Nature Neuroscience homepage
 Journal home > Archive > Table of Contents > Article > Abstract
Journal home
Advance online publication
Current issue
Archive
Press releases
Supplements
Focuses
Guide to authors
Online submissionOnline submission
Permissions
For referees
Free online issue
Contact the journal
Subscribe
Advertising
work@npg
naturereprints
About this site
For librarians
 
NPG Resources
Nature
Nature Reviews Neuroscience
Nature Cell Biology
Nature Medicine
Neuroscience Gateway
UCSD-Nature Signaling Gateway
NPG Subject areas
Biotechnology
Cancer
Chemistry
Clinical Medicine
Dentistry
Development
Drug Discovery
Earth Sciences
Evolution & Ecology
Genetics
Immunology
Materials Science
Medical Research
Microbiology
Molecular Cell Biology
Neuroscience
Pharmacology
Physics
Browse all publications
Article
Nature Neuroscience  4, 997 - 1005 (2001)
Published online: 17 September 2001; | doi:10.1038/nn732

A post-docking role for active zone protein Rim

Sandhya P. Koushika1, 3, Janet E. Richmond2, 3, Gayla Hadwiger1, Robby M. Weimer2, Erik M. Jorgensen2 & Michael L. Nonet1

1  Department of Anatomy and Neurobiology, Washington University School of Medicine, 660 S. Euclid Avenue, Saint Louis, Missouri 63110, USA

2  Department of Biology, University of Utah, 257 South 1400 East, Salt Lake City, Utah 84112-0840, USA

3  The first two authors contributed equally to this work

Correspondence should be addressed to Michael L. Nonet nonetm@thalamus.wustl.edu
Rim1 was previously identified as a Rab3 effector localized to the presynaptic active zone in vertebrates. Here we demonstrate that C. elegans unc-10 mutants lacking Rim are viable, but exhibit behavioral and physiological defects that are more severe than those of Rab3 mutants. Rim is localized to synaptic sites in C. elegans, but the ultrastructure of the presynaptic densities is normal in Rim mutants. Moreover, normal levels of docked synaptic vesicles were observed in mutants, suggesting that Rim is not involved in the docking process. The level of fusion competent vesicles at release sites was reduced fivefold in Rim mutants, but calcium sensitivity of release events was unchanged. Furthermore, expression of a constitutively open form of syntaxin suppressed the physiological defects of Rim mutants, suggesting Rim normally acts to regulate conformational changes in syntaxin. These data suggest Rim acts after vesicle docking likely via regulating priming.

MORE ARTICLES LIKE THIS
These links to content published by NPG are automatically generated

REFERENCE
Synaptic Vesicle Fusion
Nature Encyclopaedia of Life Sciences
 See all 3 matches for Reference

REVIEWS
Snares and munc18 in synaptic vesicle fusion
Nature Reviews Neuroscience Review (01 Aug 2002)
 See all 4 matches for Reviews

NEWS AND VIEWS
pRIMing synaptic vesicles for fusion
Nature Neuroscience News and Views (01 Oct 2001)
UNC-13 and neurotransmitter release
Nature Neuroscience News and Views (01 Nov 1999)
 See all 3 matches for News And Views

RESEARCH
An open form of syntaxin bypasses the requirement for UNC-13 in vesicle priming
Nature Letters to Editor (19 Jul 2001)
 See all 14 matches for Research

 Top
Abstract
Previous | Next
Table of contents
Full textFull text
Download PDFDownload PDF
Send to a friendSend to a friend
Save this linkSave this link

Open Innovation Challenges

naturejobs

More science jobs
Post a job for free
Figures & Tables
See also: News and Views by Lloyd & Bellen
Export citation
natureproducts

Search buyers guide:

 
ADVERTISEMENT
 
Nature Neuroscience
ISSN: 1097-6256
EISSN: 1546-1726		 Journal home | Advance online publication | Current issue | Archive | Press releases | Supplements | Focuses | For authors | Online submission | Permissions | For referees | Free online issue | About the journal | Contact the journal | Subscribe | Advertising | work@npg | naturereprints | About this site | For librarians
Nature Publishing Group, publisher of Nature, and other science journals and reference works©2001 Nature Publishing Group | Privacy policy