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Dynamic changes in the structure and intracellular locale of the mammalian low-molecular-weight heat shock protein.

Dynamic changes in the structure and intracellular locale of the mammalian low-molecular-weight... Dynamic changes in the structure and intracellular locale of the mammalian low-molecular-weight heat shock protein. A P Arrigo , J P Suhan and W J Welch Cold Spring Harbor Laboratory, New York 11724. ABSTRACT Mammalian cells grown at 37 degrees C contain a single low-molecular-weight heat shock (or stress) protein with an apparent mass of 28 kilodaltons (kDa) whose synthesis increases in cells after exposure to elevated temperatures or other forms of physiologic stress. Herein we present data demonstrating that heat shock protein 28 exists in a number of dynamic states depending upon the physiologic state of the cell. Biochemical fractionation of 37 degrees C cells in the absence of nonionic detergent revealed that the 28-kDa protein partitioned approximately equally between the soluble and insoluble fractions. The addition of detergent in the fractionation procedure resulted in all of the protein distributed within the soluble phase. In contrast, in cells first heat shocked and then fractionated in the presence of detergent, most of the 28-kDa protein was found within the insoluble fraction. These biochemical results appeared entirely consistent with indirect immunofluorescence experiments, demonstrating that the 28-kDa protein resided within the perinuclear region of 37 degrees C cells in close proximity to the Golgi complex. After heat shock treatment, the 28-kDa protein relocalized within the nucleus and resisted detergent extraction. The extent of 28-kDa protein redistribution into the nucleus and its detergent insolubility increased as a function of the severity of the heat shock treatment. With time of recovery from the heat treatment there occurred a gradual return of the 28-kDa protein into the detergent-soluble phase. Concomitant with these changes in 28-kDa protein solubility was a corresponding change in the apparent size of the protein as determined by gel filtration. While at 37 degrees C cells the protein exhibited a mass of 200 to 800 kDa; after heat shock the protein assumed sizes of 2 MDa or greater. Using immunoelectron microscopy, we show an accumulation of these aggregates of 28-kDa protein within the nucleus. Finally, we show that the heat-dependent redistribution of the 28-kDa protein from the cytoplasm into the nucleus was greatly diminished when the cells were first rendered thermotolerant, and we suggest that this simple assay (i.e., 28-kDa protein detergent solubility) may prove useful in evaluating the thermotolerant status of a cell or tissue. CiteULike Connotea Delicious Digg Facebook Google+ Mendeley Reddit StumbleUpon Twitter What's this? « Previous | Next Article » Table of Contents This Article doi: 10.1128/​MCB.8.12.5059 Mol. Cell. Biol. December 1988 vol. 8 no. 12 5059-5071 » Abstract PDF Classifications Research Article Services Email this article to a colleague Similar articles in ASM journals Alert me when this article is cited Alert me if a correction is posted Similar articles in this journal Similar articles in Web of Science Similar articles in PubMed Alert me to new issues of MCB Download to citation manager Reprints and Permissions Copyright Information Books from ASM Press MicrobeWorld Citing Articles Load citing article information Citing articles via Web of Science Citing articles via Google Scholar Google Scholar Articles by Arrigo, A. P. Articles by Welch, W. J. Search for related content PubMed PubMed citation Articles by Arrigo, A. P. Articles by Welch, W. J. Related Content Load related web page information Social Bookmarking CiteULike Connotea Delicious Digg Facebook Google+ Mendeley Reddit StumbleUpon Twitter What's this? current issue January 2012, volume 32, issue 1 Spotlights in the Current Issue Architecture of the Yeast RNA Polymerase II Open Complex State and Regulation by TFIIF GATA-1 Establishes Cell-Type-Specific Autophagy as a Developmental Program Prickle Phosphorylation Regulates Its Localization and β-Catenin-Independent Wnt Signaling Alert me to new issues of MCB About MCB Subscribers Authors Reviewers Advertisers Inquiries from the Press Permissions & Commercial Reprints ASM Journals Public Access Policy MCB RSS Feeds 1752 N Street N.W. • Washington DC 20036 202.737.3600 • 202.942.9355 fax • journals@asmusa.org Print ISSN: 0270-7306 Online ISSN: 1098-5549 Copyright © 2011 by the American Society for Microbiology. For an alternate route to MCB .asm.org, visit: http://intl- MCB .asm.org | More Info» var gaJsHost = (("https:" == document.location.protocol) ? "https://ssl." : "http://www."); document.write(unescape("%3Cscript src='" + gaJsHost + "google-analytics.com/ga.js' type='text/javascript'%3E%3C/script%3E")); var pageTracker = _gat._getTracker("UA-5821458-11"); pageTracker._trackPageview(); http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Molecular and Cellular Biology American Society For Microbiology

Dynamic changes in the structure and intracellular locale of the mammalian low-molecular-weight heat shock protein.

