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CD39, NTPDase 1, is attached to the plasma membrane by two transmembrane domains. Why?

Since the identification of CD39 and other members of the e-NTPDase (ecto-nucleoside triphosphate diphosphohydrolase) family as the primary enzymes responsible for cell surface nucleotide hydrolysis, one of their most intriguing features has been their unusual topology. The active site lies in the l...

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Detalles Bibliográficos
Autores principales: Grinthal, Alison, Guidotti, Guido
Formato: Texto
Lenguaje:English
Publicado: Springer Netherlands 2006
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2254477/
https://www.ncbi.nlm.nih.gov/pubmed/18404478
http://dx.doi.org/10.1007/s11302-005-5907-8
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author Grinthal, Alison
Guidotti, Guido
author_facet Grinthal, Alison
Guidotti, Guido
author_sort Grinthal, Alison
collection PubMed
description Since the identification of CD39 and other members of the e-NTPDase (ecto-nucleoside triphosphate diphosphohydrolase) family as the primary enzymes responsible for cell surface nucleotide hydrolysis, one of their most intriguing features has been their unusual topology. The active site lies in the large extracellular region, but instead of being anchored in the membrane by a single transmembrane domain or lipid link like other ectoenzymes, CD39 has two transmembrane domains, one at each end. In this review we discuss evidence that the structure and dynamics of the transmembrane helices are intricately connected to enzymatic function. Removal of either or both transmembrane domains or disruption of their native state by detergent solubilization reduces activity by 90%, indicating that native function requires both transmembrane domains to be present and in the membrane. Enzymatic and mutational analysis of the native and truncated forms has shown that the active site can exist in distinct functional states characterized by different total activities, substrate specificities, hydrolysis mechanisms, and intermediate ADP release during ATP hydrolysis, depending on the state of the transmembrane domains. Disulfide crosslinking of cysteines introduced within the transmembrane helices revealed that they interact within and between molecules, in particular near the extracellular domain, and that activity depends on their organization. Both helices exhibit a high degree of rotational mobility, and the ability to undergo dynamic motions is required for activity and regulated by substrate binding. Recent reports suggest that membrane composition can regulate NTPDase activity. We propose that mechanical bilayer properties, potentially elasticity, might regulate CD39 by altering the balance between stability and mobility of its transmembrane domains.
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spelling pubmed-22544772008-02-27 CD39, NTPDase 1, is attached to the plasma membrane by two transmembrane domains. Why? Grinthal, Alison Guidotti, Guido Purinergic Signal Invited Review Since the identification of CD39 and other members of the e-NTPDase (ecto-nucleoside triphosphate diphosphohydrolase) family as the primary enzymes responsible for cell surface nucleotide hydrolysis, one of their most intriguing features has been their unusual topology. The active site lies in the large extracellular region, but instead of being anchored in the membrane by a single transmembrane domain or lipid link like other ectoenzymes, CD39 has two transmembrane domains, one at each end. In this review we discuss evidence that the structure and dynamics of the transmembrane helices are intricately connected to enzymatic function. Removal of either or both transmembrane domains or disruption of their native state by detergent solubilization reduces activity by 90%, indicating that native function requires both transmembrane domains to be present and in the membrane. Enzymatic and mutational analysis of the native and truncated forms has shown that the active site can exist in distinct functional states characterized by different total activities, substrate specificities, hydrolysis mechanisms, and intermediate ADP release during ATP hydrolysis, depending on the state of the transmembrane domains. Disulfide crosslinking of cysteines introduced within the transmembrane helices revealed that they interact within and between molecules, in particular near the extracellular domain, and that activity depends on their organization. Both helices exhibit a high degree of rotational mobility, and the ability to undergo dynamic motions is required for activity and regulated by substrate binding. Recent reports suggest that membrane composition can regulate NTPDase activity. We propose that mechanical bilayer properties, potentially elasticity, might regulate CD39 by altering the balance between stability and mobility of its transmembrane domains. Springer Netherlands 2006-06-01 2006-06 /pmc/articles/PMC2254477/ /pubmed/18404478 http://dx.doi.org/10.1007/s11302-005-5907-8 Text en © Springer 2006
spellingShingle Invited Review
Grinthal, Alison
Guidotti, Guido
CD39, NTPDase 1, is attached to the plasma membrane by two transmembrane domains. Why?
title CD39, NTPDase 1, is attached to the plasma membrane by two transmembrane domains. Why?
title_full CD39, NTPDase 1, is attached to the plasma membrane by two transmembrane domains. Why?
title_fullStr CD39, NTPDase 1, is attached to the plasma membrane by two transmembrane domains. Why?
title_full_unstemmed CD39, NTPDase 1, is attached to the plasma membrane by two transmembrane domains. Why?
title_short CD39, NTPDase 1, is attached to the plasma membrane by two transmembrane domains. Why?
title_sort cd39, ntpdase 1, is attached to the plasma membrane by two transmembrane domains. why?
topic Invited Review
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2254477/
https://www.ncbi.nlm.nih.gov/pubmed/18404478
http://dx.doi.org/10.1007/s11302-005-5907-8
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