Bioactive scaffolds with enhanced supramolecular motion promote recovery from spinal cord injury.

The signaling of cells by scaffolds of synthetic molecules that mimic proteins is known to be effective in the regeneration of tissues. Here, we describe peptide amphiphile supramolecular polymers containing two distinct signals and test them in a mouse model of severe spinal cord injury. One signal activates the transmembrane receptor ß1-integrin and a second one activates the basic fibroblast growth factor 2 receptor. By mutating the peptide sequence of the amphiphilic monomers in nonbioactive domains, we intensified the motions of molecules within scaffold fibrils. This resulted in notable differences in vascular growth, axonal regeneration, myelination, survival of motor neurons, reduced gliosis, and functional recovery. We hypothesize that the signaling of cells by ensembles of molecules could be optimized by tuning their internal motions.

Fast magic-angle spinning proton NMR studies of polymers at surfaces and interfaces.

Solid-state proton NMR with fast magic-angle sample spinning has been used to study the structure and dynamics of polymers and the water interface in porous glass composites. The composites were prepared by photopolymerization of poly(ethyl acrylate) and other acrylate formulations in a high surface-area rigid glass matrix with 40-A interconnected pores. High resolution solid-state proton spectra were obtained for polymer films and composites with 15 kHz magic-angle sample spinning at temperatures above the polymer glass transition temperature. The solid-state proton spectra can be detected with high sensitivity and used to determine the composition of polymer and water filling the pores. These results and spin diffusion studies using 1H-29Si 2D heteronuclear correlation and wideline separation NMR show that the polymer fills the central 30 A of the pore, and that the remaining volume is filled with surface hydroxyl groups and water.

WIM/WISE NMR studies of chain dynamics in solid polymers and blends.

Wideline separation (WISE) NMR with window-less isotropic mixing (WIM) is developed as a method to study the dynamics of polymers and blends. This experiment is designed to measure the dynamics of polymers through the proton lineshapes that are correlated with the carbon chemical shifts in two-dimensional NMR experiments. If the atoms experience large amplitude fluctuations that are fast compared to the dipolar broadening, then the proton lines will be narrowed relative to rigid solids. We have modified the WISE experiment by replacing the cross polarization step with WIM to quench spin diffusion during the cross polarization so that the proton linewidths can be directly related to the chain dynamics. Two-dimensional WIM/WISE has been used to measure the main-chain and side-chain dynamics in poly(n-butyl methacrylate) and blends of polystyrene and poly(vinyl methyl ether).

Solid-state multipulse proton Nuclear Magnetic Resonance (NMR) characterization of self-assembling polymer films.

Multipulse solid-state proton Nuclear Magnetic Resonance (NMR) has been used to study the domain structure in poly(styrene-b-isoprene-b-styrene) triblock copolymers in clear and self-assembled polymer films. Films containing ordered arrays of microcavities (3-5 microm) were obtained by casting the polymer from carbon disulfide solution in a moist environment, while clear films were obtained by solvent evaporation under nitrogen. The domain sizes for the polystyrene and polyisoprene blocks were measured by proton spin diffusion using the dipolar filter pulse sequence. The domain sizes for the dispersed phase and the long period were measured to be in the range of 3-6 nm, depending on the polymer molecular weight, and no differences domain size were observed for the clear and the self-assembled polymer films.

Magnetically induced orientation of phosphatidylcholine membranes.

