In vivo recognition of cyclopentadienyltricarbonylrhenium (CpTR) derivatives.

In vivo metabolism of [(188)Re]tricarbonyl(carboxycyclopentadienyl)rhenium ([(188)Re]CpTR-COOH) and its glycine conjugate ([(188)Re]CpTR-Gly) was investigated to estimate the applicability of cyclopentadienyltricarbonylrhenium (CpTR) compounds to (186/188)Re-labeling reagents for polypeptides and peptides. Both [(188)Re]CpTR derivatives were stable after incubation in a buffered-solution and in murine plasma at 37 degrees C for 6 h. Plasma protein binding was hardly observed with the two derivatives. However, different biodistribution and metabolic fates were observed with the two CpTR derivatives. While more lipophilic [(188)Re]CpTR-COOH was excreted by both hepatobiliary and urinary excretion, the majority of less lipophilic [(188)Re]CpTR-Gly was excreted by urinary excretion. In addition, while [(188)Re]CpTR-Gly was rapidly excreted into urine as its intact structure, [(188)Re]CpTR-COOH was metabolized to more hydrophilic compounds including its glycine conjugate, [(188)Re]CpTR-Gly. Renal excretion of [(188)Re]CpTR-Gly was significantly reduced in probenecid retreated mice. The present studies reinforced that CpTR core remained stable under biological environment. CpTR-COOH was partially recognized as an aromatic acid and was metabolized as such. However, glycine conjugation rendered CpTR-COOH hydrophilic enough to be excreted into urine without further metabolism. These findings suggested that radiolabeling reagents that liberate [(186/188)Re]CpTR-Gly from covalently conjugated (186/188)Re-labeled polypeptides and peptides by the action of renal brush border enzymes would be useful to reduce renal radioactivity levels.

Design, synthesis, and evaluation of [188Re]organorhenium-labeled antibody fragments with renal enzyme-cleavable linkage for low renal radioactivity levels.

Renal localization of radiolabeled antibody fragments constitutes a problem in targeted imaging and radiotherapy. We have reported that Fab fragments labeled with 3'-[131I]iodohippuryl Nepsilon-maleoyl-lysine (HML) showed markedly low renal radioactivity levels even shortly after injection, due to a rapid and selective release of m-[131I]iodohippuric acid by the action of brush border enzymes. To estimate the applicability of the molecular design to metallic radionuclides, [188Re]tricarbonyl(cyclopentadienylcarbonate)rhenium ([188Re]CpTR-COOH) was conjugated with Nepsilon-tert-butoxycarbonyl-glycyl-lysine or Nepsilon-maleoyl-glycyl-lysine to prepare [188Re]CpTR-GK-Boc or [188Re]CpTR-GK. The cleavage of the glycyl-lysine linkage of the two compounds generates a glycine conjugate of [188Re]CpTR-COOH ([188Re]CpTR-Gly), which possesses in vivo behaviors similar to those of m-iodohippuric acid. The hydrolysis rate of the peptide bond in [188Re]CpTR-GK-Boc was compared with that in 3'-[125I]iodohippuryl Nepsilon-Boc-lysine ([125I]HL-Boc) using brush border membrane vesicles (BBMVs) prepared from rat kidneys. [188Re]CpTR-GK was conjugated to thiolated Fab fragments to prepare [188Re]CpTR-GK-Fab. The biodistribution of radioactivity after injection of [188Re]CpTR-GK-Fab was compared with that of [125I]HML-Fab and [188Re]CpTR-Fab prepared by conjugating N-hydroxysuccinimidyl ester of [188Re]CpTR-COOH with antibody fragments. While [188Re]CpTR-GK-Boc liberated [188Re]CpTR-Gly in BBMVs, [125I]HL-Boc liberated m-[125I]iodohippuric acid at a much faster rate. In addition, although [125I]HL-Boc was hydrolyzed by both metalloenzymes and nonmetalloenzymes, metalloenzymes were responsible for the cleavage of the peptide linkage in [188Re]CpTR-GK-Boc. In biodistribution studies, [188Re]CpTR-GK-Fab exhibited significantly lower renal radioactivity levels than did [188Re]CpTR-Fab. However, the renal radioactivity levels of [188Re]CpTR-GK-Fab were slightly higher than those of [125I]HML-Fab. The analysis of urine samples collected for 6 h postinjection of [188Re]CpTR-GK-Fab showed that [188Re]CpTR-Gly was the major radiometabolite. In tumor-bearing mice, [188Re]CpTR-GK-Fab significantly reduced renal radioactivity levels without impairing the radioactivity levels in tumor. These findings indicate that the molecular design of HML can be applied to metallic radionuclides by using a radiometal chelate of high inertness and by designing a radiometabolite of high urinary excretion when released from antibody fragments following cleavage of a glycyl-lysine linkage. This study also indicates that a change in chemical structure of a radiolabel attached to a glycyl-lysine linkage significantly affected enzymes involved in the hydrolysis reaction. Since there are many kinds of enzymes that cleave a variety of peptide linkages on the renal brush border membrane, selection of a peptide linkage optimal to a radiometal chelate of interest may provide radiolabeled antibody fragments that exhibit renal radioactivity levels similar to those of [131I]HML-labeled ones. The in vitro system using BBMVs might be useful for selecting an appropriate peptide linkage.