In Vitro and in Silico Tools To Assess Extent of Cellular Uptake and Lysosomal Sequestration of Respiratory Drugs in Human Alveolar Macrophages.

Accumulation of respiratory drugs in human alveolar macrophages (AMs) has not been extensively studied in vitro and in silico despite its potential impact on therapeutic efficacy and/or occurrence of phospholipidosis. The current study aims to characterize the accumulation and subcellular distribution of drugs with respiratory indication in human AMs and to develop an in silico mechanistic AM model to predict lysosomal accumulation of investigated drugs. The data set included 9 drugs previously investigated in rat AM cell line NR8383. Cell-to-unbound medium concentration ratio (Kp,cell) of all drugs (5 μM) was determined to assess the magnitude of intracellular accumulation. The extent of lysosomal sequestration in freshly isolated human AMs from multiple donors (n = 5) was investigated for clarithromycin and imipramine (positive control) using an indirect in vitro method (±20 mM ammonium chloride, NH4Cl). The AM cell parameters and drug physicochemical data were collated to develop an in silico mechanistic AM model. Three in silico models differing in their description of drug membrane partitioning were evaluated; model (1) relied on octanol-water partitioning of drugs, model (2) used in vitro data to account for this process, and model (3) predicted membrane partitioning by incorporating AM phospholipid fractions. In vitro Kp,cell ranged >200-fold for respiratory drugs, with the highest accumulation seen for clarithromycin. A good agreement in Kp,cell was observed between human AMs and NR8383 (2.45-fold bias), highlighting NR8383 as a potentially useful in vitro surrogate tool to characterize drug accumulation in AMs. The mean Kp,cell of clarithromycin (81, CV = 51%) and imipramine (963, CV = 54%) were reduced in the presence of NH4Cl by up to 67% and 81%, respectively, suggesting substantial contribution of lysosomal sequestration and intracellular binding in the accumulation of these drugs in human AMs. The in vitro data showed variability in drug accumulation between individual human AM donors due to possible differences in lysosomal abundance, volume, and phospholipid content, which may have important clinical implications. Consideration of drug-acidic phospholipid interactions significantly improved the performance of the in silico models; use of in vitro Kp,cell obtained in the presence of NH4Cl as a surrogate for membrane partitioning (model (2)) captured the variability in clarithromycin and imipramine Kp,cell observed in vitro and showed the best ability to predict correctly positive and negative lysosomotropic properties. The developed mechanistic AM model represents a useful in silico tool to predict lysosomal and cellular drug concentrations based on drug physicochemical data and system specific properties, with potential application to other cell types.

[1]  T. Seki,et al.  Intracellular pharmacokinetics of telithromycin, a ketolide antibiotic, in alveolar macrophages , 2010, The Journal of pharmacy and pharmacology.

[2]  D. Baldwin,et al.  The levels of clarithromycin and its 14-hydroxy metabolite in the lung. , 1994, The European respiratory journal.

[3]  M. Bebawy,et al.  Ciprofloxacin Is Actively Transported across Bronchial Lung Epithelial Cells Using a Calu-3 Air Interface Cell Model , 2013, Antimicrobial Agents and Chemotherapy.

[4]  R. Austin,et al.  Partitioning of ionizing molecules between aqueous buffers and phospholipid vesicles. , 1995, Journal of pharmaceutical sciences.

[5]  Territo Mc,et al.  The function of human alveolar macrophages. , 1979 .

[6]  Z. Fišar,et al.  Binding of imipramine to phospholipid bilayers using radioligand binding assay. , 2004, General physiology and biophysics.

[7]  Z. Fi,et al.  Binding of Imipramine to Phospholipid Bilayers Using Radioligand Binding Assay , 2004 .

[8]  T. N. Finley,et al.  The ultrastructure of alveolar macrophages from human cigarette smokers and nonsmokers. , 1971, Laboratory investigation; a journal of technical methods and pathology.

