Quantification of 4-hydroxyifosfamide in plasma of ifosfamide-treated mice.

PURPOSE: Ifosfamide is becoming an important clinical anticancer drug. Meaningful pharmacology studies require quantification of its activated and active metabolites, 4-hydroxyifosfamide (HOIfos) and isophosphoramide mustard (IPM), respectively. METHODS: Current methodology for quantifying the unstable HOIfos in biological fluids consists of trapping acrolein as it is produced during the decomposition of this metabolite. However, unlike cyclophosphamide, ifosfamide is extensively metabolized to two dechloroethylated metabolites, which are susceptible to 4-hydroxylation and similarly are capable of yielding acrolein upon decomposition. Because the current method has the potential to yield higher than actual values for HOIfos, it was compared with an HOIfos-specific method that traps the first stage degradation product of HOIfos, aldoifosfamide, as its semicarbazone, and depends on the use of radiolabeled drug for quantification. Six experiments in mice were conducted with blood collection 15 or 30 min after drug treatment followed by determination of HOIfos in plasma by the two methods. RESULTS: Comparison of plasma levels of HOIfos determined by the two methods indicated only minor differences between the two. CONCLUSION: These results suggest the possibility that the nonspecific method may be acceptable as a first estimation of levels of this metabolite in biological fluids until the development of a specific method that does not require radiolabeled drug, such as high-performance liquid chromatography or gas chromatography/mass spectrometry, has been developed.

Nuclear magnetic resonance study of the conformation and dynamics of beta-casein at the oil/water interface in emulsions.

A (13)C and (31)P nuclear magnetic resonance (NMR) study has been carried out on beta-casein adsorbed at the interface of a tetradecane/water emulsion. (13)C NMR spectra show signals from the carbonyl, carboxyl, aromatic, and C alpha carbons in beta-casein, well resolved from solvent resonances. Only a small fraction of all carbon atoms in beta-casein contribute to detectable signals; intensity measurements show that the observable spectrum is derived from about 30 to 40 amino acid residues.(31)P NMR spectra show signals from the five phosphoserines on the hydrophilic N-terminal part of the protein. Analysis of T(1) relaxation times of these nuclei, using the model free approach for the spectral density function and the line shape of the alpha-carbon region, indicates that a large part of the protein is in a random coil conformation with restricted motion and a relatively long internal correlation time. The NMR results show that the conformation and dynamics of the N-terminal part of beta-casein are not strongly altered at the oil/water interface, as compared to beta-casein in micelle-like aggregates in aqueous solution.

Combined effects of light and water stress on chloroplast volume regulation.

A nuclear magnetic resonance technique was used to measure changes in the water content of Acer platanoides chloroplasts in leaf discs that had reached osmotic equilibrium with external solutions either in the dark or under exposure to light. Results showed that chloroplast volume regulation (CVR) maintained constant water content in the chloroplasts over a range of water potentials in the dark, but CVR failed when the water potential fell below a critical value. The critical potential was lower in the dark in sun leaves than in shade leaves. Upon exposure to intense light, CVR remained effective in sun leaves over the same range as in the dark, but it failed in shade leaves at all water potentials. Osmolytes are necessary for CVR, but KCl is relatively ineffective; increased concentrations of intracellular KCl did not fully support an increase in the range of CVR. The results indicate that leaves need reserve supplies of cytosolic osmolytes to maintain CVR at low water potentials, and a larger reserve supply is needed in leaves that are exposed to intense light.

Nuclear magnetic resonance study of spin relaxation and magnetic field gradients in maple leaves.

1H Nuclear magnetic resonance techniques were used to measure the distributions of spin-spin relaxation times, T2, and of magnetic field gradients in both the chloroplast and nonchloroplast water compartments of maple leaves (Acer platanoides). Results showed that encounters between water molecules and membranes inside chloroplasts provide an inefficient relaxation mechanism; i.e., chloroplast membranes interact weakly with water molecules. Gradient measurements indirectly measured the sizes of chloroplasts by showing that water in the chloroplasts is confined to small compartments a few microns in diameter. A comparison between measured gradients and gradients calculated for a model leaf indicated that chloroplasts are somewhat more likely to occupy positions along cell walls adjacent to air spaces, but also they may be found in the interiors of cells.

A nuclear magnetic resonance imaging technique designed for studies of water in plant leaves.

A new imaging technique is described which uses nuclear magnetic resonance (NMR) to create a water profile of plant leaves. The water profile shows the average distribution of water as a function of depth into a leaf along a line perpendicular to the leaf surface; it can be used to measure the thickness of cell layers and the quantity of water in each layer. Two-dimensional NMR methods were used to avoid chemical shift distortion which degrades the resolution in leaf images made by conventional NMR techniques; image resolution was improved further by deconvolution analysis. To illustrate its application, the technique was used to follow changes in the internal structure of developing leaves.

