Project description:The microsomes are re-formed vesicle-like artifacts, not ordinarily present in living cells, from pieces of the endoplasmic reticulum (ER), plasma membrane, mitochondria, and Golgi apparatus of broken eukaryotic cells. Typically, microsomes are separated by differential centrifuged from homogenized of cell or tissue. Based on enrichment of ER fractions, prepared microsomes mainly show a large of metabolic activity following high amount of metabolic enzyme, as cytochrome P450 (CYP). CYPs are important components of xenobiotic-metabolizing monooxygenase accounting for an approximate 75% of biotransformation of clinically relevant drugs. Hepatic CYP are ER-anchored hemoproteins involved in the metabolism of numerous endo- and xenobiotics including drugs, steroids, and carcinogens. The CYPs catalytic activity is subject to regulation via phosphorylation. In several previous studies, 8 CYP phosphorylation sites had been discovered in human. Protein kinase A (PKA) and protein kinase C (PKC) were identified as a major catalyst for the phosphorylation of CYPs in 2003. The phosphorylation of CYPs process to their ubiquitination undergoing ubiquitin-dependent 26S proteosomal degradation.

Project description:The microsomes are re-formed vesicle-like artifacts, not ordinarily present in living cells, from pieces of the endoplasmic reticulum (ER), plasma membrane, mitochondria, and Golgi apparatus of broken eukaryotic cells. Typically, microsomes are separated by differential centrifuged from homogenized of cell or tissue. Based on enrichment of ER fractions, prepared microsomes mainly show a large of metabolic activity following high amount of metabolic enzyme, as cytochrome P450 (CYP). CYPs are important components of xenobiotic-metabolizing monooxygenase accounting for an approximate 75% of biotransformation of clinically relevant drugs. Hepatic CYP are ER-anchored hemoproteins involved in the metabolism of numerous endo- and xenobiotics including drugs, steroids, and carcinogens. The CYPs catalytic activity is subject to regulation via phosphorylation. In several previous studies, 8 CYP phosphorylation sites had been discovered in human. Protein kinase A (PKA) and protein kinase C (PKC) were identified as a major catalyst for the phosphorylation of CYPs in 2003. The phosphorylation of CYPs process to their ubiquitination undergoing ubiquitin-dependent 26S proteosomal degradation.

Project description:Purpose: To know the expression of all cytochrome P450 (CYP) enzymes and related drug metabolizing enzymes in pancreatic cancer models Methods: We obtained expression profiles of 8 commercially-available pancreatic cancer cell lines and one non-cancerous immortalized cell line by RNA-sequencing. The pancreatic cancer cells were compared among themselves and to the non-cancerous control cells. Results: We confirmed reports that CYP3A5 is highly overexpressed in pancreatic cancer models, and additionally report that known xenobiotic-metabolizing CYPs are lowly expressed in comparison.

Project description:Human hepatic cell lines have been widely used as an in vitro model for the study of drug metabolism and liver toxicity. However, the validity of this model is still a subject of debate because the expressions of various proteins including drug-metabolizing enzymes (DMEs) in the cell lines can differ significantly from that of human livers. In the present study, we first conducted an untargeted proteomics of the microsomes of the cell lines HepG2, Hep3B, and Huh7 in comparison with human livers using a SWATH method. Furthermore, a targeted proteomic approach, named high-resolution multiple reaction monitoring (MRM-HR), was utilized to compare the expressions of pre-selected DMEs between human livers and the cell lines.

Project description:Antiretroviral drugs such as efavirenz (EFV) are essential to combat HIV infection in the brain, but little is known about how these drugs are metabolized locally. In this study, the cytochrome P450 (P450) and UDP-glucuronosyltransferase (UGT)-dependent metabolism of EFV was probed in brain microsomes from mice, cynomolgus macaques, and humans as well as primary neural cells from C57BL/6N mice. Utilizing ultra-high performance liquid chromatography high resolution mass spectrometry (uHPLC-HRMS), the formation of 8-hydroxyefavirenz (8-OHEFV) from EFV and the glucuronidation of P450-dependent metabolites 8-OHEFV and 8,14-dihydroxyefavirenz (8,14-diOHEFV) was observed in brain microsomes from all three species. The direct glucuronidation of EFV, however, was only detected in the cynomolgus macaque brain microsomes. In brain cell typesprimary neural cells treated with EFV, microglia formed 8-OHEFV only while glucuronidation was detected in cortical neurons and astrocytes treated with P450-dependent metabolites of EFV. Untargeted and targeted proteomics experiments were used to determine which P450s and UGTs were present in the brain microsomes. Eleven P450s and 11 UGTs were detected in the human brain microsomes, whilewith 10 P450s and 15 UGTs were identified in the mouse brain microsomes and 17 and 6 P450s and UGTs, respectively, observed in the macaque brain microsomes. For many of these enzymes, this was the first time they have been noted at the protein level in the brain microsomes. This study indicates the potential for the brain to play a contributing role in the local metabolism of EFV, and the related pharmacological and toxicological consequences.metabolism to contribute to pharmacological and toxicological EFV outcomes in brain.

