Apparent specific volumes and tastes of amino acids

The apparent specific volumes of 17 amino acids are determinedand compared with their tastes and predicted ranges of tastereported in earlier work. Most amino acids elicit many basictastes although one taste usually predominates. All D-aminoacids tasted (except proline and hydroxy prohne) are sweet andseven of the L-amino acids are sweet. Ten of the 16 L-aminoacids are bitter but two of these are both bitter and sweetin accordance with prediction from their apparent specific volumes.‘Spatial barriers’ account for the exclusion ofthe larger L-amino acids from sweet receptors. However, D-proline,the only reportedly purely bitter D-amino acid, is cyclic andthis explains its borderline position between the sweet andbitter regions, and the sweet-bitter taste of L-proline. Lowmol. wt amino acids, irrespective of whether they are D- orL-enantiomers, are always sweet, providing that their apparentspecific volumes are below 0.66 and that they do not generatesuprathreshold concentrations of protons. The two dicarboxylicamino acids, glutamic and aspartic are sour. Apparent specificvolumes represent the effective size of solutes in water dueto their intrinsic molecular architecture. The values reportedhere are used to interpret steric exclusion of certain enantiomersfrom the taste receptors. These results support the idea thatapparent specific volume is a determinant of taste quality.     

棉铃虫幼虫对人类呈味物质的取食反应

利用叶碟法在室内测定了棉铃虫对人类酸、甜、苦、咸4种基本呈味物质和麻、辣味2种植物提取物的取食反应。正交试验结果表明,棉铃虫幼虫对用甜味、苦味和辣味物质(蔗糖、奎宁和辣椒提取物)处理过的烟叶取食选择率较高,对这3种呈味物质表现出有较好的适应性;而幼虫对咸味、酸味和麻味物质(氯化钠、柠檬酸和花椒提取物)处理过的烟叶取食量较少,这3种呈味物质表现出较强的拒食活性。在选择性条件下,幼虫的取食量与花椒提取物剂量显著相关;而在非选择性条件下,幼虫的取食量与氯化钠剂量显著相关。     

INFLUENCE OF COLOR ON TASTE THRESHOLDS

Increasing molar concentrations of sweet, sour, bitter and saltywere evaluated in colorless and colored (red, green, yellow)water solutions by 28 untrained students. Green color statisticallyincreased sweet taste threshold sensitivity while yellow colordecreased taste sensitivity. Red color did not affect the tastesensitivity of sweet. In the case of sour, both yellow and greencolors decreased sensitivity with red having no affect. Redcolor decreased bitter taste sensitivity with yellow and greencolor having no effect. No significant differences due to coloraffected salty taste sensitivity. Thus, psychological colorassociation can alter reports of certain basic taste sensations. ^*Scientific Series Paper Number 1764 of the Colorado State UniversityExperiment Station.     

Molecular mechanisms underlying the reception and transmission of sour taste information

Taste enables organisms to determine the properties of ingested substances by conveying information regarding the five basic taste modalities: sweet, salty, sour, bitter, and umami. The sweet, salty, and umami taste modalities convey the carbohydrate, electrolyte, and glutamate content of food, indicating its desirability and stimulating appetitive responses. The sour and bitter modalities convey the acidity of food and the presence of potential toxins, respectively, stimulating aversive responses to such tastes. In recent years, the receptors mediating sweet, bitter, and umami tastes have been identified as members of the T1R and T2R G-protein-coupled receptor families; however, the molecular mechanisms underlying sour taste detection have yet to be clearly elucidated. This review covers the molecular mechanisms proposed to mediate the detection and transmission of sour stimuli, focusing on polycystic kidney disease 1-like 3 (Pkd1l3), Pkd2l1, and carbonic anhydrase 4 (Car4).     

Adiabatic compressibility of myosin subfragment-1 and heavy meromyosin with or without nucleotide.

The partial specific adiabatic compressibilities of myosin subfragment-1 (S1) and heavy meromyosin (HMM) of skeletal muscle in solution were determined by measuring the density and the sound velocity of the solution. The partial specific volumes of S1 and HMM were 0.713 and 0.711 cm3/g, respectively. The partial specific adiabatic compressibilities of S1 and HMM were 4.2 x 10(-12) and 2.9 x 10(-12) cm2/dyn, respectively. These values are in the same range as the most of globular proteins so far studied. The result indicates that the flexibility of S1 region almost equals to that of HMM. After binding to ADP.orthovanadate, S1 and HMM became softer than their complexes with ADP. The bulk moduli of S1 and HMM were of the order of (4-6) x 10(10) dyn/cm2, which are very comparable with the bulk modulus of muscle fiber.     

