Carbon-13 nuclear magnetic resonance studies of cobalamins

The carbon-13 nuclear magnetic resonance spectra of aquocobalamin, adenosylcobalamin, methylcobalamin, and (carboxymethyl)cobalamin have been interpreted. The assignments were made by a comparison of the spectra with that of cyanocobalamin, by a study of the pH dependence of the chemical shifts, by an analysis of the effect of the axial ligands on the carbon atoms of the corrin ring, and by a study of the specific line broadening effect of the paramagnetic ions Mn2+ and Gd3+. The chemical shift changes that accompany the "base-on"----"base-off" conversion of the organocobalamins demonstrate that the conformation of the "western" half of the corrin ring and the conformations of the a, b, c, d, f, and g side chains are relatively constant. In contrast, the conformations of the "eastern" half of the corrin ring and the e propionamide side chain are highly variable.     

Carbon-13 nuclear magnetic resonance spectra of lignins

From the ¹³C-nmr spectra of a large number of dimeric and monomeric lignin model compounds the chemical shifts of the carbon atoms of the C₉-units in lignin with different substitution patterns were determined. The absorption peaks of the carbon-13 spectra of two lignins (beech and spruce) could be assigned by comparison (Table 3).     

Carbon-13 nuclear magnetic resonance studies of acetate metabolism in intact cells of Rhodopseudomonas sphaeroides

¹³C-nuclear magnetic resonance was used to study the metabolism of [2-¹³C]acetate in suspensions of Rhodopseudomonas sphaeroides. In the dark, in logarithmic-phase cells the ¹³C label appeared first in butyrate C-2 and C-4 and subsequently in glutamate C-4 and succinate C-2 and C-3. In the light, synthesis of poly(β-hydroxybutyrate) (PHB) takes place. Butyrate synthesis seems to be independent of PHB synthesis or degradation activity. Starved, logarithmic-phase cells also show massive synthesis of PHB in the dark. Stationary-phase cells incorporate ¹³C predominantly into glutamate and succinate. No significant butyrate biosynthesis can be detected in the dark or during illumination. The incorporation of label in PHB is very slow in these cells and most probably originates from exchange of ¹²C for ¹³C into PHB. This might indicate slow turnover without net synthesis of the polymer occurring under these conditions. The results are discussed in relation to the redox state and the availability of metabolic energy for biosynthetic reactions in the dark and during illumination of cell suspensions of Rps. sphaeroides.     

Carbon-13 nuclear magnetic resonance studies of spironolactone and several related steroids

The ¹³c chemical shifts for all the carbon atoms in spironolactone have been assigned. Assignments for nine additional steroids which include the C-7β isomer of spironolactone, its C-7 thiol hydrolysis product, the 7α-thioacetate derivative of testosterone and its thiol hydrolysis product are also reported.     

Metabolism of methanol in plant cells. Carbon-13 nuclear magnetic resonance studies

Using (13)C-NMR, we demonstrate that [(13)C]methanol readily entered sycamore (Acer pseudoplatanus L.) cells to be slowly metabolized to [3-(13)C]serine, [(13)CH(3)]methionine, and [(13)CH(3)]phosphatidylcholine. We conclude that the assimilation of [(13)C]methanol occurs through the formation of (13)CH(3)H(4)Pte-glutamate (Glu)(n) and S-adenosyl-methionine, because feeding plant cells with [3-(13)CH(3)]serine, the direct precursor of (13)CH(2)H(4)Pte-Glu(n), can perfectly mimic [(13)CH(3)]methanol for folate-mediated single-carbon metabolism. On the other hand, the metabolism of [(13)C]methanol in plant cells revealed assimilation of label into a new cellular product that was identified as [(13)CH(3)]methyl-beta-D-glucopyranoside. The de novo synthesis of methyl-beta-D-glucopyranoside induced by methanol did not require the formation of (13)CH(3)H(4)Pte-Glu(n) and was very likely catalyzed by a "transglycosylation" process.     

Natural abundance 13C nuclear magnetic resonance studies of live cestodes

1. Natural abundance carbon-13 nmr spectra of several intact cestodes have been obtained. 2. All spectra show peaks assignable to triglycerides and the N(CH3)3 carbons of the choline moiety. 3. The olefinic region of the 13C nmr spectra indicated that the cestode larvae Mesocestoides corti and Echinococcus multilocularis have a larger concentration of polyunsaturated fatty acids than Hymenolepis adults. 4. Mobile fragments of glycogen were detected in all species studied, but its apparent concentration in individual cestodes was highly variable.     

Carbon-13 nuclear magnetic resonance spectra of carbohydrate oxirane derivatives

The ¹³C-chemical shifts and ¹J_C,H values of two series of carbohydrate oxirane derivatives, namely methyl 2,3-anhydro-ribo- and -lyxofuranosides and methyl 2,3-anhydro-4,6-O-benzylidene-manno- and -allopyranosides have been determined. The assignment of ¹³C resonances has been established mainly by the examination of the proton-coupled and the selective proton-decoupled spectra. The effect of the oxirane rings on the chemical shifts of β and γ carbon atoms (from the oxirane ring oxygen atom) has been observed. Large ¹J_C,H values associated with cis CH bonds adjacent to the oxirane rings relative to those of trans counterparts have been found.     

