In Vivo Readout of CFTR Function: Ratiometric Measurement of CFTR-Dependent Secretion by Individual, Identifiable Human Sweat Glands

To assess CFTR function in vivo, we developed a bioassay that monitors and compares CFTR-dependent and CFTR-independent sweat secretion in parallel for multiple (∼50) individual, identified glands in each subject. Sweating was stimulated by intradermally injected agonists and quantified by optically...

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Autores principales: Wine, Jeffrey J., Char, Jessica E., Chen, Jonathan, Cho, Hyung-ju, Dunn, Colleen, Frisbee, Eric, Joo, Nam Soo, Milla, Carlos, Modlin, Sara E., Park, Il-Ho, Thomas, Ewart A. C., Tran, Kim V., Verma, Rohan, Wolfe, Marlene H.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2013
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Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3811985/
https://www.ncbi.nlm.nih.gov/pubmed/24204751
http://dx.doi.org/10.1371/journal.pone.0077114
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author Wine, Jeffrey J.
Char, Jessica E.
Chen, Jonathan
Cho, Hyung-ju
Dunn, Colleen
Frisbee, Eric
Joo, Nam Soo
Milla, Carlos
Modlin, Sara E.
Park, Il-Ho
Thomas, Ewart A. C.
Tran, Kim V.
Verma, Rohan
Wolfe, Marlene H.
author_facet Wine, Jeffrey J.
Char, Jessica E.
Chen, Jonathan
Cho, Hyung-ju
Dunn, Colleen
Frisbee, Eric
Joo, Nam Soo
Milla, Carlos
Modlin, Sara E.
Park, Il-Ho
Thomas, Ewart A. C.
Tran, Kim V.
Verma, Rohan
Wolfe, Marlene H.
author_sort Wine, Jeffrey J.
collection PubMed
description To assess CFTR function in vivo, we developed a bioassay that monitors and compares CFTR-dependent and CFTR-independent sweat secretion in parallel for multiple (∼50) individual, identified glands in each subject. Sweating was stimulated by intradermally injected agonists and quantified by optically measuring spherical sweat bubbles in an oil-layer that contained dispersed, water soluble dye particles that partitioned into the sweat bubbles, making them highly visible. CFTR-independent secretion (M-sweat) was stimulated with methacholine, which binds to muscarinic receptors and elevates cytosolic calcium. CFTR-dependent secretion (C-sweat) was stimulated with a β-adrenergic cocktail that elevates cytosolic cAMP while blocking muscarinic receptors. A C-sweat/M-sweat ratio was determined on a gland-by-gland basis to compensate for differences unrelated to CFTR function, such as gland size. The average ratio provides an approximately linear readout of CFTR function: the heterozygote ratio is ∼0.5 the control ratio and for CF subjects the ratio is zero. During assay development, we measured C/M ratios in 6 healthy controls, 4 CF heterozygotes, 18 CF subjects and 4 subjects with ‘CFTR-related’ conditions. The assay discriminated all groups clearly. It also revealed consistent differences in the C/M ratio among subjects within groups. We hypothesize that these differences reflect, at least in part, levels of CFTR expression, which are known to vary widely. When C-sweat rates become very low the C/M ratio also tended to decrease; we hypothesize that this nonlinearity reflects ductal fluid absorption. We also discovered that M-sweating potentiates the subsequent C-sweat response. We then used potentiation as a surrogate for drugs that can increase CFTR-dependent secretion. This bioassay provides an additional method for assessing CFTR function in vivo, and is well suited for within-subject tests of systemic, CFTR-directed therapeutics.
