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Journal Article
COPI vesicles accumulating in the presence of a GTP restricted arf1 mutant are depleted of anterograde and retrograde cargo
R. Pepperkok, J.A. Whitney, M. Gomez, T.E. Kreis
Journal of Cell Science 2000 113: 135-144;
R. Pepperkok
Cell Biophysics and Cell Biology Program, EMBL Heidelberg, Meyerhofstr.1, Germany. .
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J.A. Whitney
Cell Biophysics and Cell Biology Program, EMBL Heidelberg, Meyerhofstr.1, Germany. .
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M. Gomez
Cell Biophysics and Cell Biology Program, EMBL Heidelberg, Meyerhofstr.1, Germany. .
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T.E. Kreis
Cell Biophysics and Cell Biology Program, EMBL Heidelberg, Meyerhofstr.1, Germany. .
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Summary

Microinjection of the slowly hydrolyzable GTP analogue GTP(gamma)S or the ectopic expression of a GTP restricted mutant of the small GTPase arf1 (arf1[Q71L]) leads to the rapid accumulation of COPI coated vesicles and buds in living cells. This effect is blocked at 15 degrees C and by microinjection of antibodies against (beta)-COP. Anterograde and retrograde membrane protein transport markers, which have been previously shown to be incorporated into COPI vesicles between the endoplasmic reticulum and Golgi complex, are depleted from the GTP(gamma)S or arf1[Q71L] induced COPI coated vesicles and buds. In contrast, in control cells 30 to 60% of the COPI carriers co-localize with these markers. These in vivo data corroborate recent in vitro work, suggesting that GTP(gamma)S and arf1[Q71L] interfere with the sorting of membrane proteins into Golgi derived COPI vesicles, and provide the first in vivo evidence for a role of GTP hydrolysis by arf1 in the sorting of cargo into COPI coated vesicles and buds.

  • © 2000 by Company of Biologists

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Journal Article
COPI vesicles accumulating in the presence of a GTP restricted arf1 mutant are depleted of anterograde and retrograde cargo
R. Pepperkok, J.A. Whitney, M. Gomez, T.E. Kreis
Journal of Cell Science 2000 113: 135-144;
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Journal Article
COPI vesicles accumulating in the presence of a GTP restricted arf1 mutant are depleted of anterograde and retrograde cargo
R. Pepperkok, J.A. Whitney, M. Gomez, T.E. Kreis
Journal of Cell Science 2000 113: 135-144;

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