Development of oligodeoxynucleotides (oligo-dNs) and their analogs as therapeutic agents is complicated by their low rate of transport across cellular membranes, which is required for interaction with the intracellular complementary nucleic acid sequences, and the lack of tissue-specific delivery. To overcome these obstacles, bioconjugates between cell surface receptor ligands and oligodeoxynucleoside methylphosphonates (oligo-MPs) have been constructed containing homogeneous, chemically defined covalent linkages. We have previously established that a model conjugate, [32P]-labeled [YEE(ah-GalNAc)3]-SMCC-AET-pUmpT7 (1), is delivered to Hep G2 cells in a ligand-specific manner, reaching a peak value of 26 pmol per 10(6) cells after 24 hours incubation at 37 degrees C (Hangeland et al., 1995). In this work, the in vivo behavior of this conjugate is explored. Administration of this conjugate to mice via tail vein injection demonstrates rapid uptake in liver to the extent of 69.9 +/- 9.9% of the injected dose after 15 minutes. Thereafter, the conjugate and its metabolites are rapidly cleared via the kidney and urine. Polyacrylamide gel electrophoresis analysis of extracts of Hep G2 cells and mouse liver reveal the conjugate 1 to be extensively metabolized. In contrast, the conjugate found in mouse urine is largely intact. These data show that this novel, biodegradable delivery vehicle represents a viable approach for the delivery of antisense oligo-MPs and other oligo-dN analogs to the liver for therapeutic and diagnostic applications.
Responses specific to the spin-spin relaxation time (T2) have been observed in two time-dependent studies of the intracellular water in normal and transformed Syrian hamster fetal fibroblasts. At 300-MHz (7.0 T), the spin-lattice relaxation time (T1) was insensitive to several aspects of cellular physiology that produced changes in the T2 and the apparent self-diffusion coefficient (Dapp) of intracellular water. In normal cells stimulated with epidermal growth factor (EGF), T1 was insensitive to time-dependent changes detected by T2 and Dapp. In synchronized tumor cells, T1 was insensitive to cell-cycle-dependent changes detected by T2. The strongly coupled behavior of T2 and Dapp that was observed as a function of time in EGF-stimulated cells indicates that the diffusion of intracellular water through inhomogeneous local magnetic field gradients produced effects observable in T2. Conformational changes in large intracellular macromolecular assemblies such as chromatin or the cytoskeleton may alter the magnitude and inhomogeneity of local field gradients, producing responses in T2 and Dapp only.
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