Non-invasive detection of protein metabolism in vivo by n.m.r. spectroscopy. Application of a novel 19F-containing residualizing label

Design of protein homocystamides with enhanced tumor uptake properties for (19)F magnetic resonance imaging

Straightforward and reliable tools for in vivo imaging of tumors can benefit the studies of cancer development, as well as contribute to successful diagnosis and treatment of cancer. (19)F NMR offers an exceptional quantitative way of in vivo imaging of the infused agents because of the lack of (19)F signals from the endogenous molecules in the body. The purpose of this study is to develop molecular probes with appropriate NMR characteristics and the biocompatibility for in vivo applications using (19)F MRI. We have studied the reaction between perfluorotoluene and homocysteine thiolactone resulting in the formation of N-substituted homocysteine thiolactone derivative. It has been shown that the reaction occurs selectively at the para position. This fluorine-labeled homocysteine thiolactone has been employed for the introduction of a perfluorotoluene group as a (19)F-containing tag into human serum albumin. The modified protein has been studied in terms of its ability to aggregate and promote the formation of free radicals. By comparing the properties of N-perfluorotoluene-homocystamide of albumin with N-homocysteinylated albumin, it has been revealed that blocking of the alpha-amino group of the homocysteine residue in the fluorinated albumin conjugate inhibits the dangerous aggregation process, as well as free radical formation. A dual-labeled albumin-based molecular probe for (19)F MRI and fluorescence microscopy has been obtained by functionalizing the protein with both maleimide of a fluorescent dye and a fluorinated thiolactone derivative. The incubation of cells with this conjugate did not reveal any significant reduction in cell viability with respect to the parent albumin. The perfluorotoluene-labeled albumin has been demonstrated to act as a promising agent for in vivo (19)F MRI.

Uptake and life time of fluoride ion in rats by 19F-NMR

19F nuclear magnetic resonance (NMR) was utilized to obtain information on the uptake and half-life time of fluoride ion in rats. Changes in tissue fluoride level after acute loading were monitored over time in blood and tissue homogenates obtained from liver and brain. The rate of fluoride elimination from various tissues was roughly similar, following in all cases a first-order kinetic rate law. The F- concentration in brain was about 20% of that found in liver, indicating a reduced fluoride diffusion across the blood-brain barrier. In vivo F- spectra were obtained in rat brain in few minutes with a good signal-to-noise ratio; this confirms the possibility of extending the use of F- as a probe of biomolecules to in vivo applications.

Quantification of the accumulation and degradation of beta-very-low-density lipoproteins in vivo using a 19F-containing residualizing label and n.m.r. spectroscopy

beta-Very-low-density lipoproteins (beta-VLDL)O were conjugated to the 19F-containing residualizing label, NN-dilactitol-3,5-bis(trifluoromethyl)benzylamine (DLBA), to determine whether the metabolism of this lipoprotein fraction could be characterized in vivo with n.m.r. spectroscopy. Solution state 19F high-resolution n.m.r. spectroscopy of DLBA-beta-VLDL, containing either intact apoproteins or selectively enzymically digested products, demonstrated that the extent of degradation could be distinguished by differences in spin-spin relaxation times (T2 times). DLBA-beta-VLDL was injected intravenously into rabbits, and accumulation of 19F in hepatic tissue was quantified non-invasively by n.m.r. spectroscopy 5 and 30 h after injection. In addition to quantifying the accumulation of DLBA-beta-VLDL in hepatic tissue, a marked decrease (approx. 100 Hz) in the linewidth of 19F resonance from labelled lipoproteins was observed at 30 h compared with the 5 h interval in continuously monitored animals. The change in linewidth was consistent with a decrease in molecular size that occurred during protein degradation, resulting in increased T2 times. To demonstrate that T2 times can be used as an index to quantify apoprotein degradation in vivo, relaxation measurements were performed on livers excised 20 h after injection of DLBA-beta-VLDL into rabbits. Two molecular motional fractions were revealed by relaxation profiles representing either an intact or an extensively degraded form of apoprotein. The amplitudes of each component were compared with results from trichloroacetic acid precipitation of liver homogenates acquired from rabbits 20 h after injection of beta-VLDL labelled with the radioiodinated analogue of DLBA, dilactitol-125I-tyramine. The amount of degraded apoprotein determined by n.m.r. spectroscopy and acid precipitation was 68.6 +/- 7.0% and 58.7 +/- 7.5% (n = 4) respectively. The results of this study demonstrate that 19F n.m.r. spectroscopy can be used to define the temporal characteristics of the hepatic metabolism of lipoproteins in vivo by quantifying both the tissue-specific accumulation and extent of apoprotein degradation. The methodology developed offers promise for the non-invasive, sequential and longitudinal evaluation of lipoprotein metabolism in vivo.

Detection of site-specific binding and co-binding of ligands to macromolecules using 19F NMR

Study of ligand-macromolecular interactions by 19F nuclear magnetic resonance (NMR) spectroscopy affords many opportunities for obtaining molecular biochemical and pharmaceutical information. This is due to the absence of a background fluorine signal, as well as the relatively high sensitivity of 19F NMR. Use of fluorine-labeled ligands enables one to probe not only binding and co-binding phenomena to macromolecules, but also can provide data on binding constants, stoichiometries, kinetics, and conformational properties of these complexes. Under conditions of slow exchange and macromolecule-induced chemical shifts, multiple 19F NMR resonances can be observed for free and bound ligands. These shifted resonances are a direct correlate of the concentration of ligand bound in a specific state rather than the global concentrations of bound or free ligand which are usually determined using other techniques such as absorption spectroscopy or equilibrium dialysis. Examples of these interactions are demonstrated both from the literature and from interactions of 5-fluorotryptophan, 5-fluorosalicylic acid, flurbiprofen, and sulindac sulfide with human serum albumin. Other applications of 19F NMR to study of these interactions in vivo, as well for receptor binding and metabolic tracing of fluorinated drugs and proteins are discussed.