The molecular biology of taste transduction

Taste cells respond to a wide variety of chemical stimuli: certain ions are perceived as salty (Na⁺) or sour (H⁺); other small molecules are perceived as sweet (sugars) and bitter (alkaloids). Taste has evolutionary value allowing animals to respond positively (to sweet carhohydrates and salty NaCl) or aversively (to bitter poisons and corrosive acids). Recently, some of the proteins involved in taste transduction have been cloned. Several different G proteins have been identified and cloned from taste tissue: gustducin is a taste cell specific G protein closely related to the transducins. Work is under way to clone additional components of the taste transduction pathways. The combination of electrophysiology, biochemistry and molecular biology is being used to characterize taste receptor cells and their sensory transduction mechanisms.     

TASTE INTENSITIES OF OIL-IN-WATER EMULSIONS WITH VARYING FAT CONTENT

The objective of this study was to determine the effect fat has on the intensity of sweet, salty, sour, bitter and umami tastes in oil-in-water emulsions. The first experiment used two levels of fat (9% and 17% in oil-in-water emulsions) and two intensities of each taste (high and low). We compared the taste intensities of these emulsions to the intensities of oil-free samples with equal total volume, and to oil free samples of the same aqueous taste compound concentrations. Because of potential confusion between taste intensity and viscosity, we repeated the experiment, having panelists rate both thickness and taste intensity. Diluting with oil, compared to diluting with water, decreased bitterness, but increased the intensity of salty, sweet, sour and umami tastes. When compared to samples with equal aqueous taste compound concentrations, fat suppressed bitterness, but had no effect on the other tastes.     

Taste receptor proteins

The chemistry of taste has eluded widespread investigation until only recently. Of the four basic taste qualities — sweet, salty, sour and bitter, only sweet and to some lesser extent — bitter — have had inroads made on the molecular level. Carbon-14 labeled sugars are preferently bound to taste bud proteins versus other non-sensory proteins. The binding of the sugars is in good agreement with their relative sweetness and graded conformational changes in protein molecules are seen, by a number of methods, upon these interactions. The protein may occur in two forms — soluble and membrane bound, and the bound form can be solubilized. Unique proteins are present in taste buds and would thus differentiate them from other non-sensory proteins. The sweet-sensitive protein activity has been studied in a number of animals, but purification and characterization in all has not proceeded to the point wherein comparisons can be made. Bitter reception has been suggested as the property of a protein from pig tongues, and an enzyme — phosphodiesterase has been found to be both activated and inhibited by bitter compounds. Lipids from gustatory tissue have been suggested as candidates for receptors for salty, sour and bitter, but not sweet stimulants.     

Characterization of pH-induced transitions of beta-lactoglobulin: ultrasonic, densimetric, and spectroscopic studies.

Depending on solution conditions, beta-lactoglobulin can exist in one of its six pH-dependent structural states. We have characterized the acid and basic-induced conformational transitions between these structural states over the pH range of pH 1 to pH 13. To this end, we have employed high-precision ultrasonic and densimetric measurements coupled with fluorescence and CD spectroscopic data. Our combined spectroscopic and volumetric results have revealed five pH-induced transitions of beta-lactoglobulin between pH 1 and pH 13. The first transition starts at pH 2 and is not completed even at pH 1, our lowest experimental pH. This transition is followed by the dimer-to-monomer transition of beta-lactoglobulin between pH 2.5 and pH 4. The dimer-to-monomer transition is accompanied by decreases in volume, v degrees (-0.008(+/-0.003) cm3 x g(-1)), and adiabatic compressibility, k degrees (S) (-(0.7(+/-0.4))x10(-6) cm3 x g(-1) x bar(-1)). We interpret the observed changes in volume and compressibility associated with the dimer-to-monomer transition of beta-lactoglobulin, in conjunction with X-ray crystallographic data, as suggesting a 7 % increase in protein hydration, with the hydration changes being localized in the area of contact between the two monomeric subunits. The so-called N-to-Q transition of beta-lactoglobulin occurs between pH 4.5 and pH 6 and is accompanied by increases in volume, v degrees (0.004(+/-0.003) cm3 x g(-1)), and compressibility, k degrees (S) ((0.7(+/-0.4))x10(-6) cm3 x g(-1) x bar(-1)). The Tanford transition of beta-lactoglobulin is centered at pH 7.5 and is accompanied by a decrease in volume, v degrees (-0.006(+/-0.003) cm3 x g(-1)), and an increase in compressibility, k degrees (S) ((1.5(+/-0.5))x10(-6) cm3 x g(-1) x bar(-1)). Based on these volumetric results, we propose that the Tanford transition is accompanied by a 5 to 10 % increase in the protein hydration and a loosening of the interior packing of beta-lactoglobulin as reflected in a 12 % increase in its intrinsic compressibility. Finally, above pH 9, the protein undergoes irreversible base-induced unfolding which is accompanied by decreases in v degrees (-0.014(+/-0.003) cm3 x g(-1)) and k degrees (S) (-(7.0(+/-0.5))x10(-6) cm3 x g(-1) x bar(-1)). Combining these results with our CD spectroscopic data, we propose that, in the base-induced unfolded state of beta-lactoglobulin, only 80 % of the surface area of the fully unfolded conformation is exposed to the solvent. Thus, in so far as solvent exposure is concerned, the base-induced unfolded states of beta-lactoglobulin retains some order, with 20 % of its amino acid residues remaining solvent inaccessible.     

