about
Pseudogenization of a sweet-receptor gene accounts for cats' indifference toward sugarReduced body weight is a common effect of gene knockout in miceBitter receptor gene (TAS2R38), 6-n-propylthiouracil (PROP) bitterness and alcohol intake.The molecular basis of individual differences in phenylthiocarbamide and propylthiouracil bitterness perceptionGenetic analysis of chemosensory traits in human twinsNutrient preference and diet-induced adiposity in C57BL/6ByJ and 129P3/J miceSweet taste receptor gene variation and aspartame taste in primates and other speciesAge-related differences in bitter taste and efficacy of bitter blockersPreferences for salty and sweet tastes are elevated and related to each other during childhoodForty mouse strain survey of water and sodium intake.T2R38 taste receptor polymorphisms underlie susceptibility to upper respiratory infectionThe human sweet tooth.The bitter taste receptor T2R38 is an independent risk factor for chronic rhinosinusitis requiring sinus surgery.Genetics of taste receptors.Gustation genetics: sweet gustducin!The perception of quinine taste intensity is associated with common genetic variants in a bitter receptor cluster on chromosome 12Psychophysical dissection of genotype effects on human bitter perception.Body fat distribution and organ weights of 14 common strains and a 22-strain consomic panel of ratsHuman bitter perception correlates with bitter receptor messenger RNA expression in taste cells.Genome scan for human obesity and linkage to markers in 20q13.Polymorphisms in the taste receptor gene (Tas1r3) region are associated with saccharin preference in 30 mouse strains.No relationship between sequence variation in protein coding regions of the Tas1r3 gene and saccharin preference in ratsAllelic variation of the Tas1r3 taste receptor gene selectively affects behavioral and neural taste responses to sweeteners in the F2 hybrids between C57BL/6ByJ and 129P3/J mice.Research issues in genetic testing of adolescents for obesity.Genetic, physical, and comparative map of the subtelomeric region of mouse Chromosome 4.Loci on chromosomes 2, 4, 9, and 16 for body weight, body length, and adiposity identified in a genome scan of an F2 intercross between the 129P3/J and C57BL/6ByJ mouse strainsHeritability and genetic covariation of sensitivity to PROP, SOA, quinine HCl, and caffeineQTL analysis of dietary obesity in C57BL/6byj X 129P3/J F2 mice: diet- and sex-dependent effects.The bamboo-eating giant panda (Ailuropoda melanoleuca) has a sweet tooth: behavioral and molecular responses to compounds that taste sweet to humans.A locus on mouse Chromosome 9 (Adip5) affects the relative weight of the gonadal but not retroperitoneal adipose depot.Quantitative trait loci for individual adipose depot weights in C57BL/6ByJ x 129P3/J F2 mice.The gustatory and olfactory systems during infancy: implications for development of feeding behaviors in the high-risk neonate.Children's perceptions about medicines: individual differences and taste.Voluntary ethanol consumption by mice: genome-wide analysis of quantitative trait loci and their interactions in a C57BL/6ByJ x 129P3/J F2 intercross.Major taste loss in carnivorous mammals.Relationship between bitter-taste receptor genotype and solid medication formulation usage among young children: a retrospective analysis.Birth of a new breed of supertaster.Forty mouse strain survey of body composition.Forty mouse strain survey of voluntary calcium intake, blood calcium, and bone mineral contentTwin study of the heritability of recognition thresholds for sour and salty taste.
P50
Q21090156-CBBE3227-7D45-49D3-871C-17A94A29E838Q21090156-ECFB7C14-2A89-4A10-99E7-4FA0844493ABQ21283780-A587DA70-A849-4D67-9353-45D1A30029E0Q24540123-8FA34DE9-2CBA-4ABD-A04C-21D1994DA135Q24540285-30CF44B8-F8F0-43F6-AE87-D42803BFC11AQ24610803-68016C47-C976-4C0F-AD5D-BA9034CB010FQ24630023-C449057C-B546-4FCA-B992-3865E93B8EA8Q28388576-AE48FEFB-DDEA-4375-9B7C-3B6184DA036AQ28541080-2F0AE449-42F7-4CE8-B488-35B6BDA47A1FQ28657681-3BE2E4C0-48D3-4A48-A129-26F354C03BF6Q30493706-B55507AE-7F40-4E38-8223-4B4C36E8F6D1Q30527825-FB4B89A3-4207-406C-985A-3474D3D9D401Q33255358-6C2AA335-C788-4E13-A09E-A043DBEA8842Q33848518-6E92D89A-52E9-4C0C-AE33-5B1E8749C228Q34037605-E59EC8A8-F1A4-4FA8-9A2C-F37ACAF4B0ADQ34075517-33D7D634-63A2-43E2-8C6E-C01DD6E02E2EQ34129017-12894F4C-FA61-4645-B0C8-1B19B9CAE1EEQ34146104-6B0F6766-A81C-444C-AE68-952F15068B17Q34179381-475FD5A2-45ED-476E-97D1-3D0E4D9AD1EEQ34370299-4584F2BC-2633-4FC4-9AE4-2A3BF6DBECE2Q34388612-4D41C595-F152-4A6B-BDED-A43A3F4FAFBCQ34441917-5F799CF1-AC11-4A0B-8DDC-A0D4947BD362Q34446439-428099B9-735B-46BD-B68D-0F9E1433D437Q34446447-6D14E6D3-32C6-4165-A266-9F2C7D0E43F2Q34451971-64970A61-6DF7-4F5C-A0F0-C780CFC6B9F5Q34482768-1990DCB5-2B94-4CD3-A607-38103B9B9A1DQ34535409-CA802CE9-4EAD-48FE-9BE0-E874CCB83D10Q34666910-4C4151EB-EB47-4FA9-97E9-152E5E8D435CQ34901756-A95F0578-7259-4DEE-8243-A66628BDD494Q35132385-273EDEFD-FFFB-4B4B-9E80-3C21AC7AFDA8Q35222170-4F1CA817-9448-4442-B866-6045C226FA62Q35225240-CC1238D8-A1DC-4A3A-AF8C-54C56FF2340AQ35571102-869A44BB-50A0-41E7-828F-AD05C9C83997Q35782413-D158FDF4-1C16-41A2-899B-DACC10FC7A01Q35786231-6EBC7C78-CCD8-4F4C-B43C-789A79423C88Q35882549-E7569144-8D20-4947-80AA-CEC4250A9FF6Q35927348-421D4D5A-EA19-419C-AA74-F152795633BAQ35929131-F972712F-F779-435C-8F3D-282C35A9845DQ36158114-C41AB1F7-37DB-4F9A-BC3A-913B1E9AEEBAQ36158423-0C879208-D7AB-40B5-8559-B26C1EA5509E
P50
description
hulumtuese
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Danielle R Reed
@nl
Danielle R Reed
@sl
Danielle R. Reed
@en
Danielle R. Reed
@es
Danielle Reed
@fr
type
label
Danielle R Reed
@nl
Danielle R Reed
@sl
Danielle R. Reed
@en
Danielle R. Reed
@es
Danielle Reed
@fr
prefLabel
Danielle R Reed
@nl
Danielle R Reed
@sl
Danielle R. Reed
@en
Danielle R. Reed
@es
Danielle Reed
@fr
P106
P1153
7402979742
P21
P31
P496
0000-0002-4374-6107