Arrigo, A P; Suhan, J P; Welch, W J
Molecular and Cellular Biology , Volume 8 (12): 5059 – Dec 1, 1988
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Dynamic changes in the structure and intracellular locale of the mammalian low-molecular-weight heat shock protein.

Arrigo, A P; Suhan, J P; Welch, W J
Molecular and Cellular Biology , Volume 8 (12): 5059 – Dec 1, 1988

Abstract

Dynamic changes in the structure and intracellular locale of the mammalian low-molecular-weight heat shock protein. A P Arrigo , J P Suhan and W J Welch Cold Spring Harbor Laboratory, New York 11724. ABSTRACT Mammalian cells grown at 37 degrees C contain a single low-molecular-weight heat shock (or stress) protein with an apparent mass of 28 kilodaltons (kDa) whose synthesis increases in cells after exposure to elevated temperatures or other forms of physiologic stress. Herein we present data demonstrating that heat shock protein 28 exists in a number of dynamic states depending upon the physiologic state of the cell. Biochemical fractionation of 37 degrees C cells in the absence of nonionic detergent revealed that the 28-kDa protein partitioned approximately equally between the soluble and insoluble fractions. The addition of detergent in the fractionation procedure resulted in all of the protein distributed within the soluble phase. In contrast, in cells first heat shocked and then fractionated in the presence of detergent, most of the 28-kDa protein was found within the insoluble fraction. These biochemical results appeared entirely consistent with indirect immunofluorescence experiments, demonstrating that the 28-kDa protein resided within the perinuclear region of 37 degrees C cells in close proximity to the Golgi complex. After heat shock treatment, the 28-kDa protein relocalized within the nucleus and resisted detergent extraction. The extent of 28-kDa protein redistribution into the nucleus and its detergent insolubility increased as a function of the severity of the heat shock treatment. With time of recovery from the heat treatment there occurred a gradual return of the 28-kDa protein into the detergent-soluble phase. Concomitant with these changes in 28-kDa protein solubility was a corresponding change in the apparent size of the protein as determined by gel filtration. While at 37 degrees C cells the protein exhibited a mass of 200 to 800 kDa; after heat shock the protein assumed sizes of 2 MDa or greater. Using immunoelectron microscopy, we show an accumulation of these aggregates of 28-kDa protein within the nucleus. Finally, we show that the heat-dependent redistribution of the 28-kDa protein from the cytoplasm into the nucleus was greatly diminished when the cells were first rendered thermotolerant, and we suggest that this simple assay (i.e., 28-kDa protein detergent solubility) may prove useful in evaluating the thermotolerant status of a cell or tissue. CiteULike Connotea Delicious Digg Facebook Google+ Mendeley Reddit StumbleUpon Twitter What's this? « Previous | Next Article » Table of Contents This Article doi: 10.1128/​MCB.8.12.5059 Mol. Cell. Biol. December 1988 vol. 8 no. 12 5059-5071 » Abstract PDF Classifications Research Article Services Email this article to a colleague Similar articles in ASM journals Alert me when this article is cited Alert me if a correction is posted Similar articles in this journal Similar articles in Web of Science Similar articles in PubMed Alert me to new issues of MCB Download to citation manager Reprints and Permissions Copyright Information Books from ASM Press MicrobeWorld Citing Articles Load citing article information Citing articles via Web of Science Citing articles via Google Scholar Google Scholar Articles by Arrigo, A. P. Articles by Welch, W. J. Search for related content PubMed PubMed citation Articles by Arrigo, A. P. Articles by Welch, W. J. Related Content Load related web page information Social Bookmarking CiteULike Connotea Delicious Digg Facebook Google+ Mendeley Reddit StumbleUpon Twitter What's this? current issue January 2012, volume 32, issue 1 Spotlights in the Current Issue Architecture of the Yeast RNA Polymerase II Open Complex State and Regulation by TFIIF GATA-1 Establishes Cell-Type-Specific Autophagy as a Developmental Program Prickle Phosphorylation Regulates Its Localization and β-Catenin-Independent Wnt Signaling Alert me to new issues of MCB About MCB Subscribers Authors Reviewers Advertisers Inquiries from the Press Permissions & Commercial Reprints ASM Journals Public Access Policy MCB RSS Feeds 1752 N Street N.W. • Washington DC 20036 202.737.3600 • 202.942.9355 fax • journals@asmusa.org Print ISSN: 0270-7306 Online ISSN: 1098-5549 Copyright © 2011 by the American Society for Microbiology. For an alternate route to MCB .asm.org, visit: http://intl- MCB .asm.org | More Info» var gaJsHost = (("https:" == document.location.protocol) ? "https://ssl." : "http://www."); document.write(unescape("%3Cscript src='" + gaJsHost + "google-analytics.com/ga.js' type='text/javascript'%3E%3C/script%3E")); var pageTracker = _gat._getTracker("UA-5821458-11"); pageTracker._trackPageview();