Responses of Primate Taste Cortex Neurons to the Astringent Tastant Tannic Acid

In order to advance knowledge of the neural control of feeding,we investigated the cortical representation of the taste oftannic acid, which produces the taste of astringency. It isa dietary component of biological importance particularly toarboreal primates. Recordings were made from 74 taste responsiveneurons in the orbitofrontal cortex. Single neurons were foundthat were tuned to respond to 0.001 M tannic acid, and representeda subpopulation of neurons that was distinct from neurons responsiveto the tastes of glucose (sweet), NaCl (salty), HCI (sour),quinine (bitter) and monosodium glutamate (umami). In addition,across the population of 74 neurons, tannic acid was as wellrepresented as the tastes of NaCI, HCI quinine or monosodiumglutamate. Multidimensional scaling analysis of the neuronalresponses to the tastants indicates that tannic acid lies outsidethe boundaries of the four conventional taste qualities (sweet,sour, bitter and salty). Taken together these data indicatethat the astringent taste of tannic acid should be consideredas a distinct taste quality, which receives a separate representationfrom sweet, salt, bitter and sour in the primate cortical tasteareas. Chem. Senses 21: 135–145, 1996.     

A serotonin-sensitive sensor for investigation of taste cell-to-cell communication

Taste receptor cells are the taste sensation elements for sour, salty, sweet, bitter and umami sensations. It was demonstrated that there are cell-to-cell communications between type II (sour) and type III (sweet, bitter and umami) taste cells. Serotonin (5-HT) is released from type III cells, which is the only type of taste cells that has synaptic process with sensory afferent fibers. Then, taste information is transmitted via fibers to the brain. During this process, 5-HT plays important roles in taste information transmission. In order to explore a sensor to detect 5-HT released from taste cell or taste cell networks, we develop a 5-HT sensitive sensor based on LAPS chip. This sensor performs with a detection limit of 3.3 × 10(-13)M and a sensitivity of 19.1 mV per concentration decade. Upon the stimuli of sour and mix (bitter, sweet and umami) tastants, 5-HT released from taste cells could be detected flexibly, benefit from the addressability of LAPS chip. The experimental results show that the local concentration of 5-HT is around several nM, which is consistent with those from other methods. In addition, immunofluorescent imaging technique is utilized to confirm the functional existence of both type II and III cells in a cluster of isolated taste cells. Different types of taste cells are labeled with corresponding specific antibody. This 5-HT sensitive LAPS chip provides a potential and promising way to detect 5-HT and to investigate the taste coding and information communication mechanisms.     

Inner-sphere complexes of divalent cations with single-stranded poly(rA) and poly(rU)

A combination of ultrasound velocimetry, density, and UV spectroscopy has been employed to study the hydration effects of binding of Mn(2+) and alkaline-earth cations to poly(rA) and poly(rU) single strands. The hydration effects, obtained from volume and compressibility measurements, are positive due to overlapping the hydration shells of interacting molecules and consequently releasing the water molecules to bulk state. The volume effects of the binding to poly(rA), calculated per mole of cations, range from 30.6 to 40.6 cm(3) mol(-1) and the compressibility effects range from 59.2 x 10(-4) to 73.6 x 10(-4) cm(3) mol(-1) bar(-1). The volume and compressibility effects for poly(rU) are approximately 17 cm(3) mol(-1) and approximately 50 x 10(-4) cm(3) mol(-1) bar(-1), respectively. The comparative analysis of the dehydration effects suggests that the divalent cations bind to the polynucleotides in inner-sphere manner. In the case of poly(rU) the dehydration effects correspond to two direct coordination, probably between adjacent phosphate groups. The optical study did not reveal any effects of cation on the secondary structure or aggregation of poly(rU). In the case of single-helical poly(rA) binding is more specific: dehydration effects correspond to three to five direct contacts and must involve atomic groups of adenines, and the divalent cations stabilize and aggregate the polynucleotide.     

