Progression of subcellular changes during chemical hypoxia to cultured rat hepatocytes: A laser scanning confocal microscopic study

The aim of this study was to evaluate changes in the subcellular organelles of cultured hepatocytes by laser scanning confocal microscopy during chemical hypoxia with cyanide and iodoacetate, inhibitors of mitochon‐drial respiration and glycolysis, respectively. Parameter‐specific fluorophores used...

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Veröffentlicht in:	Hepatology (Baltimore, Md.) Md.), 1995-05, Vol.21 (5), p.1361-1372
Hauptverfasser:	Zahrebelski, George, Nieminen, Anna‐Liisa, Al‐Ghoul, Kristin, Qian, Ting, Herman, Brian, Lemasters, John J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Animal cells Animals Biological and medical sciences Cell cultures. Hybridization. Fusion Cell Death Cells, Cultured Electrophysiology Extracellular Space - metabolism Fluoresceins - pharmacokinetics Fundamental and applied biological sciences. Psychology Hypoxia - chemically induced Hypoxia - pathology Image Processing, Computer-Assisted Indicators and Reagents Lysosomes - ultrastructure Male Microscopy, Confocal Mitochondria, Liver - metabolism Mitochondria, Liver - physiology Molecular and cellular biology Propidium - pharmacokinetics Rats Rats, Sprague-Dawley
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creator	Zahrebelski, George Nieminen, Anna‐Liisa Al‐Ghoul, Kristin Qian, Ting Herman, Brian Lemasters, John J.
description	The aim of this study was to evaluate changes in the subcellular organelles of cultured hepatocytes by laser scanning confocal microscopy during chemical hypoxia with cyanide and iodoacetate, inhibitors of mitochon‐drial respiration and glycolysis, respectively. Parameter‐specific fluorophores used were calcein for cell topography and membrane permeability, rhodamine‐dextran for lysosomes, rhodamine 123 and tetramethylrhodamine methylester (TMRM) for mitochondrial membrane potential (Δ Ψ) and propidium iodide for loss of cell viability. During the first 30 to 40 minutes of chemical hypoxia to cultured hepatocytes, numerous surface blebs formed and cell volume increased, but Δ Ψ decreased relatively little. Subsequently, the nonspecific permeability of mitochondrial membranes increased, and mitochondria depolarized. These events were followed a few minutes later by disintegration of individual lysosomes. After a few more minutes, viability was lost as indicated by bleb rupture, gross plasma membrane permeability to calcein, and nuclear labeling with propidium iodide. Thus, the following sequence of intracellular events occurred during chemical hypoxia: adenosine triphosphate (ATP) depletion, bleb formation with cellular swelling, onset of a mitochondrial permeability transition, disintegration of lysosomes, plasma membrane failure from bleb rupture, and cell death. Any explanation of the pathophysiology of hypoxic injury must take into account this unique sequence of events.