In vivo study of chloroplast volume regulation.

This paper describes a new technique that can be used to study chloroplast volume regulation in vivo. Nuclear magnetic resonance spectroscopy was used to measure relative amounts of chloroplast water in Acer platanoides leaves as they dried in air, and also in leaf disks exposed to aqueous polyethylene glycol, sucrose, or glycerol. The chloroplasts retained a constant quantity of water as leaf water potentials varied between -0.05 and -1.90 MPa, indicating that volume regulation was effective throughout this range. The chloroplasts lost water when the water potential fell below -1.90 MPa, except when leaf disks were exposed to glycerol, suggesting that the lower limit of effective volume regulation is determined by physiological levels of osmotic solutes and that glycerol can be used for chloroplast osmoregulation.

Identification of 7-(2-hydroxyethyl)guanine as a product of alkylation of calf thymus DNA with clomesone.

Evidence at the molecular level is presented in support of alkylation of O6-guanine moieties of DNA as the mechanism of cytotoxicity of Clomesone to HT-29 cells and consists in the isolation and identification of a product resulting from alkylation of calf thymus DNA with Clomesone, followed by depurination to yield 7-(2-hydroxyethyl)guanine, whose formation is reasonably explained by O6-guanine chloroethylation followed by intramolecular alkylation at N7 of guanine and subsequent hydrolysis to the hydroxyethylguanine.

Effects of modifications of the retinal beta-ionone ring on archaebacterial sensory rhodopsin I.

Ring desmethyl and acyclic analogues of all-trans retinal were incorporated into the apoprotein of the phototaxis receptor sensory rhodopsin I (SR-I) in Halobacterium halobium membranes. All modified retinals generate SR-I analogue pigments which exhibit "opsin shifts," i.e., their absorption spectra are shifted to longer wavelengths compared with model protonated Schiff bases of the same analogues. Each SR-I pigment analogue exhibits cyclic photochemical reactions as monitored by flash spectroscopy, but the analogue photocycles differ from that of native SR-I by exhibiting pronounced biphasic recovery of flash-induced absorption changes and abnormal flash-induced absorption difference spectra. Despite perturbations in the photochemical properties, the SR-I pigment analogues are capable of both attractant (single photon) and repellent (two photon) phototaxis signaling in cells. Our interpretation is that the hydrophobic ring substituents interact with the binding pocket to maintain the correct configuration for native SR-I absorption and photochemistry, but these interactions are not essential for the physiological function of SR-I as a dual attractant/repellent phototaxis receptor. These results support the conclusion emerging from several studies that the photoactivation process that triggers the conformation changes of SR-I and the related proton pump bacteriorhodopsin is conserved despite the different biological functions of their photoactivation.

More manganese accumulates in maple sun leaves than in shade leaves.

Nuclear magnetic resonance and neutron activation analysis were used to measure manganese concentrations in leaves of Acer platanoides. Mn was found to accumulate in both the vacuoles and the chloroplasts, with more Mn (per unit area) in sun leaves than in shade leaves. No Mn was lost at senescence. Different seasonal patterns of Mn accumulation were found in sun and shade leaves. The quantity of chloroplast reserve Mn (bound to the outer surface of thylakoid membranes) increased rapidly in sun leaves from bud-break through midsummer, and then remained approximately constant through senescence. In shade leaves, however, the quantity of reserve Mn increased slowly, and at approximately a constant rate throughout the growing season.

Thermal damage to chloroplast envelope membranes.

Nuclear magnetic resonance was used to detect thermal injury to chloroplasts in vivo. A lesion occurs in the chloroplast envelope membrane at temperatures between 53 degrees C and 57 degrees C, depending on species, leaf condition, and heating rate. The injury is associated with a sudden loss of water from the chloroplast.

Water is allocated differently to chloroplasts in sun and shade leaves.

Hydrogen-1 nuclear magnetic resonance spectroscopy was used to study water allocation in cell compartments of sun and shade leaves. NMR spectra of Acer platanoides were resolved into two peaks that were assigned to chloroplast and nonchloroplast water. Sun leaves contained 1.7 times more water per unit area of surface than shade leaves, and the water was allocated differently. Chloroplasts in sun leaves contained 17% of the total leaf water versus 47% in shade leaves. Comparing equal leaf surface areas, the chloroplasts in shade leaves contained 60% more water than those in sun leaves.

Kinetically resolved states of the Halobacterium halobium flagellar motor switch and modulation of the switch by sensory rhodopsin I.

