Applications of Raman spectroscopy to investigate the molecular constituents of nucleic acids were initiated in the late 1960s and soon thereafter progressed to studies of synthetic and native nucleic acids and complex biological assemblies containing either DNA or RNA. Raman applications to nucleic acids have continued to increase in number and diversity up to the present time. This paper attempts to provide an overview of this large body of work, with emphasis on studies carried out during the past decade and focusing on problems of biological interest and significance. The specific Raman methodologies included in this review of nucleic acid applications are (i) conventional Raman spectroscopy (i.e. off-resonance Raman excitation), (ii) ultraviolet resonance Raman (UVRR) spectroscopy, and (iii) polarized Raman microspectroscopy. For each methodology, the experimentally obtained nucleic acid spectrum consists of a number of discrete vibrational bands, most of which can be assigned confidently to a base, sugar or phosphate constituent of the macromolecule and many of which can be employed as sensitive indicators or fingerprints of either local structure, global conformation, intermolecular interaction or molecular dynamics. The applications selected for review include numerous examples from the authors' laboratories. The topics addressed include the influences of base composition, base sequence, superhelical stress and drug ligation on nucleic acid structure and polymorphism, the thermodynamic parameters governing nucleic acid premelting and melting phenomena, the molecular mechanisms and determinants of protein/nucleic acid recognition and the structures and dynamics of nucleic acids in virus assemblies.
Polarized Raman spectra of oriented fibers of calf thymus DNA in the A and B conformations have been obtained by use of a Raman microscope operating in the 180 degrees back-scattering geometry. The following polarized Raman intensities in the spectral interval 200-1800 cm-1 were measured with both 514.5 and 488.0 nm laser excitations: (1) Icc, in which the incident and scattered light are polarized parallel to the DNA helical axis (c axis); (2) Ibb, in which the incident and scattered light are polarized perpendicular to c; and (3) Ibc and Icb, in which the incident and scattered light are polarized in mutually perpendicular directions. High degrees of structural homogeneity and unidirectional orientation were confirmed for both the A and B form fibers, as judged by comparison of the observed Raman markers and intensity anisotropies with measurements reported previously for oligonucleotide single crystals of known three-dimensional structures. The fiber Raman anisotropies have been combined with solution Raman depolarization ratios to evaluate the local tensors corresponding to key conformation-sensitive Raman bands of the DNA bases and sugar-phosphate backbone. The present study yields novel vibrational assignments for both A DNA and BDNA conformers and also confirms many previously proposed Raman vibrational assignments. Among the significant new findings are the demonstration of complex patterns of A form and B form indicator bands in the spectral intervals 750-900 and 1050-1100 cm-1, the identification of highly anisotropic tensors corresponding to vibrations of base, deoxyribose, and phosphate moieties, and the determination of relatively isotropic Raman tensors for the symmetrical stretching mode of phosphodioxy groups in A and B DNA. The present fiber results provide a basis for exploitation of polarized Raman spectroscopy to determine DNA helix orientation as well as to probe specific nucleotide residue orientations in nucleoproteins, viruses, and other complex biological assemblies.
The filamentous virus fd consists of a single-stranded DNA genome sheathed by 2700 copies of a 50-residue alpha-helical subunit (protein pVIII) and serves as a model assembly of alpha-helices. To advance vibrational assignments for the alpha-helix, we have investigated Raman spectra of fd virions containing 13C and 2H (deuterium) labels at various main-chain sites of the pVIII subunits. 13C was introduced at specific peptide carbonyls, while deuterium was introduced at selected alpha-carbon (Calpha) and amide nitrogen positions. Interpretation of the Raman spectra reveals a previously unrecognized alpha-helix band in the spectral interval 730-745 cm-1, tentatively assigned to a carbonyl in-plane bending mode (amide IV). Experimental evidence has also been obtained for a distinctive alpha-helix marker near 1345 cm-1, assigned to a coupled Calpha-H bending and Calpha-C stretching mode. The fd virions containing 13C-labeled carbonyls exhibit unexpectedly complex amide I profiles, consisting of multiple band components. Amide I splitting resulting from 13C substitution of carbonyls is attributed to decoupling of transition-dipole interactions normally occurring in the extended pVIII helix. The present study identifies novel conformation-dependent Raman bands in a native alpha-helix assembly, confirms amide I and amide III assignments proposed previously for filamentous viruses, and facilitates new Raman assignments for the packaged ssDNA. The alpha-helix markers identified here should also be useful in conformation analyses of other proteins by Raman spectroscopy.