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Publisher
American Society For Microbiology
Copyright
Copyright © 1988 by the American society for Microbiology.
ISSN
0270-7306
eISSN
1098-5549
DOI
10.1128/MCB.8.12.5059
Publisher site
See Article on Publisher Site

Abstract

Dynamic changes in the structure and intracellular locale of the mammalian low-molecular-weight heat shock protein. A P Arrigo , J P Suhan and W J Welch Cold Spring Harbor Laboratory, New York 11724. ABSTRACT Mammalian cells grown at 37 degrees C contain a single low-molecular-weight heat shock (or stress) protein with an apparent mass of 28 kilodaltons (kDa) whose synthesis increases in cells after exposure to elevated temperatures or other forms of physiologic stress. Herein we present data demonstrating that heat shock protein 28 exists in a number of dynamic states depending upon the physiologic state of the cell. Biochemical fractionation of 37 degrees C cells in the absence of nonionic detergent revealed that the 28-kDa protein partitioned approximately equally between the soluble and insoluble fractions. The addition of detergent in the fractionation procedure resulted in all of the protein distributed within the soluble phase. In contrast, in cells first heat shocked and then fractionated in the presence of detergent, most of the 28-kDa protein was found within the insoluble fraction. These biochemical results appeared entirely consistent with indirect immunofluorescence experiments, demonstrating that the 28-kDa protein resided within the perinuclear region of 37 degrees C cells in close proximity to the Golgi complex. After heat shock treatment, the 28-kDa protein relocalized within the nucleus and resisted detergent extraction. The extent of 28-kDa protein redistribution into the nucleus and its detergent insolubility increased as a function of the severity of the heat shock treatment. With time of recovery from the heat treatment there occurred a gradual return of the 28-kDa protein into the detergent-soluble phase. Concomitant with these changes in 28-kDa protein solubility was a corresponding change in the apparent size of the protein as determined by gel filtration. While at 37 degrees C cells the protein exhibited a mass of 200 to 800 kDa; after heat shock the protein assumed sizes of 2 MDa or greater. Using immunoelectron microscopy, we show an accumulation of these aggregates of 28-kDa protein within the nucleus. Finally, we show that the heat-dependent redistribution of the 28-kDa protein from the cytoplasm into the nucleus was greatly diminished when the cells were first rendered thermotolerant, and we suggest that this simple assay (i.e., 28-kDa protein detergent solubility) may prove useful in evaluating the thermotolerant status of a cell or tissue. CiteULike Connotea Delicious Digg Facebook Google+ Mendeley Reddit StumbleUpon Twitter What's this? « Previous | Next Article » Table of Contents This Article doi: 10.1128/​MCB.8.12.5059 Mol. Cell. Biol. December 1988 vol. 8 no. 12 5059-5071 » Abstract PDF Classifications Research Article Services Email this article to a colleague Similar articles in ASM journals Alert me when this article is cited Alert me if a correction is posted Similar articles in this journal Similar articles in Web of Science Similar articles in PubMed Alert me to new issues of MCB Download to citation manager Reprints and Permissions Copyright Information Books from ASM Press MicrobeWorld Citing Articles Load citing article information Citing articles via Web of Science Citing articles via Google Scholar Google Scholar Articles by Arrigo, A. P. Articles by Welch, W. J. Search for related content PubMed PubMed citation Articles by Arrigo, A. P. Articles by Welch, W. J. Related Content Load related web page information Social Bookmarking CiteULike Connotea Delicious Digg Facebook Google+ Mendeley Reddit StumbleUpon Twitter What's this? current issue January 2012, volume 32, issue 1 Spotlights in the Current Issue Architecture of the Yeast RNA Polymerase II Open Complex State and Regulation by TFIIF GATA-1 Establishes Cell-Type-Specific Autophagy as a Developmental Program Prickle Phosphorylation Regulates Its Localization and β-Catenin-Independent Wnt Signaling Alert me to new issues of MCB About MCB Subscribers Authors Reviewers Advertisers Inquiries from the Press Permissions & Commercial Reprints ASM Journals Public Access Policy MCB RSS Feeds 1752 N Street N.W. • Washington DC 20036 202.737.3600 • 202.942.9355 fax • journals@asmusa.org Print ISSN: 0270-7306 Online ISSN: 1098-5549 Copyright © 2011 by the American Society for Microbiology. For an alternate route to MCB .asm.org, visit: http://intl- MCB .asm.org | More Info» var gaJsHost = (("https:" == document.location.protocol) ? "https://ssl." : "http://www."); document.write(unescape("%3Cscript src='" + gaJsHost + "google-analytics.com/ga.js' type='text/javascript'%3E%3C/script%3E")); var pageTracker = _gat._getTracker("UA-5821458-11"); pageTracker._trackPageview();

Journal

Molecular and Cellular BiologyAmerican Society For Microbiology

Published: Dec 1, 1988

There are no references for this article.