Spontaneous switching of the rotation sense of the flagellar motor of the archaebacterium Halobacterium halobium and modulation of the switch by attractant and repellent photostimuli were analyzed by using a computerized cell-tracking system with 67-ms resolution coupled to electronic shutters. The data fit a three-state model of the switch, in which a Poisson process governs the transition from state N (nonreversing) to state R (reversing). After a reversal, the switch returns to state N, passing through an intermediate state I (inactive), which produces a ca. 2-s period of low reversal frequency before the state N Poisson rate is restored. The stochastic nature of the H. halobium switch reveals a close similarity to Escherichia coli flagellar motor properties as elucidated previously. Sensory modulation of the switch by both photoattractant and photorepellent signals can be interpreted in terms of modulation of the single forward rate constant of the N to R transition. Insight into the mechanism of modulation by the phototaxis receptor sensory rhodopsin I (SR-I) was gained by increasing the lifetime of the principal photointermediate of the SR-I photochemical reaction cycle, S373, by replacing the native chromophore, all-trans-retinal, with the acyclic analog, 3,7,11-trimethyl-2,4,6,8-dodecapentaenal. Flash photolysis of analog-containing cells revealed an eightfold decrease in the rate of thermal decay of S373, and behavioral analysis showed longer periods of reversal suppression than that of cells with the native chromophore over similar ranges of illumination intensities. This indicates that attractant signaling is governed by the lifetime of the S373 intermediate rather than by the frequency of photocycling. In this sense, SR-I is similar to rhodopsin, whose function depends on an active photoproduct (Meta-II).

The solution conformation of sucrose: concentration and temperature dependence.

13C-N.m.r. spin-lattice relaxation measurements were used to study molecular motion in aqueous sucrose. Results show that sucrose tumbles anisotropically in solution, and that its conformation is independent of temperature and concentration. Internal rotation occurs with distinctly different rates and activation energies in the three hydroxymethyl groups. Our data are consistent with results of calculations by Bock and Lemieux who predicted that the conformation of aqueous sucrose is similar to the crystal conformation but with the loss of one intramolecular hydrogen-bond.

Chromophore/protein interaction in bacterial sensory rhodopsin and bacteriorhodopsin.

Retinal analogues with altered conjugated double bond systems or altered stereochemistry were incorporated into the phototaxis receptor sensory rhodopsin (SR) and the light-driven proton pump bacteriorhodopsin (BR) from Halobacterium halobium. Wavelength shifts in absorption ("opsin shifts") due to analogue interaction with the protein microenvironment demonstrate that the same overall electrostatic and steric properties of the retinal binding-site structures exist in both proteins despite their different functions. pi-Electron calculations from the opsin shifts lead to a new description of protein charge distribution that applies to the binding sites of both SR and BR. The new data extends the previously proposed external point charge model for BR to include an ion-pair protein/chromophore interaction near the beta-ionone moiety. The new data modifies the previously proposed external point-charge model, the derivation of which involved an experimentally erroneous opsin shift for one of the BR analogues.

Effects of trypsin and calcium chloride on signal IIs in oxygen-evolving PS II preparations.

Photosystem II oxygen-evolving preparations exhibited a reversible loss of signal IIs hyperfine structure when treated with 1.0 M CaCl2. A progressive irreversible loss of hyperfine structure was observed upon trypsin treatment of these preparations. These treatments appear to alter the environment of the radical responsible for signal IIs. Gel electrophoresis of trypsin-treated photosystem II preparations indicates that three polypeptides (45, 32-34, and 26 kDa) are altered with the same kinetics as observed for the trypsin-induced loss of signal IIs. Two of these polypeptides (45 and 32-34 kDa) are core components of photosystem II.

A theory and a model for interpreting the proton nuclear magnetic resonance spectra of water in plant leaves.

Some plant leaves display complex, orientation-dependent, proton nuclear magnetic resonance (1H NMR) spectra. The spectral patterns vary as the angle between the leaf surface and the applied magnetic field is varied. They also vary with temperature and with the quantity of absorbed manganous ions, but they are independent of magnetic field strength. In this paper, we propose a theory to explain the origin of the spectra and a model from which the patterns can be calculated. The theory shows how heterogeneous magnetic susceptibilities and local dipolar magnetic fields in chloroplasts can shift the water-proton resonance field. The model describes a simplified leaf structure in which the chloroplasts are nonrandomly aligned with respect to the leaf surface. Model calculations are tested by comparison with experimental spectra from hawthorn leaves (Crataegus sp.).

Water permeability of chloroplast envelope membranes. In vivo measurement by saturation-transfer NMR.

In tulip tree (Liriodendron tulipifera) leaves, the proton NMR signal from chloroplast water is resolved from that of water in other leaf compartments. We used the saturation-transfer NMR method to measure the mean water molecule residence time within a chloroplast, (88 +/- 17) ms at 20 degrees C. From the measured chloroplast dimensions, we calculate an effective permeability coefficient of (9 +/- 2) X 10(-4) cm/s for the chloroplast envelope membrane. This is the first in vivo measurement of chloroplast water permeability.