Site-specific isotope substitutions in the coat protein (pVIII) of the filamentous bacterial virus Ff (fd, fl, M13) have been employed to advance vibrational band assignments and facilitate structural interpretation of the Raman spectrum. We report spectra of phage fd assembled in vivo from pVIII subunits incorporating either deuteriophenylalanine (Fd5), deuteriotryptophan (Wd5), or deuteriotyrosine (Yd4) residues with labeled ring sites. The deuterated aromatics were introduced into fd individually and in combination. On the basis of observed isotope shifts, definitive assignments have been developed for all prominent Raman bands diagnostic of the pVIII aromatic residues (F11, F42, F45, W26, Y21, Y24). The present study constitutes the first direct experimental determination of Raman fingerprints of tyrosine and phenylalanine side chains within hydrophobic alpha-helical domains and yields unexpected results. Importantly, neither Y21 nor Y24 of pVIII exhibits the "canonical" Fermi doublet expected in the 820-860 cm-1 interval of the Raman spectrum. Instead, each tyrosine exhibits a single band near 853 cm-1. Since the application of denaturing conditions is sufficient to generate in fd an apparent Fermi doublet, it is concluded that the anomalous singlet is intrinsic to tyrosine environments in the native virion assembly. In addition, the Raman results clearly demonstrate an interdependence of the environments of aromatic side chains in virion subunits. We show that the results on fd isotopomers are also confirmed by Raman spectroscopy of Ff virions incorporating the tyrosine mutations Y21M, Y24M, and Y21F/Y24S. The Raman marker bands identified for pVIII aromatics modify and extend Raman correlations proposed previously for proteins. The unusual environments detected for aromatic residues in the mature Ff assembly are discussed in relation to recently proposed models for filamentous virion architecture.
The study of filamentous virus structure by Raman spectroscopy requires accurate band assignments. In previous work, site- and residue-specific isotope substitutions were implemented to elucidate definitive assignments for Raman bands arising from vibrational modes of the alpha-helical coat protein main chain and aromatic side chains in the class I filamentous phage, fd [Overman, S. A., and Thomas, G. J., Jr. (1995) Biochemistry 34, 5440-5451; Overman, S. A., and Thomas, G. J., Jr. (1998) Biochemistry 37, 5654-5665]. Here, we extend the previous methods and expand the assignment scheme to identify Raman markers of nonaromatic side chains of the coat protein in the native fd assembly. This has been accomplished by Raman analysis of 11 different fd isotopomers selectively incorporating deuterium at specific sites in either alanine, aspartic acid, glutamic acid, glycine, isoleucine, leucine, lysine, serine, or valine residues of the coat protein. Raman markers are also identified for the corresponding deuterated side chains. In combination with previous assignments, the results provide a comprehensive understanding of coat protein contributions to the Raman signature of the fd virion and validate Raman markers assigned to the packaged single-stranded DNA genome. The findings described here show that nonaromatic side chains contribute prolifically to the fd Raman signature, that marker bands for specific nonaromatics differ in general from those observed in corresponding polypeptides and amino acids, and that the frequencies and intensities of many nonaromatic markers are sensitive to secondary and higher-order structures. Nonaromatic markers within the 1200-1400 cm-1 interval also interfere seriously with the diagnostic Raman amide III band that is normally exploited in secondary structure analysis. Implications of these findings for the assessment of protein conformation by Raman spectroscopy are considered.
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