Lipid bilayers prepared from natural phospholipids orient in magnetic fields with the long axis of the lipid molecules perpendicular to the magnetic field. This magnetically induced orientation was studied at high (11.7 Tesla (T)), mid (9.36 T), and low (4.68 T) magnetic field strengths using lipid aggregates prepared from natural and synthetic phosphatidylcholine analogs. Phosphatidylcholine analogs containing saturated diacylated chains (12 to 16 carbons/chain) exhibited extensive orientation of the lipid when bilayer formation occurred by gentle hydration conditions. Gentle hydration involved incubating dried phosphatidylcholine C above the main phase transition (Tm); brief shaking or swirling by hand was occasionally needed to completely disperse the lipids. The method of bilayer formation significantly influenced the amount of lipid that orients in magnetic fields. Thus the supramolecular structures (and % orientation) above Tm in an 11.7 T field of dimyristoylphosphatidylcholine (DMPC) bilayers are SUV (0%), LUV (approximately 15%), SPLV (approximately 40%), vortexed-MLV (approximately 60%) and non-vortexed MLV (approximately 90%). Single layered vesicles prepared by the REV method exhibited orientation at 11.7 T similar to LUV prepared by freeze thaw cycles. Aqueous dispersions of eggPC prepared by gentle hydration exhibit approximately 40% orientation at 11.7 T which decreased to approximately 30% orientation if 30% cholesterol is added to the membrane. Magnetic orientation of bilayers thus appears to be a general phenomenon for both saturated and unsaturated natural phospholipids either with or without cholesterol in the membrane.

1H nuclear magnetic resonance study of the dynamic properties of the B and Z-forms of poly[d(A-br5C).d(G-T)].

Poly[d(A-br5C).d(G-T)], a synthetic polynucleotide with a 50% A-T base composition, undergoes a reversible, highly co-operative transition between the right-handed B and left-handed Z conformations. The latter is stabilized at both elevated temperature and ionic strength. The B and Z-forms of poly[d(A-br5C).d(G-T)] coexist in 4.6 M-NaCl at 45 degrees C. Due to slow exchange, two sets of Tim and Gim resonances are observed and can be assigned to the B and Z conformations (the chemical shifts are, respectively, Tim = 13.4, 14.1 p.p.m. (parts/million); and Gim = 11.9, 12.4 p.p.m.). Measurements of the 1H spin-lattice (R1) and spin-spin (R2) relaxation rates of the exchangeable thymine (Tim) and guanine (Gim) imino protons have been used to probe the internal dynamics of the B and Z-forms of poly[d(A-br5C).d(G-T)] and the mechanism of the B-Z transition. The proton exchange behavior in the B and Z conformations is quite different. At elevated temperature, R1 for both Tim and Gim in the B conformation is dominated by exchange with the solvent, with Tim exchanging more rapidly than Gim. This demonstrates that exchange involves the opening of single base-pairs and that neighboring A-T and G-br5C base-pairs exchange independently of each other. B-form poly[d(A-br5C).d(G-T)] is unusual in that there is an acceleration of the Tim exchange rate with increasing NaCl concentration. Conversion to the Z-form by addition of 4.5 M-NaCl dramatically reduces both the Tim and Gim exchange rates (estimated to be less than 2 s-1 at 70 degrees C). Thus, the G-br5C base-pair and, in particular, the A-T base-pair are stabilized in the Z conformation. By measuring relaxation rates at 45 to 50 degrees C where the B and Z-forms are in equilibrium, we find that the B-Z interconversion rates are less than two per second. In the B conformation at 25 degrees C, the dipolar contributions to the imino proton relaxation rates are about one-third of those expected on the basis of a rigid rod model for 65 base-pair fragments, a difference we assign to large amplitude (30 degrees high frequency (less than 100 ns) out-of-plane motions of the bases. Conversion to the Z conformation has little effect on the dipolar contributions to relaxation, i.e. on the internal motions.(ABSTRACT TRUNCATED AT 400 WORDS)

Internal motions in B- and Z-form poly(dG-dC).poly(dG-dC): 1H NMR relaxation studies.

