Renal Disposition Characteristics of Oligonucleotides Modified at Terminal Linkages in the Perfused Rat Kidney

Abstract

To clarify the renal disposition characteristics of oligonucleotides at the organ level, the renal handling of model end-capped oligonucleotides, 3′- methoxyethylamine 5′-biotin-decathymidylic acid containing phosphoramidate modifications at 3′- and 5′-terminal internucleoside linkages (T₁₀) and its phosphorothioate (Ts₁₀), were studied in the perfused rat kidney. In a single-pass indicator dilution experiment, venous outflow and urinary excretion patterns and tissue accumulation of radiolabeled oligonucleotides were evaluated under filtering or nonfiltering conditions. No significant binding to bovine serum albumin (BSA) in the perfusate was observed for T₁₀, whereas more than 90% of Ts₁₀ bound to BSA. The steady-state distribution volume of T₁₀ calculated from the venous outflow pattern was larger than that of inulin, which corresponds to the extracellular volume of the kidney, whereas the distribution volume of Ts₁₀ was larger than that of BSA (the intravascular volume). These results suggested their interaction with the vascular wall. Rapid urinary excretion was observed for T₁₀, similar to inulin used as a marker of golmerular filtration rate. On the other hand, urinary excretion of Ts₁₀ was greatly restricted due to its high binding ability (>90%) to BSA in the perfusate. A significant amount of T₁₀ and Ts₁₀ was accumulated in the kidney (T₁₀,1.8% of injected dose; Ts₁₀, 1.3%) compared with inulin (0.2%) and BSA (10 from the capillary side was significantly inhibited by simultaneous injection of dextran sulfate, suggesting that the oligonucleotide was taken up as an anionic molecule. These findings will be useful information for the development of delivery systems for antisense oligonucleotides.