The good taste of peptides

The taste of peptides is seldom one of the most relevant issues when one considers the many important biological functions of this class of molecules. However, peptides generally do have a taste, covering essentially the entire range of established taste modalities: sweet, bitter, umami, sour and salty. The last two modalities cannot be attributed to peptides as such because they are due to the presence of charged terminals and/or charged side chains, thus reflecting only the zwitterionic nature of these compounds and/or the nature of some side chains but not the electronic and/or conformational features of a specific peptide. The other three tastes, that is, sweet, umami and bitter, are represented by different families of peptides. This review describes the main peptides with a sweet, umami or bitter taste and their relationship with food acceptance or rejection. Particular emphasis will be given to the sweet taste modality, owing to the practical and scientific relevance of aspartame, the well‐known sweetener, and to the theoretical importance of sweet proteins, the most potent peptide sweet molecules. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Autonomic nervous system responses associated with primary tastes

The hedonic dimension of the taste sensation plays a crucial role in the control of many taste-mediated responses related to food ingestion or rejection. The purpose of this study was to evaluate the emotional reactivity associated with each primary taste (sweet, salty, sour and bitter) through analysis of the variations of autonomic nervous system (ANS) parameters. Thirty-four healthy non-smoker volunteer subjects (17 males and 17 females, mean age = 28 years) participated in the experiment. Taste stimuli were solutions of 0.3 M sucrose (sweet), 0.15 M NaCl (salty), 0.02 M citric acid (sour) and 0.00015 M quinine sulfate (bitter). Evian mineral water was used as the diluent and control (neutral taste). Throughout the test, five ANS parameters (skin potential and skin resistance, skin blood flow and skin temperature, and instantaneous heart rate) were simultaneously and continuously recorded. Results of the ANOVA evidenced a significant effect of primary taste on skin resistance amplitude (P: < 0.001) and duration (P: < 0.0001), skin temperature amplitude (P: < 0.001), skin blood flow amplitude (vasoconstriction) (P: < 0.0001) and instantaneous heart rate increase (P: < 0.0001). Skin resistance and cardiac responses were the most relevant ANS parameters to distinguish among the taste solutions. The four primary tastes could be associated with significantly different ANS responses in relation to their hedonic valence: the pleasantly connoted and innate-accepted sweet taste induced the weakest ANS responses whereas the unpleasant connoted tastes (salty, sour and bitter) induced stronger ANS responses, the innate-rejected bitter taste inducing the strongest ones. Such a neurovegetative characterization of each primary taste could provide references for the hedonic analysis of the more complex gustative sensation attached to foods.     

Coding of sweet,bitter, and umami tastes: different receptor cells sharing similar signaling pathways

Mammals can taste a wide repertoire of chemosensory stimuli. Two unrelated families of receptors (T1Rs and T2Rs) mediate responses to sweet, amino acids, and bitter compounds. Here, we demonstrate that knockouts of TRPM5, a taste TRP ion channel, or PLCbeta2, a phospholipase C selectively expressed in taste tissue, abolish sweet, amino acid, and bitter taste reception, but do not impact sour or salty tastes. Therefore, despite relying on different receptors, sweet, amino acid, and bitter transduction converge on common signaling molecules. Using PLCbeta2 taste-blind animals, we then examined a fundamental question in taste perception: how taste modalities are encoded at the cellular level. Mice engineered to rescue PLCbeta2 function exclusively in bitter-receptor expressing cells respond normally to bitter tastants but do not taste sweet or amino acid stimuli. Thus, bitter is encoded independently of sweet and amino acids, and taste receptor cells are not broadly tuned across these modalities.     

Activation of Polycystic Kidney Disease-2-like 1 (PKD2L1)-PKD1L3 Complex by Acid in Mouse Taste Cells