doi_str_mv	10.1002/hep.1840210521
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Parameter‐specific fluorophores used were calcein for cell topography and membrane permeability, rhodamine‐dextran for lysosomes, rhodamine 123 and tetramethylrhodamine methylester (TMRM) for mitochondrial membrane potential (Δ Ψ) and propidium iodide for loss of cell viability. During the first 30 to 40 minutes of chemical hypoxia to cultured hepatocytes, numerous surface blebs formed and cell volume increased, but Δ Ψ decreased relatively little. Subsequently, the nonspecific permeability of mitochondrial membranes increased, and mitochondria depolarized. These events were followed a few minutes later by disintegration of individual lysosomes. After a few more minutes, viability was lost as indicated by bleb rupture, gross plasma membrane permeability to calcein, and nuclear labeling with propidium iodide. 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Thus, the following sequence of intracellular events occurred during chemical hypoxia: adenosine triphosphate (ATP) depletion, bleb formation with cellular swelling, onset of a mitochondrial permeability transition, disintegration of lysosomes, plasma membrane failure from bleb rupture, and cell death. Any explanation of the pathophysiology of hypoxic injury must take into account this unique sequence of events.</description><subject>Animal cells</subject><subject>Animals</subject><subject>Biological and medical sciences</subject><subject>Cell cultures. Hybridization. Fusion</subject><subject>Cell Death</subject><subject>Cells, Cultured</subject><subject>Electrophysiology</subject><subject>Extracellular Space - metabolism</subject><subject>Fluoresceins - pharmacokinetics</subject><subject>Fundamental and applied biological sciences. Psychology</subject><subject>Hypoxia - chemically induced</subject><subject>Hypoxia - pathology</subject><subject>Image Processing, Computer-Assisted</subject><subject>Indicators and Reagents</subject><subject>Lysosomes - ultrastructure</subject><subject>Male</subject><subject>Microscopy, Confocal</subject><subject>Mitochondria, Liver - metabolism</subject><subject>Mitochondria, Liver - physiology</subject><subject>Molecular and cellular biology</subject><subject>Propidium - pharmacokinetics</subject><subject>Rats</subject><subject>Rats, Sprague-Dawley</subject><issn>0270-9139</issn><issn>1527-3350</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>1995</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqFUE1v1DAUtBCoLAtXbkg-IG5Z_BGvE25VVVqkSvQA5-jZedk18sbBjlVy5o_j7a4KN05PT29m3swQ8pazDWdMfNzjtOFNzQRnSvBnZMWV0JWUij0nKyY0q1ou25fkVUo_GGNtLZoLcqG11Ntarsjv-xh2EVNyYaRhoCkbi95nD5HaPYw7TLTP0Y27suLBWfB0v0zhlwM6B2qzn3PEnkaYabECc7DLjOkTvaQeEkaaLIzjIz2MQzjSi0gMyYbJWZrm3C-vyYsBfMI357km3z9ff7u6re6-3ny5uryrrKw5rzjTZjBgVCON1bKvEWuhesnBtqgbUdd2KxsuDJO22ULTcuyVMtwIsA0CyjX5cNKdYviZMc3dwaVjWhgx5NRpLZRgShXg5gQ8Gk0Rh26K7gBx6Tjrjq13JWr3t_VCeHdWzuaA_RP8XHO5vz_fofThhwijdekJJpUQosRak_YEe3Ael_887W6v7_-x8AenIp4D</recordid><startdate>199505</startdate><enddate>199505</enddate><creator>Zahrebelski, George</creator><creator>Nieminen, Anna‐Liisa</creator><creator>Al‐Ghoul, Kristin</creator><creator>Qian, Ting</creator><creator>Herman, Brian</creator><creator>Lemasters, John J.</creator><general>W.B. 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Parameter‐specific fluorophores used were calcein for cell topography and membrane permeability, rhodamine‐dextran for lysosomes, rhodamine 123 and tetramethylrhodamine methylester (TMRM) for mitochondrial membrane potential (Δ Ψ) and propidium iodide for loss of cell viability. During the first 30 to 40 minutes of chemical hypoxia to cultured hepatocytes, numerous surface blebs formed and cell volume increased, but Δ Ψ decreased relatively little. Subsequently, the nonspecific permeability of mitochondrial membranes increased, and mitochondria depolarized. These events were followed a few minutes later by disintegration of individual lysosomes. After a few more minutes, viability was lost as indicated by bleb rupture, gross plasma membrane permeability to calcein, and nuclear labeling with propidium iodide. 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subjects	Animal cells Animals Biological and medical sciences Cell cultures. Hybridization. Fusion Cell Death Cells, Cultured Electrophysiology Extracellular Space - metabolism Fluoresceins - pharmacokinetics Fundamental and applied biological sciences. Psychology Hypoxia - chemically induced Hypoxia - pathology Image Processing, Computer-Assisted Indicators and Reagents Lysosomes - ultrastructure Male Microscopy, Confocal Mitochondria, Liver - metabolism Mitochondria, Liver - physiology Molecular and cellular biology Propidium - pharmacokinetics Rats Rats, Sprague-Dawley
title	Progression of subcellular changes during chemical hypoxia to cultured rat hepatocytes: A laser scanning confocal microscopic study
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