[9]  Johannes Kornhuber,et al.  Quantitative modeling of selective lysosomal targeting for drug design , 2008, European Biophysics Journal.

[10]  M. Rowland,et al.  Physiologically based pharmacokinetic modelling 2: predicting the tissue distribution of acids, very weak bases, neutrals and zwitterions. , 2006, Journal of pharmaceutical sciences.

[11]  K. Zangger,et al.  Probing the interactions of macrolide antibiotics with membrane-mimetics by NMR spectroscopy. , 2012, Journal of medicinal chemistry.

[12]  J Brian Houston,et al.  Saturable Uptake of Lipophilic Amine Drugs into Isolated Hepatocytes: Mechanisms and Consequences for Quantitative Clearance Prediction , 2007, Drug Metabolism and Disposition.

[13]  P. Carrupt,et al.  Mechanisms of Liposomes/Water Partitioning of (p-Methylbenzyl)alkylamines , 1998, Pharmaceutical Research.

[14]  S. Krämer,et al.  Towards the Predictability of Drug-Lipid Membrane Interactions: The pH-Dependent Affinity of Propranolol to Phosphatidylinositol Containing Liposomes , 1998, Pharmaceutical Research.

[15]  K. Morimoto,et al.  Distribution characteristics of clarithromycin and azithromycin, macrolide antimicrobial agents used for treatment of respiratory infections, in lung epithelial lining fluid and alveolar macrophages , 2011, Biopharmaceutics & drug disposition.

[16]  A. Avdeef,et al.  pH-Metric logP 10. Determination of Liposomal Membrane-Water Partition Coefficients of lonizable Drugs , 1998, Pharmaceutical Research.

[17]  W. Daniel,et al.  Lysosomal trapping as an important mechanism involved in the cellular distribution of perazine and in pharmacokinetic interaction with antidepressants , 1999, European Neuropsychopharmacology.

[18]  Dave Singh,et al.  The effects of corticosteroids on COPD lung macrophages: a pooled analysis , 2015, Respiratory Research.

[19]  T M Dwyer,et al.  Types of interaction of amphiphilic drugs with phospholipid vesicles. , 1988, The Journal of pharmacology and experimental therapeutics.

[20]  E. W. Swenson,et al.  Human alveolar macrophages: comparison of phagocytic ability, glucose utilization, and ultrastructure in smokers and nonsmokers. , 1970, The Journal of clinical investigation.

[21]  S. Krämer,et al.  The pH-Dependence in the Partitioning Behaviour of (RS)-[3H]Propranolol Between MDCK Cell Lipid Vesicles and Buffer , 1996, Pharmaceutical Research.

[22]  Jeffery M Gearhart,et al.  Predicting passive and active tissue:plasma partition coefficients: interindividual and interspecies variability. , 2014, Journal of pharmaceutical sciences.

[23]  I. Hidalgo,et al.  Models to Predict Unbound Intracellular Drug Concentrations in the Presence of Transporters , 2012, Drug Metabolism and Disposition.

[24]  Hand Wl,et al.  Uptake of antibiotics by human alveolar macrophages. , 1984 .

[25]  Compartmental Models for Apical Efflux by P-glycoprotein—Part 1: Evaluation of Model Complexity , 2014, Pharmaceutical Research.

[26]  J. Krise,et al.  Evaluating the roles of autophagy and lysosomal trafficking defects in intracellular distribution-based drug-drug interactions involving lysosomes. , 2013, Journal of pharmaceutical sciences.

[27]  Gus R Rosania,et al.  The great multidrug-resistance paradox. , 2006, ACS chemical biology.

[28]  T. Seki,et al.  Distribution characteristics of telithromycin, a novel ketolide antimicrobial agent applied for treatment of respiratory infection, in lung epithelial lining fluid and alveolar macrophages. , 2009, Drug metabolism and pharmacokinetics.

[29]  D. Postma,et al.  Cigarette smoke extract affects functional activity of MRP1 in bronchial epithelial cells , 2007, Journal of biochemical and molecular toxicology.

