QSAR Models for Predicting Five Levels of Cellular Accumulation of Lysosomotropic Macrocycles

Drugs that accumulate in lysosomes reach very high tissue concentrations, which is evident in the high volume of distribution and often lower clearance of these compounds. Such a pharmacokinetic profile is beneficial for indications where high tissue penetration and a less frequent dosing regime is...

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Veröffentlicht in:	INTERNATIONAL JOURNAL OF MOLECULAR SCIENCES 2019-11, Vol.20 (23), p.5938
Hauptverfasser:	Norinder, Ulf, Munic Kos, Vesna
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Sprache:	eng
Schlagworte:	Accumulation Accuracy Antiinfectives and antibacterials applicability domain Biological activity cellular accumulation Cellular structure Chromatography, Liquid classification models Computational Biology - methods Computer applications Dosage Drugs Inflammation Liquid chromatography Lysosomes Lysosomes - chemistry macrocycle Macrocyclic compounds Macrocyclic Compounds - chemistry Macrocyclic Compounds - pharmacokinetics Mass spectrometry Mass spectroscopy Medicin och hälsovetenskap molecular descriptors Molecular Structure OPLS Pharmacokinetics Pharmacology Prediction models QSAR Quantitative Structure-Activity Relationship Structure-activity relationships Tandem Mass Spectrometry Tissue Distribution
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description	Drugs that accumulate in lysosomes reach very high tissue concentrations, which is evident in the high volume of distribution and often lower clearance of these compounds. Such a pharmacokinetic profile is beneficial for indications where high tissue penetration and a less frequent dosing regime is required. Here, we show how the level of lysosomotropic accumulation in cells can be predicted solely from molecular structure. To develop quantitative structure-activity relationship (QSAR) models, we used cellular accumulation data for 69 lysosomotropic macrocycles, the pharmaceutical class for which this type of prediction model is extremely valuable due to the importance of cellular accumulation for their anti-infective and anti-inflammatory applications as well as due to the fact that they are extremely difficult to model by computational methods because of their large size (M > 500). For the first time, we show that five levels of intracellular lysosomotropic accumulation (as measured by liquid chromatography coupled to tandem mass spectrometry-LC-MS/MS), from low/no to extremely high, can be predicted with 60% balanced accuracy solely from the compound's structure. Although largely built on macrocycles, the eight non-macrocyclic compounds that were added to the set were found to be well incorporated by the models, indicating their possible broader application. By uncovering the link between the molecular structure and cellular accumulation as the key process in tissue distribution of lysosomotropic compounds, these models are applicable for directing the drug discovery process and prioritizing the compounds for synthesis with fine-tuned accumulation properties, according to the desired pharmacokinetic profile.
doi_str_mv	10.3390/ijms20235938
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Such a pharmacokinetic profile is beneficial for indications where high tissue penetration and a less frequent dosing regime is required. Here, we show how the level of lysosomotropic accumulation in cells can be predicted solely from molecular structure. To develop quantitative structure-activity relationship (QSAR) models, we used cellular accumulation data for 69 lysosomotropic macrocycles, the pharmaceutical class for which this type of prediction model is extremely valuable due to the importance of cellular accumulation for their anti-infective and anti-inflammatory applications as well as due to the fact that they are extremely difficult to model by computational methods because of their large size (M > 500). For the first time, we show that five levels of intracellular lysosomotropic accumulation (as measured by liquid chromatography coupled to tandem mass spectrometry-LC-MS/MS), from low/no to extremely high, can be predicted with 60% balanced accuracy solely from the compound's structure. Although largely built on macrocycles, the eight non-macrocyclic compounds that were added to the set were found to be well incorporated by the models, indicating their possible broader application. 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subjects	Accumulation Accuracy Antiinfectives and antibacterials applicability domain Biological activity cellular accumulation Cellular structure Chromatography, Liquid classification models Computational Biology - methods Computer applications Dosage Drugs Inflammation Liquid chromatography Lysosomes Lysosomes - chemistry macrocycle Macrocyclic compounds Macrocyclic Compounds - chemistry Macrocyclic Compounds - pharmacokinetics Mass spectrometry Mass spectroscopy Medicin och hälsovetenskap molecular descriptors Molecular Structure OPLS Pharmacokinetics Pharmacology Prediction models QSAR Quantitative Structure-Activity Relationship Structure-activity relationships Tandem Mass Spectrometry Tissue Distribution
title	QSAR Models for Predicting Five Levels of Cellular Accumulation of Lysosomotropic Macrocycles
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