Contribution of the resonance Raman spectroscopy to the identification of Z DNA

Poly(dG-dC).poly(dG-dC) at low salt concentration (0.1 M NaCl) and at high salt concentration (4.5 M NaCl) has been studied by Raman resonance spectroscopy using two excitation wavelengths: 257 nm and 295 nm. As resonance enhances the intensity of the lines in a proportion corresponding to the square of the molar absorption coefficient, the intensities of the lines with 295 nm wavelength excitation are enhanced about sevenfold during the B to Z transition. With 257 nm excitation wavelength the 1580 cm-1 line of guanosine is greatly enhanced in the Z form whereas with 295 nm excitation several lines are sensitive to the modifications of the conformation: the guanine band around 650 cm-1 and at 1193 cm-1 and the bands of the cytosines at 780 cm-1, 1242 cm-1 and 1268 cm-1. By comparison with the U.V. resonance Raman spectra of DNA, we conclude that resonance Raman spectroscopy allows one to characterize the B to Z transition from one line with 257 nm excitation wavelength and from three lines with 295 nm excitation. The conjoined study of these four lines should permit to observe a few base pairs being in Z form in a DNA.     

Conformational Transitions of Poly(dl-dC) in Aqueous Solution as Studied by Ultraviolet Resonance Raman Spectroscopy

Abstract

Poly(dI-dC) in aqueous solution can undergo different equilibrium geometries, which strongly depend on salt nature and concentrations. These equilibrium structures have been monitored by resonance Raman spectroscopy (RRS) measurements in the ultraviolet region, i. e. by using 257 and 281 nm laser excitation wavelengths which favor the resonance enhancement of the Raman contributions from inosine and cytosine residues of poly(dI-dC), respectively. Spectral changes depending on the NaCl concentration and on the presence of Ni²⁺ ions have been observed and interpreted in comparison with RRS results previously obtained for other alternating purine-pyrimidine polydeoxyribonucleotides, i.e. poly(dG-dC), poly(dA- dT) and poly(dA-dC). poly(dG-dT), which also showed B to Z conformational transitions in varying the salt concentrations. It is shown here that: i) the base stacking geometries are nearly the same in the high-salt form (5 M NaCl) of poly(dl-dC) as in the low-salt form (0.1M NaCl) of the polymer, ii) however, the high-salt structure yields important differences from a B-helix (obtained in low-salt solution) as regards the nucleoside conformations (sugar puckering and base-sugar orientation), and: iii) the addition of 9 mM NiCl₂ in the high-salt (5 M NaCl) solution of poly(dI-dC) induces the Z-conformation of the polymer.     

Kinetics of exchangeable protons in Z DNA: a UV resonance Raman study.

We have studied the hydrogen-deuterium exchange kinetics of the exchangeable protons of the poly(dG-dC).poly(dG-dC) in the Z form of the polymer, using resonance Raman spectroscopy with 257 nm and 284 nm excitation wavelengths. In our experimental conditions (4.5 M NaCl, phosphate buffer pH7, 2 degrees C) the two amino protons and the imino proton of guanine are exchanged with the same exchange half-time of 13 min, whereas the two amino protons of cytosine are exchanged with the same exchange half-time of 51 min.     

DNA Methylation Detection Using Resonance and Nanobowtie-Antenna-Enhanced Raman Spectroscopy

We show that DNA carrying 5-methylcytosine modifications or methylated DNA (m-DNA) can be distinguished from DNA with unmodified cytosine by Raman spectroscopy enhanced by both a bowtie nanoantenna and excitation resonance. In particular, m-DNA can be identified by a peak near 1000 cm^?1 and changes in the Raman peaks in the 1200–1700 cm^?1 band that are enhanced by the ring-absorption resonance. The identification is robust to the use of resonance Raman and nanoantenna excitation used to obtain significant signal improvement. The primary differences are three additional Raman peaks with methylation at 1014, 1239, and 1639 cm^?1 and spectral intensity inversion at 1324 (C₅=C₆) and 1473 cm^?1 (C₄=N₃) in m-DNA compared to that of DNA with unmodified cytosine. We attribute this to the proximity of the methyl group to the antenna, which brings the (C₅=C₆) mode closer to experiencing a stronger near-field enhancement. We also show distinct Raman spectral features attributed to the transition of DNA from a hydrated state, when dissolved, to a dried/denatured state. We observe a general broadening of the larger lines and a transfer of spectral weight from the ～1470 cm^?1 vibration to the two higher-energy lines of the dried m-DNA solution. We attribute the new spectral characteristics to DNA softening under high salt conditions and find that the m-DNA is still distinguishable via the ～1000 cm^?1 peak and distribution of the signal in the 1200–1700 cm^?1 band. The nanoantenna gain exceeds 20,000, whereas the real signal ratio is much less because of a low average enhanced region occupancy even with these relatively high DNA concentrations. It is improved when fixed DNA in a salt crystal lies near the nanoantenna. The Raman resonance gain profile is consistent with A-term expectations, and the resonance is found at ～259 nm excitation wavelength.     

