequence specificity of lexitropsin binding are discussed.     

Two-dimensional 1H and 31P NMR spectra and restrained molecular dynamics structure of a covalent CPI-CDPI2-oligodeoxyribonucleotide decamer complex

CPI-CDPI2 is a synthetic analogue of CC-1065, which is a naturally occurring antitumor antibiotic. Assignment of the 1H NMR spectra of a CPI-CDPI2-oligodeoxyribonucleotide decamer, d-(CGCTTAAGCG)2, complex has been made by two-dimensional 1H/1H spectroscopy. The solution structure of the complex was calculated by an iterative hybrid relaxation matrix method combined with NOESY distance restrained molecular dynamics. Refinement proceeded in two steps in which the decamer was initially refined alone and then CPI-CDPI2 was added to the structure to allow initial estimates of drug-DNA contacts. A hybrid matrix/MD refinement was used to better take into account problems associated with spin diffusion. Thus the distances from the 2D NOESY spectra were calculated from the relaxation rate matrix which were evaluated from a hybrid NOESY volume matrix comprising elements from the experimental spectrum and those calculated from an initial structure. The hybrid matrix derived distances were then used in a restrained molecular dynamics procedure to obtain a new structure that better approximates the NOESY spectra. The resulting partially refined structure was then used to calculate an improved theoretical NOESY volume matrix which is once again merged with the experimental matrix until refinement is complete. The efficacy of CC-1065 has been attributed to its minor groove binding and alkylation to the N3 position of adenosine. CPI-CDPI2 appears to bind to the decamer in a similar manner. The effect of CPI-CDPI2 on the decamer's 1H and 31P spectrum was consistent with a minor groove binding motif with the drug alkylating at A17 with the CDPI rings oriented toward the 5'-end of the alkylated strand. In addition, the NMR data support one major adduct but also indicate the presence of a minor adduct. The latter could represent a drug alkylation of the DNA at a secondary site (or alternative orientation of the rings).     

Hydration of DNA in aqueous solution: NMR evidence for a kinetic destabilization of the minor groove hydration of d-(TTAA)2 versus d-(AATT)2 segments.

The residence times of the hydration water molecules near the base protons of d-(GTGGAATTCCAC)2 and d-(GTGGTTAACCAC)2 were investigated by nuclear magnetic resonance (NMR) spectroscopy. Nuclear Overhauser effects (NOE) were observed between base protons of the DNA and hydration water in NOESY and ROESY experiments. Large positive NOESY cross peaks observed between the resonances of the water and the adenine 2H protons of the central d-(AATT)2 segment in the duplex d-(GTGGAATTCCAC)2 indicate the presence of a 'spine of hydration' with water molecules exhibiting residence times on the DNA longer than 1 nanosecond. In contrast, no positive intermolecular NOESY cross peaks were detected in the d-(TTAA)2 segment of the duplex d-(GTGGTTAACCAC)2, indicating that no water molecules bound with similarly long residence times occur in the minor groove of this fragment. These results can be correlated with the larger width of the minor groove in d-(TTAA)2 segments as compared to that in d-(AATT)2 segments, as observed previously in single crystal structures of related oligonucleotide duplexes in B type conformation. The present experiments confirm earlier experimental results from single crystal studies and theoretical predictions that a 5'-dTA-3' step in the nucleotide sequence interrupts the spine of hydration in the minor groove.     

NMR investigation of mithramycin A binding to d(ATGCAT)2: a comparative study with chromomycin A3

The binding of mithramycin A to the d(A1T2G3C4A5T6) duplex was investigated by 1H NMR and found to be similar to that of its analogue chromomycin A3. In the presence of Mg2+, mithramycin binds strongly to d(ATGCAT)2. On the basis of the two-dimensional NOESY spectrum, the complex formed possesses C2 symmetry at a stoichiometry of two drugs per duplex (2:1) and is in slow chemical exchange on the NMR time scale. NOESY experiments reveal contacts from the E-pyranose of mithramycin to the terminal and nonterminal adenine H2 proton of DNA and from the drug hydroxyl proton to both G3NH2 protons, C4H1' proton, and A5H1' proton. These data place the drug chromophore and E pyranose on the minor groove side of d(ATGCAT)2. NOE contacts from the A-, B-, C-, and D-pyranoses of mithramycin to several deoxyribose protons suggest that the A- and B-rings are oriented along the sugar-phosphate backbone of G3-C4, while the C- and D-rings are located along the sugar-phosphate backbone of A5-T6. These drug-DNA contacts are very similar to those found for chromomycin binding to d(ATGCAT)2. Unlike chromomycin, the NOESY spectrum of mithramycin at the molar ratio of one drug per duplex reveals several chemical exchange cross-peaks corresponding to the drug-free and drug-bound proton resonances. From the intensity of these cross-peaks and the corresponding diagonal peaks, the off-rate constant was estimated to be 0.4 s-1. These data suggest that the exchange rate of mithramycin binding to d(ATGCAT)2 is faster than that of chromomycin.     

