Your search keyword '"Immunophilins metabolism"' showing total 5 results

1. Biochemical characterization of the minor immunophilins.

Author

Davis DL, Murthy JN, and Soldin SJ

Subjects

Amino Acid Sequence, Animals, Cattle, Cyclic AMP-Dependent Protein Kinases metabolism, Glyceraldehyde-3-Phosphate Dehydrogenases metabolism, Humans, Immunophilins chemistry, Isoenzymes analysis, Isoenzymes chemistry, Isoenzymes metabolism, Jurkat Cells, Kinetics, Molecular Sequence Data, Molecular Weight, Phosphopeptides chemistry, Phosphopeptides metabolism, Phosphoric Monoester Hydrolases antagonists & inhibitors, Protein Kinase C metabolism, Tacrolimus pharmacology, Tacrolimus Binding Proteins, Thymus Gland enzymology, Immunophilins analysis, Immunophilins metabolism

Abstract

Objective: We present biochemical characterization of the previously described 14 kDa, 37 kDa, and 52 kDa immunophilins and a newly identified 5-8 kDa immunophilin., Design and Methods: Proteins were tested for the following enzymatic activities-rotamase, G3PDH, protein kinase C, cAMP dependent protein kinase-and for the ability to inhibit calcineurin phosphatase when complexed with tacrolimus (FK506)., Results: The 5-8 kDa protein, like the other minor immunophilins, lacks rotamase activity. Since the 37 kDa possesses G3PDH activity, the 5-8 kDa protein, 14 kDa protein, and 52 kDa protein were all tested and found to lack G3PDH activity. Additional work shows that none of the minor immunophilins possess protein kinase C or cyclic AMP-dependent protein kinase activity and that the 37 kDa and 5-8 kDa and probably the 52 kDa proteins are capable of inhibiting calcineurin phosphatase when bound to tacrolimus.

Published

2000

2. Comparison of steady-state trough sirolimus samples by HPLC and a radioreceptor assay.

Author

Davis DL, Murthy JN, Napoli KL, Kahan BD, Gallant-Haidner H, Yatscoff RW, and Soldin SJ

Subjects

Animals, Binding, Competitive, Cattle, Cross Reactions, Cyclosporine therapeutic use, Immunophilins isolation & purification, Immunophilins metabolism, Kidney Transplantation, Lymphocyte Culture Test, Mixed, Prednisone therapeutic use, Protein Binding, Sirolimus analogs & derivatives, Thrombocytopenia blood, Thrombocytopenia therapy, Chromatography, High Pressure Liquid standards, Immunosuppressive Agents blood, Radioligand Assay standards, Sirolimus blood

Abstract

Objectives: We have previously identified a minor immunophilin of 52 kDa molecular weight capable of binding tacrolimus and sirolimus. Because immunophilins are capable of binding both parent drug and metabolites and HPLC assays are typically used to assess parent drug in clinical situations, we used this immunophilin in a radioreceptor assay (RRA) to determine if any metabolites not included in the HPLC measurement would bind to the immunophilin and be associated with thrombocytopenia in patients receiving sirolimus., Design and Methods: We tested 51 steady-state trough whole blood samples from non-thrombocytopenic patients and 51 steady-state trough samples from thrombocytopenic patients and compared them to HPLC measurements of parent drug in the same samples. We also tested whole blood samples spiked with authentic sirolimus metabolites using RRA to ascertain the effect these metabolites have on the technique., Results: We found minimal cross-reactivity in this assay for sirolimus metabolites (binding ranged from <10% to 26%), and good correlation of the radioreceptor assay with HPLC (linear regression slope 0.92, y-intercept 0.79). There was no statistically significant difference between the RRA and HPLC results in two patient groups-thrombocytopenic and non-thrombocytopenic-using the paired t-test (p<0.005) and Bland-Altman analysis., Conclusions: These findings indicate that although the RRA could be substituted for HPLC in therapeutic drug monitoring, the 52 kDa immunophilin does not offer an advantage in terms of detecting metabolites associated with thrombocytopenia. However, the RRA offers the advantages of shorter turnaround time, smaller sample volume and potential for automation.

Published

2000

3. Minor immunophilin binding of tacrolimus and sirolimus metabolites.

Author

Davis DL, Murthy JN, Gallant-Haidner H, Yatscoff RW, and Soldin SJ

Subjects

Animals, Anti-Bacterial Agents metabolism, Cattle, Cross Reactions, Humans, Immunophilins isolation & purification, Immunosuppressive Agents metabolism, Lymphocyte Culture Test, Mixed, Molecular Weight, Protein Binding, Radioligand Assay, Sirolimus analogs & derivatives, Tacrolimus analogs & derivatives, Immunophilins metabolism, Sirolimus metabolism, Tacrolimus metabolism