Raman Spectroscopy Study of the B-Z Transition in (dG-dC)n · (dG-dC)n and a DNA Restriction Fragment

Abstract

The B to Z conformational transition of (dG-dC)_n·(dG-dC)_n and a 157 bp DNA restriction fragment were followed using Raman spectroscopy. The 157 bp DNA has a 95 bp segment from the E. coli lactose operon sandwiched between 26 and 32 bp of (dC-dG) sequences. Raman spectra of the DNAs were obtained at varying sodium chloride concentrations through the region of the transition. A data analysis procedure was developed to subtract the background curves and quantify Raman vibrational bands. Profiles of relative intensity vs. sodium chloride concentration are shown for bands at 626, 682, 831–833 and 1093 cm^?1. Both (dG-dC)_n·(dG-dC)_n and the 157 bp DNA show changes in the guanine vibration at 682 cm^?1 and backbone band at 831–3 cm^?1 preceeding a highly cooperative change in the 1093 cm^?1 PO 7 vibration. This result indicates that there are at least two conformational steps in the B to Z conformational pathway.

We review the effect of the (dC-dG) portion of the 157 bp DNA on the 95 bp segment. Comparison of Raman spectra of the 157 bp DNA, the 95 bp fragment and (dG-dC)_n·(dG- dC)_n indicate that in 4.5 M NaC/the (dC-dG) segments are in a Z-conformation. Base stacking in the 95 bp portion of the 157 bp DNA appears to maintain a B-type conformation. However, a substantial portion of this region no longer has a B-type backbone vibration.     

A study of the thermal stability of the Z form of (m5dC-dG)3 by resonance Raman spectroscopy.

The thermal stability of the hexanucleoside pentaphosphate m5dCpdGpm5dCpdGpm5 dCpdG has been studied by resonance Raman spectroscopy with 257 nm excitation wavelength. At low temperature and in 3M NaClO4, the Raman spectrum resembles that of poly(dG-dC).poly(dG-dC) in the Z conformation. As the temperature is increased, the position and the intensity of several bands (1312 cm-1, 1482 cm-1, 1584 cm-1 and 1632 cm-1) are modified. The variation of intensity versus temperature is biphasic. Analysis of the results suggests that the increase of temperature induces first a transition from the Z form to an intermediate stable form which then melts. These results and those previously obtained by circular dichroism and 31P nuclear magnetic resonance suggest that the intermediate form belongs to the left family but with changes in the stacking of the bases and the geometry of the phosphate groups as compared to the canonical Z form.     

Salt-induced conformational transition of poly(d2NH2A-dT) studied by ultraviolet resonance Raman spectroscopy.

The conformational changes of poly(d2NH2A-dT) in aqueous solution, induced by increasing the NaCl concentration from 0.1M to 4M, have been monitored by ultraviolet resonance Raman spectroscopy, in using the 222-, 257- and 281 nm excitation wavelengths. These changes have been interpreted in comparing the polymer spectra to those of the mononucleotide compounds on one hand, and to those of other alternating purine-pyrimidine polymers on the other hand, i.e. poly(dG-dC) and poly(dA-dT) which showed a B to Z transition in going from low- to high salt concentrations. The high salt poly(d2NH2A-dT) spectra do not show any Raman marker line of the Z conformation. The spectroscopic results indicate that most of the ribose puckering goes from C2'-endo/anti to C3'-endo/anti in increasing the salt concentration. In addition the base stacking interactions, to which the resonance Raman effect is very sensitive, are not drastically changed upon salt variations. Thus the high salt structure of poly(d2NH2A-dT) remains a right-handed helix, likely under a dominant A conformation.     