Sequence-dependent recognition of DNA duplexes. Netropsin complexation to the AATT site of the d(G-G-A-A-T-T-C-C) duplex in aqueous solution

We have investigated intermolecular interactions and conformational features of the netropsin X d(G-G-A-A-T-T-C-C) complex by one- and two-dimensional NMR studies in aqueous solution. Netropsin removes the 2-fold symmetry of the d(G-G-A-A-T-T-C-C) duplex at the AATT binding site and to a lesser extent at adjacent dG X dC base pairs resulting in doubling of resonances for specific positions in the spectrum of the complex at 25 degrees C. We have assigned the amide, pyrrole, and CH2 protons of netropsin, and the base and sugar H1' protons of the nucleic acid from an analysis of the nuclear Overhauser effect (NOESY) and correlated (COSY) spectra of the complex at 25 degrees C. We observe intermolecular nuclear Overhauser effects (NOE) between all three amide and both pyrrole protons on the concave face of the antibiotic and the minor groove adenosine H2 proton of the two central A4 X T5 base pairs of the d(G1-G2-A3-A4-T5-T6-C7-C8) duplex. Weaker intermolecular NOEs are also observed between the pyrrole concave face protons and the sugar H1' protons of residues T5 and T6 in the AATT minor groove of the duplex. We also detect intermolecular NOEs between the guanidino CH2 protons at one end of netropsin and adenosine H2 proton of the two flanking A3 X T6 base pairs of the octanucleotide duplex. These studies establish a set of intermolecular contacts between the concave face of the antibiotic and the minor groove AATT segment of the d(G-G-A-A-T-T-C-C) duplex in solution. The magnitude of the NOEs require that there be no intervening water molecules sandwiched between the antibiotic and the DNA so that release of the minor groove spine of hydration is a prerequisite for netropsin complex formation.     

Protein--DNA contacts in the structure of a homeodomain--DNA complex determined by nuclear magnetic resonance spectroscopy in solution.

The 1:1 complex of the mutant Antp(C39----S) homeodomain with a 14 bp DNA fragment corresponding to the BS2 binding site was studied by nuclear magnetic resonance (NMR) spectroscopy in aqueous solution. The complex has a molecular weight of 17,800 and its lifetime is long compared with the NMR chemical shift time scale. Investigations of the three-dimensional structure were based on the use of the fully 15N-labelled protein, two-dimensional homonuclear proton NOESY with 15N(omega 2) half-filter, and heteronuclear three-dimensional NMR experiments. Based on nearly complete sequence-specific resonance assignments, both the protein and the DNA were found to have similar conformations in the free form and in the complex. A sufficient number of intermolecular 1H-1H Overhauser effects (NOE) could be identified to enable a unique docking of the protein on the DNA, which was achieved with the use of an ellipsoid algorithm. In the complex there are intermolecular NOEs between the elongated second helix in the helix-turn-helix motif of the homeodomain and the major groove of the DNA. Additional NOE contacts with the DNA involve the polypeptide loop immediately preceding the helix-turn-helix segment, and Arg5. This latter contact is of special interest, both because Arg5 reaches into the minor groove and because in the free Antp(C39----S) homeodomain no defined spatial structure could be found for the apparently flexible N-terminal segment comprising residues 0-6.     

A proton NMR study of a DNA dumb-bell structure with hairpin loops of only two nucleotides: d(CACGTGTGTGCGTGCA).

One- and two-dimensional nuclear magnetic resonance (NMR) experiments were used to study the conformation of the DNA hexadecanucleotide d(CACGTGTGTGCGTGCA) in aqueous solution. NMR spectra were recorded for the compound in D2O and in H2O/D2O (90/10) over the temperature range 1 degree C-60 degrees C. Assignments of imino proton resonances and of non-exchangeable proton resonances (except for some H4', H5' and H5" resonances) are given. The 1H-NMR spectra indicate that below about 20 degrees C, the compound exists as a single monomolecular species. Between 20 degrees C and 55 degrees C the oligonucleotide occurs as a mixture of structures in fast exchange on the NMR time scale, except for the temperature region 30 degrees - 34 degrees C, where substantial line broadening indicates intermediate exchange; above 60 degrees C the single strand predominates. The imino proton spectra, chemical shift values, and scalar coupling and NOE data reveal that the monomeric form, which is exclusively present below 20 degrees C, consists of a structure with a B-DNA double helix region of six base pairs, both ends of which are closed by hairpin loops of only two nucleotides, giving the molecule a dumbbell-like structure: [sequence: see text].     