Proton NMR relaxation measurements are used to compare the molecular dynamics of 60 base pair duplexes of B- and Z-form poly(dG-dC).poly(dG-dC). The relaxation rates of the exchangeable guanine imino protons (Gim) in H2O and in 90% D2O show that below 20 degrees C spin-lattice relaxation is exclusively from proton-proton magnetic dipolar interactions while proton-nitrogen interactions contribute about 30% to the spin-spin relaxation. The observation that the spin-lattice relaxation is nonexponential and that the initial spin-lattice relaxation rate of the Gim, G-H8 and C-H6 protons depends on the selectivity of the exciting pulse shows that spin-diffusion dominates the spin-lattice relaxation. The relaxation rates of the Gim, C-H5, and C-H6 in B- and Z-form poly(dG-dC).poly(dG-dC) cannot be explained by assuming the DNA behaves as a rigid rod. The data can be fit by assuming large-amplitude out of plane motions (+/- 30-40 degrees, tau = 1-100 ns) and fast, large-amplitude local torsional motions (+/- 25-90 degrees, tau = 0.1-1.5 ns) in addition to collective torsional motions. The results for the B and Z forms show that the rapid internal motions are similar and large in both conformations although backbone motions are slightly slower, or of lower amplitude, in Z DNA. At high temperatures (greater than 60 degrees C), imino proton exchange with solvent dominates the spin-lattice relaxation of B-form poly(dG-dC).poly(dG-dC), but in the Z form no exchange contribution (less than 2 s-1) is observed at temperatures as high as 85 degrees C. Conformational fluctuations that expose the imino protons to the solvent are strikingly different in the B and Z forms. The results obtained here are compared with those previously reported for poly(dA-dT).poly(dA-dT).

Investigation of DNA dynamics and drug-DNA interaction by steady state fluorescence anisotropy.

We have used steady-state fluorescence polarization anisotropy (FPA) of ethidium probe molecules bound to DNA to investigate DNA-DNA interactions and the effect of high densities of intercalating drugs on the internal motions of DNA responsible for depolarization of the ethidium fluorescence. To calibrate the method, we examined the effect of DNA length on (FPA) using DNA varying in size from 10-150 base pair. The association of approximately 30 base pair DNA at high concentrations was then detected by its effect on (FPA). With sample concentrations approaching those commonly used in various physical experiments (NMR, Raman) significant DNA-DNA interactions are observed. With high molecular weight DNA (greater than 500 base pair), the limiting value of the (FPA) (0.23) is due to internal motions of the DNA (and bound chromophores). The (FPA) of ethidium probe molecules (1 drug/200 base pair) is unaffected by the addition of high levels (1 drug/2 base pair) proflavine. This indicates that either the elastic properties of DNA are unaffected by high densities of intercalated drug or that the depolarization of the ethidium fluorescence is due to highly localized motions of the base pairs that are unperturbed by binding of drugs at neighboring sites.

Unusual proton exchange properties of Z-form poly[d(G-C)].

Real-time solvent-exchange NMR has been used to study the proton exchange in Z-form poly[d(G-C)]. In 4.5 M NaCl the most slowly exchanging protons (about two orders of magnitude slower than in B-DNA) are identified as the guanine imino proton and the cytosine amino proton hydrogen bonded to the guanine carbonyl. Both protons exchange at the same rate and the exchange follows single-exponential kinetics and cannot be catalyzed, implying that the exchanges of the two protons both occur from the same transient solvent-exposed state. The exchange depends strongly on temperature and the activation energy for exchange ( approximately 22 kcal/mol) is the same as the activation energy for the B --> Z transition. The rate of proton exchange is identical with the B --> Z transition rate, both measured in 4.5 M NaCl. The correlation between the B --> Z kinetics and the proton exchange also extends to 3.25 M NaClO(4) solutions, in which both rates are 5 times faster. This unexpected parallelism between the B --> Z transition kinetics and the Z exchange kinetics indicates that the rate-limiting steps in the two processes are similar.

Comparison of the conformation of poly(dI-dC) with poly(dI-dbr5C) and the B and Z forms of poly(dG-dC). One- and two-dimensional NMR studies.

One- and two-dimensional nuclear Overhauser effects (2D NOE) have been used to compare the conformational properties of 60-80 base pair long duplexes of the synthetic DNA polymer poly(dI-dC) with those of poly(dI-dbr5C) and poly(dG-dC) in the B and Z conformations. Cross peaks in the 2D NOE spectra arising from proton-proton dipolar interactions which are more or less independent of the DNA conformation are used to assign the spectra of these molecules. Other cross peaks are sensitive to the conformational details, and these are used to make deductions about the average conformation in solution. The proton-proton interactions that give rise to the cross peaks in the 2D NOE spectrum of poly(dI-dC) are indicative of a B family conformation and rule out the possibility of some alternative conformations, including A, Z, alternating B, and left-handed B-DNA. The spectra are similar to those obtained from B-form poly(dI-dbr5C) and poly(dG-dC) but different from Z-form poly(dG-dC). Taken together, these results indicate that the solution conformation of poly(dI-dC) is not unusual but more closely resembles that of other B-form DNAs.