Project description:Cardiac sarcoplasmic reticulum (SR) plays a central role in cellular Ca homeostasis, as does endoplasmic reticulum (ER) in the nonmuscle cell. The importance of SR Ca-handling function has led to detailed understanding of Ca-release and re-uptake protein complexes, but relatively little information regarding other known ER functions. We isolated cardiac membranes based upon their ability to efficiently accumulate Ca by the SR,ER-ATPase (SERCA-positive membranes), a process known to produce two characteristic SR membrane fractions: those enriched in known junctional SR markers, and those enriched in proteins originating from classic ER subdomains. Using standard proteomic techniques, we determined the SR proteins in three membrane preparations: 1) the highest-density SERCA-positive microsomes (HighSR); 2) the slightly less dense SERCA-positive microsomes that are constrained by a ryanodine-dependent leak (MedSR); and the original crude cardiac microsomes. Only a third of all crude microsomal proteins in heart were enriched in SERCA-positive membranes at least two fold. This protocol completely excluded known contractile, mitochondrial, sarcolemmal, and other major microsomal proteins, producing a far cleaner preparation of SR. Each SERCA-positive protein was distributed between HighSR and MedSR membrane vesicles in accordance with relative densities of SERCA2a versus ryanodine receptor. The distributions reinforced past findings on the distributions for several of the major known proteins. When combined with values for relative abundance, and enrichment over crude membranes, our protocol conveniently and effectively exposed multiple domains of the cardiac ER/SR. Most of the highly enriched and abundant cardiac SR/ER proteins represent proteins that have received little research attention. The data generate a useful quantitative analysis of intracellular membrane structure and function within cardiomyocytes, and may provide a reliable way of gauging broader changes in cardiac SR.

Project description:Metabolism of anticancer drugs markedly affects their antitumor effects. The major goal of our study was to investigate associations of gene expression of enzymes metabolizing taxanes and/or anthracyclines with therapy response and survival of breast carcinoma patients The present study investigated differences in transcript levels of key modulators of oxysterol signaling pathway, including oxysterol receptors, metabolic enzymes and transporters in the groups of estrogen receptor positive (ER+) breast carcinomas in comparison to estrogen receptor negative (ER-) ones, and to control non-tumor tissues.

Project description:Label-free absolute quantitative proteomics is commonly used for absolute quantification of the proteome or specific proteins of interest in various biological samples. Current label-free absolute protein quantification (APQ) methods determine MS1 intensities, MS2 spectral counts or intensities to absolutely quantify protein concentrations from data obtained from data-dependent acquisition (DDA). In recent years, label-free data-independent acquisition (DIA) has seen increasing use as a powerful tool for relative protein quantification. Here we present a novel label-free DIA-based absolute protein quantification (DIA-APQ) method for the absolute quantification of protein expressions from DIA data. To validate this method, both DDA and DIA experiments were performed on 36 individual human liver microsome and S9 samples. The DIA-APQ assay was able to quantify approximately twice as many proteins as the DDA MS1-based APQ method whereas protein concentrations determined by the two methods were comparable. To evaluate the accuracy of the DIA-APQ method, we absolutely quantified carboxylesterase 1 concentrations in human liver samples using an established SILAC internal standard-based proteomic assay; the SILAC results were consistent with those obtained from DIA-APQ analysis. Finally, we employed a unique algorithm in DIA-APQ to distribute the MS signals from shared peptides to different protein isoforms and successfully applied the DIA-APQ method to the absolute quantification of several drug-metabolizing enzyme isoforms in human liver microsomes. This novel DIA-based APQ method not only provides a powerful approach for absolutely quantifying entire proteomes and specific candidate proteins, but also has with the capacity differentiating protein isoforms. 

Project description:We report label-free quantification of xenobiotic metabolizing enzymes (XME), transporters, redox enzymes, proteases and nucleases in 20 human liver microsomal samples. More than 3500 proteins were identified and quantified. These data can be used in physiologically based pharmacokinetic models to predict appropriate drug doses in children.

Project description:LC-MS/MS-based label-free proteomics of human liver homogenate, human liver microsomes, and human hepatocytes from 15 matched donors used to compare and understand differences in two major in vitro systems used for drug metabolism studies