Five basic tastes (bitter, sweet, umami, salty, and sour) are detected in the four taste areas where taste buds reside. Although molecular mechanisms for detecting bitter, sweet, and umami have been well clarified, those for sour and salty remain poorly understood. Several channels including acid-sensing ion channels have been proposed as candidate sour receptors, but they do not encompass all sour-sensing abilities in vivo. We recently reported a novel candidate for sour sensing, the polycystic kidney disease-2-like 1 (PKD2L1)-PKD1L3 channel complex. This channel is not a traditional ligand-gated channel and is gated open only after removal of an acid stimulus, called an off response. Here we show that off responses upon acid stimulus are clearly observed in native taste cells from circumvallate, but not fungiform papillae, of glutamate decarboxylase 67-green fluorescent protein (GAD67-GFP) knock-in mice, from which Type III taste cells can be visualized, using Ca²⁺ imaging and patch clamp methods. Off responses were detected in most cells where PKD2L1 immunoreactivity was observed. Interestingly, the pH threshold for acid-evoked intracellular Ca²⁺ increase was around 5.0, a value much higher than that observed in HEK293 cells expressing the PKD2L1-PKD1L3 complex. Thus, PKD2L1-PKD1L3-mediated acid-evoked off responses occurred both in HEK293 cells and in native taste cells, suggesting the involvement of the PKD2L1-PKD1L3 complex in acid sensing in vivo.     

The Hydrostatic and Hydrodynamic Volumes of Polyols in Aqueous Solutions and Their Sweet Taste

The tastes and solution properties of sugar alcohols were studiedin an attempt to illuminate the mechanism of sweet taste chemoreception.The SMURF method was used to measure taste time-intensity ofaqueous solutions of sugar alcohols and the results were interpretedusing the Stevens power function and kinetic parameters. Theapparent molar volumes, apparent specific volumes, partial molarvolumes, partial specific volumes and intrinsic viscositiesof the solutions were studied. Apparent molar volume reflectsthe size of the molecule in a hydrostatic state whereas intrinsicviscosity gives a measure of the size of the molecules in ahydrodynamic state. Generally the apparent molar volumes ofthe polyols are 6–13% greater than those of the parentsugars, indicating less interaction with the water structure.Apparent specific volume values can predict taste quality, andthe average apparent specific volume for the sugar alcoholsstudied fits within the central part of the sweet range, i.e.0.5–0.68 cm³/g, which accords with their ability to elicita pure sweet taste response. Intensities and persistences ofsweetness in the polyols followed the same trend as intrinsicviscosities. Chem. Senses 22: 149–161, 1997.     

Some Basic Psychophysics of Calcium Salt Solutions

Detection thresholds and the taste qualities of suprathresholdconcentrations of calcium salt solutions were assessed. Averagetaste detection thresholds for calcium chloride (CaCl₂), lactate(CaLa), hydroxide, phosphate and gluconate ranged between 8and 50 mM, with no reliable differences among the various salts.Between-subject variability ranged over four orders of magnitudeand reliability coefficients for repeated detection thresholdtests of CaCl₂ averaged r = 0.52. In an odor detection test,subjects could reliably discriminate 100 but not 1 mM CaCl₂and CaLa from water. The taste of suprathreshold concentrations(1–100 mM) of CaCl₂ and CaLa was considered unpleasant.At 1 mM, CaCl₂ solution was rated as 35% bitter, 32% sour, 29%sweet and 4% salty. At higher concentrations the sweet componentdiminished and the salty component increased, so that 100 mMCaCl₂ was rated as 44% bitter, 20% sour, 1% sweet and 35% salty.CaLa solutions were considered to be significantly less bitterand marginally more sour than equimolar CaCl₂ solutions. Thus,the taste of calcium varied with both the form and concentrationof salt tested, but included both sour and bitter components.Saltiness was identified only in high (     

Sour taste responses in mice lacking PKD channels

Background

The polycystic kidney disease-like ion channel PKD2L1 and its associated partner PKD1L3 are potential candidates for sour taste receptors. PKD2L1 is expressed in type III taste cells that respond to sour stimuli and genetic elimination of cells expressing PKD2L1 substantially reduces chorda tympani nerve responses to sour taste stimuli. However, the contribution of PKD2L1 and PKD1L3 to sour taste responses remains unclear.

Methodology/Principal Findings

We made mice lacking PKD2L1 and/or PKD1L3 gene and investigated whole nerve responses to taste stimuli in the chorda tympani or the glossopharyngeal nerve and taste responses in type III taste cells. In mice lacking PKD2L1 gene, chorda tympani nerve responses to sour, but not sweet, salty, bitter, and umami tastants were reduced by 25–45% compared with those in wild type mice. In contrast, chorda tympani nerve responses in PKD1L3 knock-out mice and glossopharyngeal nerve responses in single- and double-knock-out mice were similar to those in wild type mice. Sour taste responses of type III fungiform taste cells (GAD67-expressing taste cells) were also reduced by 25–45% by elimination of PKD2L1.

Conclusions/Significance

These findings suggest that PKD2L1 partly contributes to sour taste responses in mice and that receptors other than PKDs would be involved in sour detection.