NMR studies of a deoxyribodecanucleotide containing an extrahelical thymidine surrounded by an oligo(dA).oligo(dT) tract

One- and two-dimensional NMR experiments were carried out on a decamer, d-(CGCTTTTCGC).d(GCGAAAAGCG), and on the same sequence with the addition of an unpaired thymidine, d(CGCTTTTCGC).d(GCGAATAAGCG), which will be referred to as the T-bulge decamer. Evidence from one-dimensional NOE experiments on the exchangeable protons indicates that the unpaired thymidine is extrahelical. This conclusion is also supported by numerous cross-peaks in the two-dimensional NOESY spectrum of the nonexchangeable protons. Assignments for all of the resonances, with the exception of the H5' and H5" resonances, have been made for both oligonucleotide duplexes through the use of 2D NOESY, COSY, and relayed COSY experiments. Temperature dependence of the methyl resonance chemical shifts indicates that the unpaired thymidine shows unusual behavior compared to other thymidines in the duplex. Two-dimensional NOESY experiments carried out from 5 to 35 degrees C indicate the unpaired thymidine remains extrahelical throughout this temperature range. A similar temperature dependence for the methyl chemical shift is found in the corresponding single-strand d(GCGAATAAGCG). The oligo-(dA).oligo(dT) tracts in both the decamer and the T-bulge decamer have structures different from B-form DNA and exhibit NOEs similar to those observed in other oligonucleotides containing A.T tracts. The formation of this unusual A.T tract structure may induce the extrahelical conformation of the unpaired thymidine.     

NMR studies on the binding of antitumor drug nogalamycin to DNA hexamer d(CGTACG).

The interactions between a novel antitumor drug nogalamycin with the self-complementary DNA hexamer d(CGTACG) have been studied by 500 MHz two dimensional proton nuclear magnetic resonance spectroscopy. When two nogalamycins are mixed with the DNA hexamer duplex in a 2:1 ratio, a symmetrical complex is formed. All non-exchangeable proton resonances (except H5' & H5") of this complex have been assigned using 2D-COSY and 2D-NOESY methods at pH 7.0. The observed NOE cross peaks are fully consistent with the 1.3 A resolution x-ray crystal structure (Liaw et al., Biochemistry 28, 9913-9918, 1989) in which the elongated aglycone chromophore is intercalated between the CpG steps at both ends of the helix. The aglycone chromophore spans across the GC Watson-Crick base pairs with its nogalose lying in the minor groove and the aminoglucose lying in the major groove of the distorted B-DNA double helix. The binding conformation suggests that specific hydrogen bonds exist in the complex between the drug and guanine-cytosine bases in both grooves of the helix. When only one drug per DNA duplex is present in solution, there are three molecular species (free DNA, 1:1 complex and 2:1 complex) in slow exchange on the NMR time scale. This equilibrium is temperature dependent. At high temperature the free DNA hexamer duplex and the 1:1 complex are completely destabilized such that at 65 degrees C only free single-stranded DNA and the 2:1 complex co-exist. At 35 degrees C the equilibrium between free DNA and the 1:1 complex is relatively fast, while that between the 1:1 complex and the 2:1 complex is slow. This may be rationalized by the fact that the binding of nogalamycin to DNA requires that the base pairs in DNA open up transiently to allow the bulky sugars to go through. A separate study of the 2:1 complex at low pH showed that the terminal GC base pair is destabilized.     

Solution structure of [d(A-T)5]2 via complete relaxation matrix analysis of two-dimensional nuclear Overhauser effect spectra and molecular mechanics calculations: evidence for a hydration tunnel

Pure absorption phase proton two-dimensional nuclear Overhauser effect (2D NOE) spectra at 500 MHz have been obtained for [d(5'ATATATATAT3')]2 in deuterium oxide solution at several mixing times. The 100 nonexchangeable proton resonances have been assigned. The experimental 2D NOE spectra were compared with theoretical spectra calculated by using the complete relaxation matrix analysis method [Keepers, J. W., & James, T. L. (1984) J. Magn. Reson. 57, 404-426] and x-ray diffraction determined molecular coordinates of A, B, alternating B, left-handed B, C, D, and wrinkled D forms of DNA and of energy-minimized structures calculated from the most promising X-ray crystal structures by using the molecular mechanics program AMBER, in which all hydrogens, counterions, and hydration water molecules were included. The analysis of all features of the 2D NOE spectra played an important role in extracting the promising structures, and it was concluded that the wrinkled D form yields the best fit for the 2D NOE data of the A-T decamer. The molecular mechanics calculation indicated that this model structure, whose minor groove is comparatively deep and narrow, may be energetically more stable than the B form for alternating d(A-T) DNA. Interesting features of the structure include possible intra- and interchain sugar-phosphate attractions and a hydration tunnel inside the minor groove capable of accommodating three types of water molecules that aid in helix stabilization via hydrogen bonding. Counterions (sodium) serve to reduce interchain phosphate-phosphate repulsive effects.