NSF Org:	IOS Division Of Integrative Organismal Systems
Recipient:	TRUSTEES OF TUFTS COLLEGE
Initial Amendment Date:	May 17, 1999
Latest Amendment Date:	May 14, 2001
Award Number:	9817251
Award Instrument:	Standard Grant
Program Manager:	Mark Kirk IOS  Division Of Integrative Organismal Systems BIO  Directorate for Biological Sciences
Start Date:	May 15, 1999
End Date:	April 30, 2002 (Estimated)
Total Intended Award Amount:	$159,868.00
Total Awarded Amount to Date:	$159,868.00
Funds Obligated to Date:	FY 1999 = $159,868.00
History of Investigator:	James Marchand (Principal Investigator) jmarchan@opal.tufts.edu
Recipient Sponsored Research Office:	Tufts University 80 GEORGE ST MEDFORD MA  US  02155-5519 (617)627-3696
Sponsor Congressional District:	05
Primary Place of Performance:	Tufts University School of Medicine Boston MA  US  02111
Primary Place of Performance Congressional District:	08
Unique Entity Identifier (UEI):	WL9FLBRVPJJ7
Parent UEI:	WL9FLBRVPJJ7
NSF Program(s):	SENSORY SYSTEMS
Primary Program Source:	app-0199
Program Reference Code(s):	1096, 9107, BIOT
Program Element Code(s):	118500
Award Agency Code:	4900
Fund Agency Code:	4900
Assistance Listing Number(s):	47.074

ABSTRACT

The sense of smell, olfaction, depends on receptor nerve cells in the sensory tissue of the nose, which carry information to the brain. This information is encoded in the pattern of physiological activity of the receptor cells. Receptor cells have molecules on their surfaces that bind to odorant stimuli when present. It remains unknown, however, which odors are recognized by each of the olfactory receptors. This question of the molecular code for olfaction is a central question in olfactory research. This study approaches the issue with a powerful combination of voltage-sensitive dyes and molecular tagging, using the salamander nose as a model system having a relatively flat sheet of sensory tissue with limited numbers of receptor types. Physiological responses are localized by voltage-sensitive dyes at a cellular level of resolution, to identify which cells respond to particular odors. For the same tissue, molecular probes specific for olfactory receptor molecules are then used to histochemically label cells with particular receptors. Results showing which cells have types of response specificity matching up with particular receptor molecules will provide direct evidence to determine how a code for olfaction can be created.
The potential impact of this work is very high for chemosensory sciences because how organisms recognize molecules in the environment is crucial for a variety of behaviors; the basic findings on molecular recognition also will be pertinent for understanding molecular recognition mechanisms in other sensory systems and in other parts of the brain.

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