Carbon-13 nuclear magnetic resonance studies on tobacco mosaic virus and its protein.

Fourier transform nuclear magnetic resonance studies on 12% 13C-enriched tobacco mosaic virus (TMV) and its rod-like protein oligomers in solution with molecular weights up to 42 X 10(6) are reported. In the virus approximately 17% of the carbons of the protein subunit have line widths of less than or equal to 300 Hz and T1 less than or equal to 1 s and are concluded to be mobile with more than one degree of freedom of internal rotation about a carbon--carbon bond. In the rodlike polymer of TMV protein at pH 5.3, 30% of the carbons are mobile, which implies rotational motions about carbon--carbon bonds and/or motions of the protein subunits within the polymer. The presence of internal mobility is supported by the observation that 20% of the carbons in the double disklike oligomer show decreasing line width upon increasing temperature; the remaining resonances have line widths which are temperature independent during the double disklike polymerization process. Since the molecular weight of TMV protein polymers increases with increasing temperature, this demonstrates that all nuclei within the double dislike oligomer are mobile. NMR and X-ray data on the double disklike polymer reveal differences with respect to internal mobility.     

Carbon-13 nuclear magnetic resonance studies of polyamino acids: the helix-coil transition of poly-L-lysine

The helix-coil transition of poly-l-lysine hydrochloride ((Lys)_n) in aqueous solution has been studied by ¹³C Fourier-transform nuclear magnetic resonance spectroscopy. As reference compounds dodeca-l-lysine hydrobromide ((Lys)^?₁₂, tri-l-lysine hydrochloride ((Lys)₃), and l-lysine hydrochloride (Lys), have been also studied by the same method. It is found that ¹³C spin-lattice relaxation times t₁ of the carbonyl and the side-chain carbons decrease sharply at pD 10.2 which is the midpoint of the transition from the random-coil to the α-helix. Similarly the T₁ values of the carbonyl groups of (Lys)^?₁₂ decrease at this point in a more moderate way, while no change is observed for those of the side-chain carbons. This is interpreted in terms of the reduced α-helicity involved for (Lys)^?₁₂.The variation of ¹³C chemical shifts with pD for (Lys)_n and (Lys)^?₁₂ show the same trend:downfield shifts at higher pD. Furthermore, nonterminal and C-terminal residues of (Lys)₃ show similar behavior. Thus it is concluded that the ¹³C chemical shift changes are caused mainly by the pD changes and not by the conformational transition. Conversion from α-helix to β-structure by elevation of temperature at pD 11.2 results in narrowing and downfield shifts of the ¹³C resonances of (Lys)_n.     

Carbon-13 nuclear magnetic resonance studies of adenosylcobalamin and alkylcorrinoids, selectively enriched with carbon-13.

The carbon-13 nuclear magnetic resonance spectra of a series of alkylcorrinoids, selectively enriched with 13C in the alkyl ligand, were recorded at 25.2 MHz and 25 degrees. The nature of the axial ligands markedly affects the chemical shift of the labeled alkyl moiety (trans effect) as well as the 13C resonances of selected carbon atoms of the corrin ring (cis effect). Although a number of factors appear to influence the trans effect on the chemical shift of the alkyl ligand (important among them being electric field effects), the cis effect appears to be dominated by changes in charge density (at the methine bridge carbon atoms, C-5, C-10, C-15) and by steric effects (at the methyl groups at C-1, C-5, and C-15) accompanying axial ligation. Spin-latice relaxation times of several organocorrinoids, selectively labeled with 13C in the ligands attached to cobalt, were also measured. The T1 values of the methylene carbons of [5'-13C]adenosylcobalamin and [2-13C]carboxymethylcobalamin are very similar to that of the methine bridge carbon atom C-10 of the corrin ring, indicating that rotation about the carbon-cobalt bond of these two corrinoids is severely restricted. On the other hand, internal rotation about the carbon-cobalt bond of methylcobalamin is rapid.     

Structure and metabolism of mammalian liver glycogen monitored by carbon-13 nuclear magnetic resonance

Natural-abundance 13C NMR signals from glycogen are observable in situ within the perfused livers of rats. The nuclear magnetic relaxation properties (T1, T2, eta + 1) of glycogen were measured for glycogen in situ and in vitro and were found to be identical. All of the carbon nuclei in glycogen contribute to the high-resolution NMR spectrum, in spite of glycogen's very large molecular weight. The metabolism of glycogen in situ in the perfused rat liver was followed by 13C NMR. Stimulation of the fed rat liver by physiological glucagon levels led to rapid glycogenolysis. Perfusion of the liver with [1-13C]glucose led to net glycolysis, with concomitant scrambling of the label from C1 to C6 due to triosephosphate isomerase activity.     

