Disposition and Drug-Drug Interaction Potential of Veliparib (ABT-888), a Novel and Potent Inhibitor of Poly(ADP-ribose) Polymerase

ABSTRACT: The Veliparib absorption was high. Dosed radioactivity was widely distributed in rat tissues. The majority of drug-related material was excreted in urine as unchanged drug (approximately 54, 41, and 70% of the dose in rats, dogs, and humans, respectively). A lactam M8 and an amino acid M3 were two major excretory metabolites in animals. In the circulation of animals and humans, veliparib was the major drug-related component, and M8 was one of the major metabolites. Monooxygenated metabolite M2 was significant in the rat and dog, and M3 was also significant in the dog. Veliparib biotransformation occurred on the pyrrolidine moiety via formation of a lactam, an amino acid, and an N-carbamoyl glucuronide, in addition to oxidation on benzoimidazole carboxamide and sequential glucuronidation. In vitro experiments using recombinant human cytochrome P450 (P450) enzymes identified CYP2D6 as the major enzyme metabolizing veliparib with minor contributions from CYP1A2, 2C19, and 3A4. Veliparib did not inhibit or induce the activities of major human P450s. Veliparib was a weak P-glycoprotein (P-gp) substrate, showing no P-gp inhibition. Taken together, these studies indicate a low potential for veliparib to cause clinically significant P-gp or P450-mediated drug-drug interactions (DDIs). Overall, the favorable dispositional and DDI profiles of veliparib should be beneficial to its safety and efficacy

Whole Genome Sequence-Based Analysis of a Model Complex Trait, High Density Lipoprotein Cholesterol

We describe initial steps for interrogating whole genome sequence (WGS) data to characterize the genetic architecture of a complex trait, such as high density lipoprotein cholesterol (HDL-C). We estimate that common variation contributes more to HDL-C heritability than rare variation, and screening for Mendelian dyslipidemia variants identified individuals with extreme HDL-C. WGS analyses highlight the value of regulatory and non-protein coding regions of the genome in addition to protein coding regions

Specificity of Procaine and Ester Hydrolysis by Human, Minipig, and Rat Skin and Liver

ABSTRACT: The capacity of human, minipig, and rat skin and liver subcellular fractions to hydrolyze the anesthetic ester procaine was compared with carboxylesterase substrates 4-methylumbelliferyl-acetate, phenylvalerate, and para-nitrophenylacetate and the arylesterase substrate phenylacetate. Rates of procaine hydrolysis by minipig and human skin microsomal and cytosolic fractions were similar, with rat displaying higher activity. Loperamide inhibited procaine hydrolysis by human skin, suggesting involvement of human carboxylesterase hCE2. The esterase activity and inhibition profiles in the skin were similar for minipig and human, whereas rat had a higher capacity to metabolize esters and a different inhibition profile. Minipig and human liver and skin esterase activity was inhibited principally by paraoxon and bis-nitrophenyl phosphate, classical carboxylesterase inhibitors. Rat skin and liver esterase activity was inhibited additionally by phenylmethylsulfonyl fluoride and the arylesterase inhibitor mercuric chloride, indicating a different esterase profile. These results have highlighted the potential of skin to hydrolyze procaine following topical application, which possibly limits its pharmacological effect. Skin from minipig used as an animal model for assessing transdermal drug preparations had similar capacity to hydrolyze esters to human skin

Microsomal metabolism of delavirdine: evidence for mechanism-based inactivation of human cytochrome P450 3A

ABSTRACT Administration of delavirdine, an HIV-1 reverse transcriptase inhibitor, to rats or monkeys resulted in apparent loss of hepatic microsomal CYP3A and delavirdine desalkylation activity. Human CYP3A catalyzes the formation of desalkyl delavirdine and 6Ј-hydroxy delavirdine, an unstable metabolite, while CYP2D6 catalyzes only desalkyl delavirdine. CYP2D6 catalyzed desalkyl delavirdine formation was linear with time (up to 30 min) but when catalyzed by cDNA expressed CYP3A4 or human liver microsomes the reaction rate declined progressively with time. Coincubation with triazolam showed that delavirdine caused a time-and NADPH-dependent loss of CYP3A4 activity in human liver microsomes as measured by triazolam 1Ј-hydroxylation. The catalytic activity loss was saturable and was characterized by a K i of 21.6 Ϯ 8.9 M and a k inact of 0.59 Ϯ 0.08 min Ϫ1 . An apparent partition ratio of 41 was determined with cDNA expressed CYP3A4, based on the substrate depletion method. Incubation of [ 14 C]delavirdine with microsomes from several species resulted in irreversible association with an approximately 50 kDa protein, as demonstrated by SDS-PAGE/autoradiography. Binding to the protein was NADPH dependent, glutathione insensitive, proportional to the level of CYP3A expression and was inhibited by ketoconazole, a specific CYP3A inhibitor. NADPH-dependent irreversible binding to human and rat total microsomal protein was demonstrated following exhaustive extraction of microsomal protein. Binding was decreased in the presence of glutathione and appeared to be related to expression level of CYP3A. These results suggest that delavirdine can inactivate CYP3A and has the potential to slow the metabolism of coadministered CYP3A substrates. The reverse transcriptase of HIV-1 catalyzes the transcription of viral RNA to proviral DNA, an essential step in the life cycle of HIV-1 and the progression to AIDS in humans is a potent, specific non-nucleoside inhibitor of HIV-1 reverse transcriptase Analysis of plasma drug levels in male rats treated orally or intravenously with single doses of delavirdine showed that the drug was well absorbed; however, clearance of delavirdine was diminished and half-life was increased in rats treated with increasing doses of delavirdine The in vitro metabolism of delavirdine was examined using liver microsomes from several specie

Insertion of constant region domains of human IgG, into CD4-PE40 increases its plasma half-life

CD4-PE40 is a recombinant toxin containing the binding domain of CD4 and a mutant form of Pseudomonas exotoxin A from which the cell binding domain has been removed. To increase the serum half-life of CD4-PE40, we have inserted various portions of the constant domain of human IgG, into CD4-PE40. The constructs made include CD4-CH2-PE40, CD4-CH3-PE40, CD4-CH1-CH2-PE40 and CD4-CH2-CH3-PE40. The fusion proteins were expressed and purified from E. coli. Insertion of various domains from the constant region of IgG1 did not alter the cytotoxic activity of CD4-PE40; all these molecules were equally cytotoxic to cells expressing gp120 on their surface. However, there was a marked increase in the serum mean residence time of CD4-Cn2-PE40 which was 115min as compared to 47 min for CD4-PE40. Insertion of other domains also increased the half-life of CD4-PE40, however, CD4-CH2-PE40 was found to have the longest mean residence time in the circulation. One possible explanation for the increase in plasma half-life is diminished susceptibility of proteins to proteolysis. It was found that CD4-CH2-PE40 was much more resistant to proteolysis by trypsin than CD4-PE40. We proposed that insertion of the CH2 domain into CD4-PE40 covers up the protease sensitive sites in the molecule, thereby making the molecule less susceptible to degradation. The increase in size and reduced sensitivity to proteases could both be responsible for the increased plasma half-life of CD4-CH2-PE40