Considerations for use of recombinant adenoviral vectors: dose effect on hepatic cytochromes P450.

Recombinant adenovirus (Ad) serotype 5 is a vector commonly used for gene delivery. Although this vector has a natural tropism for the liver, there is a limited understanding of how Ad administration affects one of the primary hepatic processes, drug metabolism. The effects of systemic administration of a model recombinant adenoviral vector on two hepatic cytochrome P450 (P450) enzymes, CYP3A2 and 2C11, were investigated. Sprague-Dawley rats were treated with one of six vector doses, ranging from 5.7 x 10(6) to 5.7 x 10(12) virus particles (vp)/kg. Hepatic P450 protein expression, catalytic activity, and mRNA levels were measured over 14 days. Ad administration (5.7 x 10(10)-5.7 x 10(12) vp/kg) reduced CYP3A2 over the duration of the study. Six hours after administration of 5.7 x 10(12) vp/kg, CYP3A2 activity and mRNA levels were suppressed by 45 and 65%, respectively (P < or = 0.01). This continued throughout the study with levels dropping to 36 and 45% of controls by 14 days, respectively (P < or = 0.01). A similar trend was detected for CYP2C11 within this dosing range. Administration of 5.7 x 10(6), 5.7 x 10(8), and 5.7 x 10(9) vp/kg of Ad significantly increased both CYP2C11 protein expression by 86, 71, and 107% and activity 110, 118, and 53%, respectively, above those of animals treated with saline (P < or = 0.01). These results clearly indicate that a single dose of adenovirus significantly alters key drug metabolizing enzymes for an extended period of time and should be investigated further in the context of the design and implementation of clinical trial protocols.

Cyclosporine and bromocriptine-induced suppressions of CYP3A1/2 and CYP2C11 are not mediated by prolactin.

The purpose of this study was to determine if the suppression of hepatic CYP3A1/2 (cytochrome P450 3A1/2) and CYP2C11 (cytochrome P450 2C11) by cyclosporine is mediated by prolactin. Male intact rats were given subcutaneous doses of either 15 mg/kg/day of cyclosporine or 1 ml/kg/day of cyclosporine vehicle concomitantly with one of the following: 500 mg/kg prolactin, 1 ml/kg prolactin vehicle, 4 mg/kg bromocriptine, or 1 ml/kg bromocriptine vehicle for 14 days. Protein expressions were measured using Western blot analysis and activities were measured using an in vitro testosterone hydroxylation assay. The administration of prolactin did not significantly alter CYP3A1/2 protein expression. Hypoprolactinemia, produced by bromocriptine, caused a significant suppression of CYP3A1/2 activity levels when bromocriptine was administered alone and in combination with cyclosporine (P<0.001, P<0.05; respectively). However, the cause of the suppression by bromocriptine was likely not the result of lowering prolactin levels. Bromocriptine administration also lowered CYP2C11 protein expression and activity, while prolactin administration had virtually no effect on CYP2C11. Chronic cyclosporine administration caused a 140% increase in prolactin area under the curve (AUC) (P<0.001). Bromocriptine caused a significant decline in endogenous prolactin secretion, however, concurrent cyclosporine administration did not recover these levels. Overall, while both cyclosporine and bromocriptine, separately, can significantly alter the fate of hepatic P450 enzymes, the suppression is likely not due to an alteration in prolactin levels.

Suppression of hepatic CYP3A1/2 and CYP2C11 by cyclosporine is not mediated by altering growth hormone levels.

Cyclosporine (CsA) suppresses drug metabolism by decreasing cytochrome P450 (P450) enzyme levels in rat liver. Growth hormone (GH) is known to pretranslationally regulate P450 expression. Thus, the suppression of P450 by CsA may involve GH as an intermediate. To address this question, we examined the effects of administering exogenous GH via twice daily subcutaneous injections and in conjunction with chronic subcutaneous CsA administration for 14 days on hepatic P450 expression. CsA alone decreased CYP3A1/2 and CYP2C11 significantly, in a manner similar to that previously found. When administered in the absence of CsA, GH also suppressed CYP3A1/2 and CYP2C11 protein levels as compared with GH vehicle. In the presence of CsA, GH did not cause further suppression of either CYP3A1/2 or CYP2C11 expression when compared with CsA treatment with GH vehicle. Testosterone in vitro catalytic assays confirmed that CsA and GH separately cause significant decreases in activity levels. Also, the concomitant administration of GH and CsA caused lowered production of 16alpha-, 2alpha-, 6beta-, and 2beta-hydroxytestosterone as compared with the administration of GH with CsA vehicle and as compared with the administration of GH vehicle with CsA. This study shows that GH is a dominating factor over CsA in determining hepatic P450 expression and activity. In addition, CsA does not seem to alter GH levels as a mediating event in suppressing P450 expression and activity. Since CsA given in combination with GH further suppressed P450 activity as compared with CsA given in combination with vehicle, this suggests that changes in hormonal status are likely to be one of the many factors that is responsible for the lack of a clear association between cyclosporine dosing and markers of toxicity.