[30]  H. Reynolds,et al.  Analysis of proteins and respiratory cells obtained from human lungs by bronchial lavage. , 1974, The Journal of laboratory and clinical medicine.

[31]  J. Antonini,et al.  Accumulation of amiodarone and desethylamiodarone by rat alveolar macrophages in cell culture. , 1991, Biochemical pharmacology.

[32]  B. Müller,et al.  Drug Liposome Partitioning as a Tool for the Prediction of Human Passive Intestinal Absorption , 1999, Pharmaceutical Research.

[33]  L. Danziger,et al.  Intrapulmonary steady-state concentrations of clarithromycin and azithromycin in healthy adult volunteers , 1997, Antimicrobial agents and chemotherapy.

[34]  D. Ray,et al.  Evaluation of Glucocorticoid Receptor Function in COPD Lung Macrophages Using Beclomethasone-17-Monopropionate , 2013, PloS one.

[35]  Yvonne Will,et al.  A high content screening assay for identifying lysosomotropic compounds. , 2011, Toxicology in vitro : an international journal published in association with BIBRA.

[36]  T. Nakanishi,et al.  Transport of ipratropium, an anti-chronic obstructive pulmonary disease drug, is mediated by organic cation/carnitine transporters in human bronchial epithelial cells: implications for carrier-mediated pulmonary absorption. , 2010, Molecular pharmaceutics.

[37]  J. Wedzicha,et al.  Defective macrophage phagocytosis of bacteria in COPD , 2009, European Respiratory Journal.

[38]  Walter Schmitt,et al.  General approach for the calculation of tissue to plasma partition coefficients. , 2008, Toxicology in vitro : an international journal published in association with BIBRA.

[39]  D. Golde,et al.  The pulmonary-alveolar macrophage (first of two parts). , 1979, New England Journal of Medicine.

[40]  S. Sahu,et al.  Fatty Acid Composition of Phospholipids Isolated from Human Alveolar Macrophages 87 Percent of total fatty acids a Fatty , 2004 .

[41]  S. Krämer,et al.  Alpha-tocopherol influences the lipid membrane affinity of desipramine in a pH-dependent manner. , 2004, European journal of pharmaceutical sciences : official journal of the European Federation for Pharmaceutical Sciences.

[42]  J. Golden,et al.  Intrapulmonary pharmacokinetics of clarithromycin and of erythromycin , 1995, Antimicrobial agents and chemotherapy.

[43]  J. Houston,et al.  Uptake and Intracellular Binding of Lipophilic Amine Drugs by Isolated Rat Hepatocytes and Implications for Prediction of in Vivo Metabolic Clearance , 2006, Drug Metabolism and Disposition.

[44]  S. Farrow,et al.  IFN‐γ synergistically enhances LPS signalling in alveolar macrophages from COPD patients and controls by corticosteroid‐resistant STAT1 activation , 2012, British journal of pharmacology.

[45]  E. Korn Structure of Biological Membranes , 1966, Science.

[46]  T. Nakanishi,et al.  Organic Cation Transporter-Mediated Renal Secretion of Ipratropium and Tiotropium in Rats and Humans , 2011, Drug Metabolism and Disposition.

[47]  Muralikrishna Duvvuri,et al.  A novel assay reveals that weakly basic model compounds concentrate in lysosomes to an extent greater than pH-partitioning theory would predict. , 2005, Molecular pharmaceutics.

[48]  M. Reasor,et al.  Role of the alveolar macrophage in the induction of pulmonary phospholipidosis by chlorphentermine. II. Drug uptake into cells in vitro. , 1986, The Journal of pharmacology and experimental therapeutics.

[49]  S. Hodge,et al.  Smoking alters alveolar macrophage recognition and phagocytic ability: implications in chronic obstructive pulmonary disease. , 2007, American journal of respiratory cell and molecular biology.

[50]  J. Krise,et al.  Drug-drug interactions involving lysosomes: mechanisms and potential clinical implications , 2012, Expert opinion on drug metabolism & toxicology.