Intensity Changes of Base and Backbone Raman Modes in the B to Z Transition of poly(dG-dm5C)

Abstract

Raman spectroscopy was employed to investigate the temperature-induced B to Z transition of poly(dG-dm-⁵C). The transition midpoint was about 37°C for a solvent containing 20 mM Mg²⁺. A 10-fold change in Mg²⁺ concentration altered the transition midpoint by at least 60°C. Raman spectra of the B and Z forms of poly(dG-dm⁵C) exhibited characteristics similar to those observed with poly(dG-dC). The 682 cm^?1 guanine mode and 835 cm^?1 backbone mode were present in the B conformation. In the Z form the intensities of these two bands decrease substantially and new peaks were observed at 621 cm^?1, 805 and 819 cm¹. Several bands unique to poly(dG-dm⁵C) were also observed. Transition profiles of band intensity vs. temperature were determined for fourteen Raman bands. The curves of all of the base vibrations and one backbone mode had the same slope and midpoint. This indicates that conformational changes in the guanine and methycytosine bases occur concurrently.     

The Z-Conformation of Poly(dA-dT) · Poly(dA-dT) in Solution as Studied by Ultraviolet Resonance Raman Spectroscopy

Abstract

Poly(dA-dT) poly(dA-dT) structures in aqueous solutions with high NaCl concentrations and in the presence of Ni²⁺ ions have been studied with resonance Raman spectroscopy (RRS). In low water activity the effects of added 95 mM NiCl₂ in solution stabilize the syn geometry of the purines and reorganize the water distribution via local interactions of Ni-water charged complexes with the adenine N7 position. It is shown that RRS provides good marker bands for a left-handed helix: i) a purine ring breathing mode around 630 cm″^?1coupled to the deoxyribose vibration in the syn geometry, ii) a 1300-1340 cm^?1 region characterizing local chemical interactions of the Ni²⁺ ions with the adenien N7 position, iii) lines at about 1483-and 1582 cm^?1 correlated to the anti/syn reorientation of the adenine residues on B-Z structure transition, iv) marker bands of the thymidine carbonyl group couplings at 1680-and 1733 cm^?1 due to the disposition of the thymidine residues in the Z helix specific geometry. Hence poly(dA-dT) poly(dA-dT) can adopt a Z form in solution. The Z form observed in alternate purine-pyrimidine sequences does not require G-C base pairs.     

Ultraviolet Raman spectroscopy of polyribouridylic acid: Excitation profile of the hypochromism induced by order–disorder transition

Raman spectra of polyribouridylic acid excited in the uv region, from 363 to 290 nm, are reported. The conformational changes of the polymer from random coil to ordered structure with stacked bases at high and low temperature, respectively, are reflected by important changes in the Raman line intensities; this Raman hypochromism is itself a function of the excitation wavelength—its profile has been determined and shows negative values in the region of 290 nm (near resonance), i.e., hypochromism becomes hyperchromism. Thus the knowledge of the hypochromism excitation profile is important in following order–disorder transition of a polymer using resonance Raman spectroscopy. Theoretical attempts are proposed for explanation, involving not only the relative variations of the molar extinction coefficient on the order-disorder transition of the polymer, but also the damping factors of the vibronic levels. The theoretical curve is found to fit adequately the experimental data over the excitation range, using only the frequency of the O-O transition of uracil and a vibronic linewidth of 2200 cm^?1.     

Raman spectrum of protocatechuate dioxygenase from Pseudomonas putida. New low frequency bands.

The Raman spectrum (441.6 nm excitation) of protocatechuate 3,4-dioxygenase (PCD) from Pseudomonas putida shows resonance enhanced bands at 1605, 1504, 1270, 858, and 830 cm^?1 which are due to the p-hydroxyphenyl group of tyrosine coordinated to iron. In addition, we observe strong resonance enhanced bands at 592 and 524 cm^?1 and weak (presumably iron-ligand) vibrations at 465, 423, and 371 cm^?1. Recent publications of the Raman spectrum of PCD from Pseudomonas aeruginosa (Tatsuno $\text{et al}$, J. Am. Chem. Soc. 100, 4614–4615 (1978) and Keyes $\text{et al}$, Biochem. Biophys. Res. Comm. 83, 941–945 (1978) using 488 and 514 nm excitation did not report these bands. Our 441.6 nm excitation Raman spectrum of human serum transferrin, another metalloprotein with an iron-tyrosine linkage, does not show the 592 and 524 cm^?1 bands and has only two very weak bands at about 423 and 364 cm^?1. We discuss several interpretations of these data.     