The effect of lipoprotein-associated cyclosporine on drug metabolism and toxicity in rats.

PURPOSE: The objective of the study was to examine the effect of lipoprotein-associated cyclosporine on hepatic metabolism, hepatic lipoprotein receptors, and renal toxicity in comparison to the current commercially available cyclosporine (CSA) product. METHODS: Rats within the same group were given one of the following treatments: 10 mg/kg of CSA, plasma-CSA, very low-density lipoprotein (VLDL)-CSA, low-density lipoprotein (LDL)-CSA, LDL, high-density lipoprotein (HDL)-CSA, 1 mL/kg of vehicle, or saline intravenously for 14 days. Urine and blood samples were evaluated for renal function. Hepatic microsomes were prepared for immunoblotting and in vitro catalytic assays of CYP activity. Reverse transcription polymerase chain reaction (RT-PCR) was used to examine genetic regulation. RESULTS: (1) There were no statistical differences in cholesterol levels in lipoprotein-associated CSA groups as compared with vehicle controls. (2) A significant decrease in creatinine clearance was seen in the plasma-CSA treated group (56%; P < 0.05). (3) No suppressions of CYP3A protein, activity or mRNA were found in the VLDL-CSA treated group. (4) CYP3A mRNA was suppressed to a greater degree in the LDL- and HDL-CSA treated groups as compared with the suppression caused by CSA alone. (5) A significant suppression of hepatic low-density lipoprotein receptor (LDL-R) mRNA levels was found in the LDL-CSA (50%; P = 0.0333) and plasma-CSA (40%; P = 0.1138), which was not attributed to LDL alone. (6) Significant suppression of scavenger-receptors class B type I (SR-BI) mRNA levels was found in the plasma-CSA group, although no significant differences in SRBI protein levels were seen between groups. CONCLUSIONS: Specific lipoprotein-CSA complexes appear to alter metabolic responses differently in comparison to CSA alone, indicating that the metabolism of CSA is dependent on the in vivo disposition of lipoprotein-CSA. Furthermore, LDL-R is one regulatory factor responsible for altering CSA metabolism as a result of an increase in uptake of CSA into hepatocytes.

Altered cytochrome P450 and P-glycoprotein levels in rats during simulated weightlessness.

BACKGROUND: In order to investigate the effects of simulated weightlessness on drug metabolism, liver, kidney, and small intestine, microsomal proteins from tail-suspended rats were analyzed to determine cytochrome P450 (CYP) and P-glycoprotein levels following varying durations of tail-suspension. HYPOTHESIS: P-glycoprotein and CYP levels would both decrease similar to previous findings from actual spaceflight data. METHODS: Six groups of four Sprague-Dawley rats each were tail-suspended for up to 21 d; CYP and P-glycoprotein levels in the liver, kidney and small intestine were then measured by Western blotting. The results were compared with a control group of unsuspended rats. RESULTS: Our data showed there were significant changes in the levels of hepatic CYP2C11, 2E1, 4A1, and P-glycoprotein and significant changes in the levels of P-glycoprotein and CYP4A1 in the kidney. However, there were no significant changes detected in the levels of CYP3A2 in the liver or small intestine. CONCLUSIONS: We conclude that simulated weightlessness, using the tail-suspended rat model, showed significant suppressive effects on levels of CYP2C11, 2E1, and P-glycoprotein in the liver and CYP4A1 in the kidney, while demonstrating no significant effect on the levels of CYP3A2 in the liver or small intestine. Thus, generalized predictions on the effect of simulated microgravity on drug metabolism cannot be made and the overall effect of spaceflight on individual enzymes should be investigated.