Carbon-13 nuclear magnetic resonance spectroscopy of flavonoid and isoflavonoid compounds

The ¹³C NMR spectra of 15 flavonoid and 9 isoflavonoid substances of various ring C oxidiation states were analyzed and their carbon shifts assigned. In the case of 3 terpenic flavones and two glycoflavones linewidths were related qualitatively to molecular segmental motion.     

Carbon-13 and proton nuclear magnetic resonance studies on methyl aldofuranosides and their O-alkyl derivatives

The effect of O-alkylation on the carbon-13 n.m.r. spectra of methyl pentofuranosides has been determined. O-Alkylation of an OH group displaced the signal of the appended.¹³C nucleus downfield, whereas the adjacent ¹³C nuclei were, in most instances, shifted upfield to a smaller extent. The effect of O-methylation was appreciably larger than O-isopropylation or O-glycosylation, but either O-methyl or O-isopropyl derivatives may be used as models for interpreting the spectra of furanoid oligo- and poly-saccharides, including the galactomannan of Penicillium charlesii. The signal displacements are, to a large extent, comparable to those observed in the conformationally more stable mannopyranose series, so that they are insensitive to effects of steric distortion and population (or both). These effects occurred on 3-O-alkylation of methyl pentofuranosides, as appreciable changes in J_1,2 values in their p.m.r. spectra were observed.     

Carbon-13 nuclear magnetic resonance spectra of D-homoannulated 17-hydroxypregnan-20-ones

The 13C-NMR spectra of several groups of isomeric D-homoannulated 17 alpha-hydroxypregnan-20-ones have been recorded. The chemical shifts of the various carbon atoms have been correlated with the structures of the different isomers.     

Carbon-13 nuclear magnetic resonance studies of cerebroside derivatives and their properties in lecithin bilayers (1)

The ¹³C NMR chemical shifts and spin-lattice relaxation times of D-galactosylsphingosine derivatives in CDCl₃-CD₃OD and in egg-yolk lecithin vesicles in D₂O, and of N-acetylpsychosine micelles, are reported. Results with sonicated, unilamellar vesicles containing cerebroside and EYL^a show that (1) cerebrosides decrease the fluidity of the lecithin bilayer membrane and have the greatest effect on the glycerol backbone and choline methyl carbons. (2) N-acetylpsychosine experiences a greater freedom of motion in the galactose region than does cerebroside and does not reduce the fluidity of the lecithin as much as cerebroside. (3) Ac-Psy/EYL vesicles formed are permeable to Yb³⁺ but cerebroside/lecithin vesicles are not. (4) The choline groups on the inner bilayer surface are less mobile than those on the outer surface according to preliminary T₁ measurements of the Yb³⁺-separated resonances. (5) Yb³⁺-induced chemical shifts of choline methyl and choline $\text{C}\text{H}{}_2$OP peaks in mixed cerebroside-lecithin vesicle systems indicate a small preference for cerebroside in the outside monolayer. The data show that these molecules have significant effects on bilayer conformational mobilities, particularly near the surface, and thus demonstrate one mechanism for modulation of cell surface properties by glycosphingolipids.     

Carbon-13 and proton nuclear magnetic resonance of unsonicated model and mitochondrial membranes

Proton nuclear magnetic resonance (PMR) spectra at 270 MHz of aqueous dispersions of nonsonicated egg lecithin, dipalmitoyl lecithin, egg lecithin-cholesterol (1 : 1) and dipalmitoyl lecithin-cholesterol (1 : 1), together with PMR spectra of mitochondrial membranes and their extracted lipids, have been obtained.Carbon-13 nuclear magnetic resonance (CMR) spectra at 25.2 MHz of egg lecithin, egg lecithin-cholesterol (1 : 1) and sphingomyelin, together with CMR spectra of chloroplast and mitochondrial membranes, and erythrocyte ghosts, have also been obtained. The results obtained using CMR appear very promising for further study of intact membrane structure.It is suggested, on the basis of CMR evidence, that the proteins in mitochondrial membranes may be considerably less mobile than the lipids.     

Carbon-13 nuclear magnetic resonance study of spin labelled cholesteryl ester in model membranes

Carbon-13 NMR longitudinal relaxation times for unilamellar vesicles of egg phosphatidyl-choline (PC) in aqueous dispersion have been measured following the incorporation of spin labelled cholesteryl palmitate. The spin label induced relaxation rates. 1/T_1.5L, for fatty acyl chain carbons show that the C5 segment of the cholesteryl ester acyl chain is located near the C1 and C2 segments of the phospholipid acyl chains. A greater spin label induced enhancement of relaxation rate was observed for the inner vesicle layer than for the outer, and is attributed to a higher ester incorporation and/or tighter lipid packing in the inner layer.