Abstract

Objectives: We have previously identified three minor immunophilins of molecular weights 37 kDa, 14 kDa, and 5-8 kDa capable of binding tacrolimus and sirolimus., Design and Methods: When tested against pure preparations of five sirolimus metabolites, the 14 kDa protein had almost no cross-reactivity, the 37 kDa protein cross-reacted from a high of 23.2% to <10% and the 5-8 kDa protein cross-reacted from <10% to 46.4%. When the 5-8 kDa immunophilin was tested in whole blood samples to assess interference in clinical samples, the demethylated sirolimus metabolites showed about 25% less cross-reactivity while the hydroxylated metabolites reacted about the same., Results: Since MLC data on sirolimus metabolites to date indicates that their pharmacologic potencies are < or =10% of the parent, the 14 kDa immunophilin appears to be the best candidate for a sirolimus radioreceptor assay. The 5-8 kDa immunophilin is newly identified and its cross-reactivity with tacrolimus metabolites had not been assessed. Binding of the 5-8 kDa immunophilin to pure preparations of three tacrolimus metabolites showed virtually no binding of the protein to 13-O-demethyl and 31-O-demethyl tacrolimus and binding to 15-O-demethyl tacrolimus at 121% relative to parent tacrolimus. Cross-reactivity of 15-O-demethyl tacrolimus with the 5-8 kDa protein was then assessed in whole blood samples, and it bound at a level of 163%. MLC data indicates that 31-O-demethyl tacrolimus is equipotent to parent tacrolimus in immunosuppressive activity, while the 13-O-demethyl and 15-O-demethyl have negligible immunosuppressive activity., Conclusions: Therefore, the 5-8 kDa immunophilin would have limitations in a radioreceptor assay for tacrolimus. In addition, we have evidence that the 5-8 kDa immunophilin is a subunit of a 52 kDa immunophilin previously identified by our group, and the cross-reactivity of the 5-8 kDa immunophilin with these metabolites is similar to that found previously with the 52 kDa, indicating that the two proteins could be related.

Published

2000

4. Tacrolimus metabolite cross-reactivity in different tacrolimus assays.

Author

Murthy JN, Davis DL, Yatscoff RW, and Soldin SJ

Subjects

Cross Reactions, Immunoassay, Immunophilins isolation & purification, Immunophilins metabolism, Kidney Transplantation, Radioligand Assay, Tacrolimus immunology, Immunosuppressive Agents metabolism, Tacrolimus metabolism

Abstract

Objectives: Tacrolimus (FK506) is an immunosuppressive drug with great clinical promise. There is a controversy regarding the role of tacrolimus metabolites in immunosuppression and toxicity, and immunoassays and immunophilin binding assays have not been adequately tested for metabolite cross-reactivity. Methods are limited to HPLC and HPLC-MS for quantifying the parent drug. Mixed lymphocyte culture assay (MLC) is the preferred functional bioassay for the measurement of parent drug and active metabolites but it is not practical for routine laboratory use. Due to differences in assay methods and reagent specificity, the concentration of tacrolimus in a given specimen may vary among different assay kit manufacturers. The objective of this study was to evaluate the degree of cross-reactivity or interference of the three first-generation tacrolimus metabolites [13-O-demethyl (M-I), 31-O-demethyl (M-II) and 15-O-demethyl (M-III)] among two different tacrolimus immunoassays (Immunoassay: PRO-Trac II FK506, Abbott IMx tacrolimus-II); and the radioreceptor assays (RRA) using minor immunophilins (14, 37, and 52 kDa immunophilins) and tacrolimus binding protein (FKBP12)., Methods: First-generation tacrolimus metabolites (M-I, M-II, and M-III) spiked in drug-free whole blood were assayed with RRA using three minor immunophilins (14, 37, and 52 kDa) and two commercial immunoassay procedures (Incstar PRO-Trac II tacrolimus, Abbott IMx tacrolimus II). The results were compared to previously published FKBP-12 RRA data and their immunosuppressive potency., Results and Conclusion: The first generation tacrolimus metabolites (M-I, M-II, and M-III) were tested using concentrations of 10 and 20 ng/mL. The significance of the metabolite interference (% of the total interference) was calculated based on the relative concentration of each metabolite present at steady-state trough concentrations in renal transplant recipients (22). Metabolite I, which has no functional immunosuppressive activity showed minimal interference compared to M-II and M-III in all assays except the 14 kDa RRA. The Incstar PRO-Trac II tacrolimus assay showed the least M-I interference. Metabolite-II, which has a pharmacologic potency similar to the parent drug, showed a significant interference in the immunoassays and significant interference in radioreceptor assays. Metabolite III, which is pharmacologically inactive, produces 3-10% interference in the different assays if its presence in the blood is 6% of the parent drug. The total interference from these three metabolites was greater in the immunoassays than in the receptor assays. Receptor assays for tacrolimus provide results closer to the target value than do immunoassays.

Published

1998

5. Role of immunophilins in therapeutic drug monitoring of immunosuppressive drugs.

Author

Soldin SJ

Subjects

Animals, Cyclosporine blood, Cyclosporine therapeutic use, Humans, Immunoassay, Immunosuppressive Agents blood, Immunosuppressive Agents therapeutic use, Lymphocyte Culture Test, Mixed, Sirolimus blood, Sirolimus therapeutic use, Tacrolimus blood, Tacrolimus therapeutic use, Cyclosporine pharmacokinetics, Drug Monitoring methods, Immunophilins metabolism, Immunosuppressive Agents pharmacokinetics, Sirolimus pharmacokinetics, Tacrolimus pharmacokinetics

Published

1998