Resonance raman study of the heme-linked ionization in reduced horseradish peroxidase

The resonance Raman spectra of reduced horseradish peroxidase (oxidoreductase, EC 1.11.1.7) and its cyanide complex in the 200–600 cm^?1 region were measured. Among many Raman lines observed, only the line at 244 cm^?1 (pH 6.5) exhibited the pH dependent frequency shift. This line disappeared in the cyanide complex. The 244-cm^?1 line was intense upon excitation at 441.6 nm but unrecognizable at 488.0 nm. Consequently this line is assignable to the Fe-N_ε (His, proximal) stretching mode in accord with the 220-cm^?1 line of the Fe-N_ε (His F8) stretching line of deoxy Mb. It is concluded that the ionization of an amino acid residue with pK_a = 7.17 is transmitted to heme $\text{via}$ Fe-N_ε (His) bond in the proximal side.     

The concentration dependence of the right to left conformational transition in natural DNA identified by Raman spectroscopy

The classical and resonance Raman spectra of DNA from Chicken Erythrocytes have been obtained for different DNA concentrations in solution with low and high ionic strengths. The classical Raman spectra of 30 mg/ml DNA solutions were measured in varying the sodium chloride concentration from 0.1 to 4.5 M NaCl. An increase in the salt content of the solution leads to spectral changes in the 600-700 cm-1 region, indicating a C2' endo/anti to C3' endo/syn conformational transition of the purine residues. Other changes around 840 cm-1, due to the antisymmetrical stretching vibration of the PO2 group, are also detected: they were characteristic for the B----Z transition in model systems such as poly(dG-dC).poly(dG-dC). The resonance Raman spectra of low (1 mg/ml) and high (30 mg/ml) concentrated DNA solutions were obtained with low (0.1 M) and high (4.5 M) NaCl contents, in using a 284 nm excitation wavelength. No change was observed in the intensities and band positions in the low and high salt solutions of low concentrated DNA. Thus it is assumed that the DNA structure remains unchanged whatever the salt concentration for low concentrated DNA. In contrast, great modifications of the intensities and positions of some lines were found in the spectra of high DNA concentration solution when the NaCl content is increased up to 4.5 M: these changes resemble to some extent those observed in the study of B----Z transition of several polynucleotide model compounds. It is assumed that the right-handed to left-handed conformational transition may occur in certain sections of natural DNA, likely containing alternating purine-pyrimidine sequences, when the DNA concentration is sufficiently important.     

Resonance Raman on the purple intermediates of the flavoenzyme D-amino acid oxidase

Resonance Raman (RR) spectra excited at 632.8 nm within a charge transfer absorption band were obtained for a catalytic intermediate, the purple complex of D-amino acid oxidase with D-proline or D-alanine as a substrate. The resonance enhanced Raman lines around 1605 and 1360 cm^?1 in either of the complexes were suggested to be derived from vibrational modes of reduced flavin molecule. Since the highest energy band at 1692 cm^?1 in the RR spectrum with D-alanine was shifted to 1675 cm^?1 upon [¹⁵N] substitution of alanine and ammonium, this Raman line in the spectrum with D-alanine or the line at 1658 cm^?1 with D-proline is assigned to the CN stretching mode of an imino acid corresponding to each amino acid. These results confirm the concept that the purple intermediate of D-amino acid oxidase consists of reduced flavin and an imino acid.     

Resonant Raman quantification of zeaxanthin production from Flavobacterium multivorum

Resonant Raman scattering was used as a novel, rapid, non-destructive optical technique to measure zeaxanthin levels in Flavobacterium multivorum ATCC 55238. Culture broth, after bacterial growth for 40 h, exhibited characteristic resonance Raman vibrational modes at 1159 cm^–1 (C-C stretch) and 1525 cm^–1 (C=C stretch) upon excitation at 488 nm. A striking correlation was observed between the carotenoid level as estimated by HPLC and by resonance Raman spectroscopy.     