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.

The effect of intercalating drugs on the kinetics of the B to Z transition of poly(dG-dC).

We have measured the ability of the intercalating drugs proflavine, ethidium bromide, actinomycin D, and bismethidiumspermine to inhibit the salt induced transition of poly(dG-dC) from the B to the Z form. While all of the drugs studied slowed the B to Z transition, the effectiveness of the drugs correlates much better with their DNA binding kinetics than their DNA binding constants. In studies where the binding densities of ethidium and actinomycin were varied we have found that high levels of ethidium, more than 1 per 20 base pairs, were required to inhibit the B to Z transition while low levels of actinomycin, less than 1 per 450 base pairs, reduced the transition rate. Studies of the B to Z transition in the presence of both actinomycin and ethidium suggest that the drugs inhibit the transition by different mechanisms. The results are interpreted in terms of a modification of the kinetic model proposed by Pohl and Jovin in which, depending on the DNA binding kinetics of the drug, the drug may inhibit nucleation and/or propagation of the B to Z transition.

Biosynthesis and characterization of [15N]actinomycin D and conformational analysis by nitrogen-15 nuclear magnetic resonance.

We describe the production and characterization of actinomycin D labeled with 15N at all twelve nitrogen positions. Cultures of Streptomyces parvulus were incubated in the presence of racemic [15N]glutamic acid and, following an initial delay, labeled antibiotic was produced. Evidence is presented that the D enantiomorph of glutamic acid was ultimately used for actinomycin biosynthesis. The 15N NMR spectrum at 10.14 and 20.47 MHz of the labeled drug in CDCl3 is presented. All nitrogens except the phenoxazone chromophore nitrogen are inverted when spectra are obtained under broad-band proton irradiation conditions. All 15N resonances have been assigned, and the proton-nitrogen one-bond coupling constants were determined in CDCl3 to be 92.5 +/- 0.3 Hz for the valine and threonine amide protons by both 1H and 15N NMR. 15N NMR spectra were also obtained in dimethyl sulfoxide, methanol, and water in order to probe solvent interactions with the peptide nitrogens and carbonyl groups. Large downfield shifts (greater than 5 ppm) were seen for the Pro, sarcosine, and methylvaline resonances when the solvent was changed from dimethyl sulfoxide to water. Smaller downfield shifts were observed for the Val and Thr peaks. These results are discussed in terms of a model for the solution conformation of the actinomycin pentapeptide rings based on different hydrogen-bonding interactions in the monomer in organic solvents and the dimer which is formed in water.

High-resolution proton nuclear magnetic resonance analysis of conformational properties of biosynthetic actinomycin analogues.

High-resolution proton nuclear magnetic resonance (1H NMR) has been used to study the conformation and dynamics of biosynthetic analogues of actinomycin D that have been substituted at one or both of the 3'-amino acids with azetidine-2-carboxylic acid, pipecolic acid, or 4-ketoproline for one or both of the prolines. The results of measurements made in organic solvents indicate that the amino acid residues on the alpha and beta pentapeptide lactone rings experience different magnetic environments in all the analogues studied. Analysis of the J alpha NH coupling constants and temperature coefficients for the valine and threonine amide protons indicates that substitution at the 3' position has little effect on the conformational and hydrogen-bonding properties of the amino acids at the 1' or 2' position. Examination of the low-field position of the H alpha proton of the 3'-amino acid reveals that the biosynthetic substitutions were made at a unique site on either the alpha or the beta pentapeptide ring and that only one conformation of proline, azetidine-2-carboxylic acid, or pipecolic acid is observed. In D2O, the dynamics of the prolines appear to differ; one remains in a preferred conformation while the other fluctuates at a rate that is intermediate on the NMR time scale. A possible relationship between the conformational and dynamic properties and the DNA binding and kinetic properties is discussed.

