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Target Concepts:
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Query: UNIPROT:P21554 (
cannabinoid receptor
)
3,582
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Astrocytes possess GPCRs (G-protein-coupled receptors) for neuroactive substances and can respond via these receptors to signals originating from neurons as well as astrocytes. Like many transmembrane proteins, GPCRs exist in a dynamic equilibrium between receptors expressed at the plasma membrane and those present within intracellular trafficking compartments. The characteristics of GPCR trafficking within astrocytes have not been investigated. We therefore monitored the trafficking of recombinant fluorescent protein chimeras of the
CB1R
(cannabinoid receptor 1) that is thought to be expressed natively in astrocytes.
CB1R
chimeras displayed a marked punctate intracellular localization when expressed in cultured rat visual cortex astrocytes, an expression pattern reminiscent of native
CB1R
expression in these cells. Based upon trafficking characteristics, we found the existence of two populations of vesicular
CB1R
puncta: (i) relatively immobile puncta with movement characteristic of diffusion and (ii) mobile puncta with movement characteristic of active transport along cytoskeletal elements. The predominant direction of active transport is oriented radially to/from the nuclear region, which can be abolished by disruption of the microtubule cytoskeleton.
CB1R
puncta are localized within intracellular acidic organelles, mainly co-localizing with endocytic compartments. Constitutive trafficking of
CB1R
to and from the plasma membrane is an energetically costly endeavour whose function is at present unclear in astrocytes. However, given that intracellular CB1Rs can engage cell signalling pathways, it is likely that this process plays an important regulatory role.
ASN
Neuro 2009 Dec 08
PMID:Dynamic imaging of cannabinoid receptor 1 vesicular trafficking in cultured astrocytes. 1990 12
How does the brain process incoming information and produce thoughts? These questions represent, to all likelihood, the most challenging matters ever faced by natural sciences, matters which may never be fully comprehended. The evolution of the nervous system that, in about billion of years, brought into existence the human brain progressed through an ever-increasing complexity of neural networks. This evolution began from the diffuse nervous system, in which primordial neurons were able to sense the environmental inputs and convey them to effector organs and to the neighbouring neurons. At the next evolutionary stage the conglomerates of neuronal cell bodies, the ganglia, appeared, thus forming the primitive centralized nervous system. The developments which ensued went through a continuous increase in complexity of neuronal conglomerates, which eventually formed the central nervous system, which attained maximal perfection in mammals. In this issue of
ASN
NEURO, Osborne et al. have described details of real-time imaging of
cannabinoid receptor
trafficking in astrocytes, a technique that will help to elucidate the role of these receptors in the ever-increasing complex neural networks.
ASN
Neuro 2009 Dec 08
PMID:Filming the glial dreams: real-time imaging of cannabinoid receptor trafficking in astrocytes. 1990 35