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spelling pubmed-38119852013-11-07 In Vivo Readout of CFTR Function: Ratiometric Measurement of CFTR-Dependent Secretion by Individual, Identifiable Human Sweat Glands Wine, Jeffrey J. Char, Jessica E. Chen, Jonathan Cho, Hyung-ju Dunn, Colleen Frisbee, Eric Joo, Nam Soo Milla, Carlos Modlin, Sara E. Park, Il-Ho Thomas, Ewart A. C. Tran, Kim V. Verma, Rohan Wolfe, Marlene H. PLoS One Research Article To assess CFTR function in vivo, we developed a bioassay that monitors and compares CFTR-dependent and CFTR-independent sweat secretion in parallel for multiple (∼50) individual, identified glands in each subject. Sweating was stimulated by intradermally injected agonists and quantified by optically measuring spherical sweat bubbles in an oil-layer that contained dispersed, water soluble dye particles that partitioned into the sweat bubbles, making them highly visible. CFTR-independent secretion (M-sweat) was stimulated with methacholine, which binds to muscarinic receptors and elevates cytosolic calcium. CFTR-dependent secretion (C-sweat) was stimulated with a β-adrenergic cocktail that elevates cytosolic cAMP while blocking muscarinic receptors. A C-sweat/M-sweat ratio was determined on a gland-by-gland basis to compensate for differences unrelated to CFTR function, such as gland size. The average ratio provides an approximately linear readout of CFTR function: the heterozygote ratio is ∼0.5 the control ratio and for CF subjects the ratio is zero. During assay development, we measured C/M ratios in 6 healthy controls, 4 CF heterozygotes, 18 CF subjects and 4 subjects with ‘CFTR-related’ conditions. The assay discriminated all groups clearly. It also revealed consistent differences in the C/M ratio among subjects within groups. We hypothesize that these differences reflect, at least in part, levels of CFTR expression, which are known to vary widely. When C-sweat rates become very low the C/M ratio also tended to decrease; we hypothesize that this nonlinearity reflects ductal fluid absorption. We also discovered that M-sweating potentiates the subsequent C-sweat response. We then used potentiation as a surrogate for drugs that can increase CFTR-dependent secretion. This bioassay provides an additional method for assessing CFTR function in vivo, and is well suited for within-subject tests of systemic, CFTR-directed therapeutics. Public Library of Science 2013-10-24 /pmc/articles/PMC3811985/ /pubmed/24204751 http://dx.doi.org/10.1371/journal.pone.0077114 Text en © 2013 Wine et al http://creativecommons.org/licenses/by/4.0/ This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are properly credited.
spellingShingle Research Article
Wine, Jeffrey J.
Char, Jessica E.
Chen, Jonathan
Cho, Hyung-ju
Dunn, Colleen
Frisbee, Eric
Joo, Nam Soo
Milla, Carlos
Modlin, Sara E.
Park, Il-Ho
Thomas, Ewart A. C.
Tran, Kim V.
Verma, Rohan
Wolfe, Marlene H.
In Vivo Readout of CFTR Function: Ratiometric Measurement of CFTR-Dependent Secretion by Individual, Identifiable Human Sweat Glands
title In Vivo Readout of CFTR Function: Ratiometric Measurement of CFTR-Dependent Secretion by Individual, Identifiable Human Sweat Glands
title_full In Vivo Readout of CFTR Function: Ratiometric Measurement of CFTR-Dependent Secretion by Individual, Identifiable Human Sweat Glands
title_fullStr In Vivo Readout of CFTR Function: Ratiometric Measurement of CFTR-Dependent Secretion by Individual, Identifiable Human Sweat Glands
title_full_unstemmed In Vivo Readout of CFTR Function: Ratiometric Measurement of CFTR-Dependent Secretion by Individual, Identifiable Human Sweat Glands
title_short In Vivo Readout of CFTR Function: Ratiometric Measurement of CFTR-Dependent Secretion by Individual, Identifiable Human Sweat Glands
title_sort in vivo readout of cftr function: ratiometric measurement of cftr-dependent secretion by individual, identifiable human sweat glands
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3811985/
https://www.ncbi.nlm.nih.gov/pubmed/24204751
http://dx.doi.org/10.1371/journal.pone.0077114
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