Wednesday, 26 September 2012

Geometry plays a role in GPCR transmembrane signaling

Geometry plays a role in GPCR transmembrane signaling [ Back to EurekAlert! ] Public release date: 26-Sep-2012
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Contact: Rita Sullivan King
news@rupress.org
212-327-8603
Rockefeller University Press

A recent study in The Journal of General Physiology characterizes the movement of rhodopsin, a GPCR and member of a large family of transmembrane receptors responsible for many cellular responses and involved in many human diseases.

In living Xenopus rod photoreceptor cells, rhodopsin is found in stacks of disc membranes that are difficult to study due to their small size. Now, Peter Calvert (SUNY Upstate Medical University) and colleagues have developed an approach with two-photon microscopy that, for the first time, allows direct examination within the living cell of how the geometry of the micro-compartment will affect its signaling.

The team focused on the effect of micro-compartments formed by "incisures", radial membrane boundaries that segment the discs into smaller regions. These micro-compartments, defined by the rim and incisures, have a surface area similar to that of a human or mouse rod photoreceptor disc, so that the total number of components in the GPCR signaling cascade are conserved, and the downstream effects of a captured photon of light are similar. Calvert and colleagues used a novel high-resolution approach to monitor fluorescently labeled rhodopsin as it diffused in the disc membrane. The team developed a model of molecular diffusion to interpret the results that explicitly took the measured micro-compartments into account, and found that the boundary geometry, not heterogeneity in diffusion or a "bound fraction," was sufficient to explain differences in the extent of diffusion or rhodopsin in different regions of the disc.

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About The Journal of General Physiology (JGP

Founded in 1918, JGP is published by The Rockefeller University Press. All editorial decisions on manuscripts submitted are made by active scientists. JGP content is posted to PubMed Central, where it is available to the public for free six months after publication. Authors retain copyright of their published works and third parties may reuse the content for non-commercial purposes under a creative commons license. For more information, please visit www.jgp.org.

Najafi, M., et al. 2012. J. Gen. Physiol. 140:249. Adler, E.M. 2012. J. Gen. Physio. 140:341.



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Geometry plays a role in GPCR transmembrane signaling [ Back to EurekAlert! ] Public release date: 26-Sep-2012
[ | E-mail | Share Share ]

Contact: Rita Sullivan King
news@rupress.org
212-327-8603
Rockefeller University Press

A recent study in The Journal of General Physiology characterizes the movement of rhodopsin, a GPCR and member of a large family of transmembrane receptors responsible for many cellular responses and involved in many human diseases.

In living Xenopus rod photoreceptor cells, rhodopsin is found in stacks of disc membranes that are difficult to study due to their small size. Now, Peter Calvert (SUNY Upstate Medical University) and colleagues have developed an approach with two-photon microscopy that, for the first time, allows direct examination within the living cell of how the geometry of the micro-compartment will affect its signaling.

The team focused on the effect of micro-compartments formed by "incisures", radial membrane boundaries that segment the discs into smaller regions. These micro-compartments, defined by the rim and incisures, have a surface area similar to that of a human or mouse rod photoreceptor disc, so that the total number of components in the GPCR signaling cascade are conserved, and the downstream effects of a captured photon of light are similar. Calvert and colleagues used a novel high-resolution approach to monitor fluorescently labeled rhodopsin as it diffused in the disc membrane. The team developed a model of molecular diffusion to interpret the results that explicitly took the measured micro-compartments into account, and found that the boundary geometry, not heterogeneity in diffusion or a "bound fraction," was sufficient to explain differences in the extent of diffusion or rhodopsin in different regions of the disc.

###

About The Journal of General Physiology (JGP

Founded in 1918, JGP is published by The Rockefeller University Press. All editorial decisions on manuscripts submitted are made by active scientists. JGP content is posted to PubMed Central, where it is available to the public for free six months after publication. Authors retain copyright of their published works and third parties may reuse the content for non-commercial purposes under a creative commons license. For more information, please visit www.jgp.org.

Najafi, M., et al. 2012. J. Gen. Physiol. 140:249. Adler, E.M. 2012. J. Gen. Physio. 140:341.



[ Back to EurekAlert! ] [ | E-mail | Share Share ]

?


AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert! system.


Source: http://www.eurekalert.org/pub_releases/2012-09/rup-gpa092612.php

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