UV resonance Raman spectroscopy of DNA and protein constituents of viruses: Assignments and cross sections for excitations at 257, 244, 238, and 229 nm

Ultraviolet resonance Raman (UVRR) spectra of H₂O and D₂O solutions of the nucleoside (dA, dG, dC, dT) and aromatic amino acid (Phe, Trp, Tyr) constituents of DNA viruses have been obtained with laser excitation wavelengths of 257, 244, 238, and 229 nm. Using the 981 cm⁻¹ marker of Na₂SO₄ as an internal standard, Raman frequencies and scattering cross sections were evaluated for all prominent UVRR bands at each excitation wavelength. The results show that UVRR cross sections of both the nucleosides and amino acids are strongly dependent on excitation wavelength and constitute sensitive and selective probes of the residues. The results provide a library of UVRR marker bands for structural analysis of DNA viruses and other nucleoprotein assemblies. © 1998 John Wiley & Sons, Inc. Biopoly 45: 247–256, 1998     

Identification of a new electronic transition in the Z form of poly(dG-dC)·poly(dG-dc) by infrared absorption and resonance Raman spectroscopy

Infrared absorption and resonance Raman spectroscopy (RRS) are used to study poly(dG-dC)·poly(dG-dC) in two different forms: the right-handed B form at low ionic strength and the left-handed Z form at high ionic strength. The existence of a new electronic absorption band in the 290–300-nm region is evidenced by uv RRS studies of the Z form at different wavelengths of excitation. Infrared absorption spectra prove that this new electronic band is polarized perpendicularly to the cytosine plane. The possibility of a nπ* character of this transition moment is discussed.     

Ultraviolet resonance Raman marker bands of the right to left helix structure transitions in DNA and polynucleotide model compounds.

The right to left helix structural transition in purine-pyrimidine alternating copolymers has been extensively studied by vibrational spectroscopies, amongst many other experimental approaches. Here, the use of resonance Raman spectroscopy in the ultraviolet region (223-, 257- and 281 nm excitation wavelengths) to monitor such structural changes is reviewed in the light of new results obtained on poly(dA-dC).poly(dG-dT) on one hand, and the previous results obtained on poly(dG-dC)2, poly(dA-dT)2 and natural DNA (Chicken erythrocytes) on the other. It is now possible to define B----Z transition marker bands involving the proper bases, which show a similar behaviour on structural transition whatever the composition of alternating purine-pyrimidine sequences: the 1580- and 1487 cm-1 lines of the purines, the 1486- and 1294 cm-1 lines of the pyrimidines are good markers in the vibrational spectra recorded at various UV excitation wavelengths.     

Three Dimensional Association of Double-Stranded Helices Are Produced in Conditions for Z-DNA Formation

Abstract

The Z form of alternating poly(dG-dC)·poly(dG-dC) can be induced when the concentration of NaCl, MgCl₂ or ethanol are increased. In order to obtain more information concerning this Z structure, the B?Z transition is analyzed on the same sample, both by UV spectrophotometry and electron microscopy. The procedures used in this work provide high resolution images with minimal alterations of the molecules. It is shown that at high vlaues of cations or ethanol, the polymer makes complex associations of numerous molecules stuck together parallelly. By decreasing the salt or ethanol concentrations, a progressive decondensation of the molecules is obtained. At low concentrations of Mg⁺⁺ (2.10^?2 M), alterations of the linear secondary structure of the molecules are observed, although the UV spectrum is of the B-type. In the presence of that low concentration of Mg⁺⁺, natural DNAs (øX174 and yeast mitochondrial DNA fragment inserted in pBR) exhibit structural modifications similar to those observed with the poly(dG-dC)·poly(dG-dC). These structures mainly consist in four-stranded hairpins and loops built up by the sticking of two segments of DNA. The correlation between these intertwining of short DNA segments and the presence of potentially Z-forming sequences is discussed.     

Hypericin Site Specific Interactions Within Polynucleotides Used as DNA Model Compounds

Summary

Interactions of the antiretroviral hypericin molecule with polynucleotides, i.e. poly(dG-dC), poly(dA-dT), poly(rG) and poly(rC), have been studied in aqueous solutions by resonance Raman spectroscopy, using an UV excitation wavelength which induces a specific resonance enhancement of spectral band intensities corresponding to proper nucleic base modes of vibration. It is shown that : i) hypericin selectively interacts with the N7 sites of purines, ii) the strength of interaction depends on the polymer structure, and : iii) interaction with guanine is stronger than with adenine molecules.