Role of actinomycin pentapeptides in actinomycin-deoxyribonucleic acid binding and kinetics.

Results are reported on equilibrium and kinetic experiments probing the DNA binding properties of a series of actinomycin analogues differing at the 3'-amino acid position. While the parent compound, actinomycin D, contains proline at this position on both pentapeptide lactone rings, the analogues under consideration here contain either azetidine-2-carboxylic acid, pipecolic acid, or 4-ketoproline on one or both pentapeptide rings. This study extends our earlier results on doubly substituted analogues [Shafer, R.H., Burnett, R. R., & Mirau, P.A. (1980) Nucleic Acids Res. 8, 1121]. DNA binding constants were determined from Scatchard plots constructed from visible absorption data and covered the range of (0.3-9) X 10(6) M-1 for the whole series of analogues. The thermal denaturation temperature of calf-thymus DNA was increased by 3-17 degrees C. DNA dissociation kinetics, along with enthalpies and entropies of activation, were also determined. The time constant for the slowest dissociation process ranged from 278 to 10 900 s. The strongest DNA binding analogue, in terms of the largest binding constant, the largest increase in DNA thermal denaturation temperature, and the slowest DNA dissociation rate, was actinomycin V, which has 4-ketoproline in the beta peptide ring, while the weakest DNA binding analogue has pipecolic acid on both peptide rings. Evidence is presented for one peptide ring exerting a greater influence than the other in the interaction with DNA. Also, the possible role of cis-trans isomerization about one or two peptide bonds in determining the slow DNA binding kinetics is discussed.

Binding of 5-fluorotryptamine to polynucleotides as a model for protein-nucleic acid interactions: fluorine-19 nuclear magnetic resonance, absorption, and fluorescence studies.

Fluorine-19 nuclear magnetic resonance (19F NMR), optical absorption, and fluorescence spectroscopy have been used to study the interaction of 5-fluorotryptamine (5FTA) with polynucleotides as a model for protein--nucleic acid interactions. In the presence of DNA, denatured DNA, poly(A), and poly(A).poly(U), the 19F resonance of 5FTA shifted 0.3-0.6 ppm upfield while the presence of poly(I).poly(C) had little effect on the chemical shift. Differences in the 19F chemical shift induced upon changing from H2O to 2H2O indicate differences in the solvent accessibility of 5FTA bound to the various polynucleotides. 19F NMR relaxation experiments were carried out for free 5FTA and in its nucleic acid complexes, and the results were interpreted by using a two correlation time model that included contributions to relaxation from dipolar coupling and chemical shift anisotropy. Values for the internal motion correlation time and the overall motion correlation time are reported. The effect of 5FTA on the melting transition of the double-stranded polynucleotides and on the quenching of 5FTA fluorescence was also studied. The 19F NMR results support the model of partial intercalation of the 5FTA chromophore into the polynucleotides, and the implications for protein-nucleic acid interactions are discussed.

Spectroscopic analysis of the equilibrium and kinetic DNA binding properties of several actinomycin analogs.

Experiments are described that measure DNA dissociation kinetics and thermal denaturation temperatures for a series of actinomycin analogs containing, in the 3' amino acid position, pipecolic acid, proline or azetidine-2-carboxylic acid. Also included are studies on actinomycin C3. Analysis of the temperature dependence of the slowest rate constant for DNA dissociation shows that both the enthalpy and entropy of ativation increase as the ring size of the 3' amino acid decreases from six to five to four. All compounds increase the DNA melting temperature to the same extent except for the analog containing pipecolic acid, which shows a smaller effect. These results are discussed in terms of a possible role for conformational changes in the actinomycin pentapeptide lactone rings in determining the slow DNA dissociations rates for this class of intercalators. It is suggested that cis-trans isomerization of proline may be important in this regard.