[51]  H. Wunderli-Allenspach,et al.  Partition coefficients in vitro: artificial membranes as a standardized distribution model , 1994 .

[52]  D. Xuan,et al.  Comparison of bronchopulmonary pharmacokinetics of clarithromycin and azithromycin , 1996, Antimicrobial agents and chemotherapy.

[53]  A. Galetin,et al.  In Vitro Assessment of Uptake and Lysosomal Sequestration of Respiratory Drugs in Alveolar Macrophage Cell Line NR8383 , 2015, Pharmaceutical Research.

[54]  M. Rowland,et al.  Physiologically based pharmacokinetic modeling 1: predicting the tissue distribution of moderate-to-strong bases. , 2005, Journal of pharmaceutical sciences.

[55]  Aleksandra Galetin,et al.  Simultaneous Assessment of Uptake and Metabolism in Rat Hepatocytes: A Comprehensive Mechanistic Model , 2012, Journal of Pharmacology and Experimental Therapeutics.

[56]  R. Horobin,et al.  A predictive model for the selective accumulation of chemicals in tumor cells , 2005, European Biophysics Journal.

[57]  S. Vavricka,et al.  Interactions of rifamycin SV and rifampicin with organic anion uptake systems of human liver , 2002, Hepatology.

[58]  Kerby Shedden,et al.  A cell-based molecular transport simulator for pharmacokinetic prediction and cheminformatic exploration. , 2006, Molecular pharmaceutics.

[59]  Ulf Bredberg,et al.  Measurement of Unbound Drug Exposure in Brain: Modeling of pH Partitioning Explains Diverging Results between the Brain Slice and Brain Homogenate Methods , 2011, Drug Metabolism and Disposition.

[60]  K. Morimoto,et al.  Subcellular distribution of azithromycin and clarithromycin in rat alveolar macrophages (NR8383) in vitro. , 2013, Biological & pharmaceutical bulletin.

[61]  Y. Sugiyama,et al.  Intracellular Drug Concentrations and Transporters: Measurement, Modeling, and Implications for the Liver , 2013, Clinical pharmacology and therapeutics.

[62]  E. Bäckström,et al.  Lung Retention by Lysosomal Trapping of Inhaled Drugs Can Be Predicted In Vitro With Lung Slices. , 2016, Journal of pharmaceutical sciences.

[63]  M. Territo,et al.  The function of human alveolar macrophages. , 1979, Journal of the Reticuloendothelial Society.

[64]  A. Cohen,et al.  The human alveolar macrophage: isolation, cultivation in vitro, and studies of morphologic and functional characteristics. , 1971, The Journal of clinical investigation.

[65]  Carsten Ehrhardt,et al.  Transport mechanisms at the pulmonary mucosa: implications for drug delivery , 2016, Expert opinion on drug delivery.

[66]  Aleksandra Galetin,et al.  Kinetic Characterization of Rat Hepatic Uptake of 16 Actively Transported Drugs , 2011, Drug Metabolism and Disposition.

[67]  H. Wunderli-Allenspach,et al.  Partition behaviour of acids and bases in a phosphatidylcholine liposome–buffer equilibrium dialysis system , 1997 .

[68]  I. Wyatt,et al.  The composition of lung lipids after poisoning with paraquat. , 1970, British journal of experimental pathology.

[69]  T. Maurer,et al.  Toward a Unified Model of Passive Drug Permeation II: The Physiochemical Determinants of Unbound Tissue Distribution with Applications to the Design of Hepatoselective Glucokinase Activators , 2014, Drug Metabolism and Disposition.

[70]  O. Fardel,et al.  Drug transporter expression in human macrophages , 2011, Fundamental & clinical pharmacology.

[71]  R. Ulrich,et al.  Drug-induced phospholipidosis: issues and future directions , 2006, Expert opinion on drug safety.

[72]  T. Steinberg,et al.  Uptake of antibiotics by human alveolar macrophages. , 1984, The American review of respiratory disease.