The complete amino-acid sequence of the sweet protein thaumatin I.

The primary structure of the sweet-tasting protein thaumatin has been elucidated. The protein consists of a single polypeptide chain of 207 residues. The sequence of the N-terminal part of the chain was determined by sequenator analysis. As the protein contains only one methionine residue, it was possible to deduce the N-terminal sequence of the C-terminal cyanogen bromide fragment by automatic sequencing of the cyanogen-bromide-cleaved, succinylated protein. To arrive at the sequence of the whole protein tryptic and Staphylococcus protease peptides, together with chymotryptic peptides and a 2-(2-nitrophenylsulfenyl)-3-methyl-3'-bromoindolenine (BNPS-skatole) fragment were also sequenced. Comparing the amino acid sequence of thaumatin with that of the other sweet-tasting protein, monellin, we have located five sets of identical tripeptides. Since immunological cross-reactivity of thaumatin antibodies with monellin has recently been described, one or more of these tripeptides might be part of a common antibody recombination site and possibly be involved in the interaction with the sweet-taste receptor.     

Possible Active Site of the Sweet-tasting Protein Thaumatin

Epitopes on thaumatin and monellin were studied using the PEPSCAN-technology.The antibodies used were raised against thaumatin. Only antibodiesthat, in an ELISA, both recognized thaumatin and monellin wereused in the PEPSCAN-analyses. On thaumatin two major overlappingepitopes were identified. On monellin no epitopes could be identified.The identified epitope region on thaumatin shares structuralfeatures with various peptide and protein sweeteners. It containsan aspartame-like site which is formed by Asp21 and Phe80, tipsof the two extruding loops KGDAALDAGGR_19–29 and CKRFGRPP_77–84,which are spatially positioned next to each other. Furthermore,sub-sequences of the KGDAALDAGGR^19–29 loop are similarto peptide-sweeteners such as L-Asp-D-Ala- L-Ala-methyl esterand L-Asp-D-Ala-Gly-methyl ester. Since the aspartame-like Asp21-Phe80site and the peptide-sweetener-like sequences are also not presentin non-sweet thaumatin-like proteins it is postulated that theKGDAALDAGGR_19–29 and CKRFGRPP_77–84 loop containimportant sweet-taste determinants. This region has previouslynot been implicated as a sweet-taste determinant of thaumatin.Chem. Senses 20: 535–543, 1995.     

Qualitative psychophysical studies on the gustatory effects of the sweet tasting proteins thaumatin and monellin

The gustatory effects of the sweet tasting proteins thaumatinand monellin were studied aftei application to small areas onthe anterior third of the tongue or to single fungiform papillae.The sweet sensation caused by thaumatin and monellin developedmore slowly, but reached a higher intensity and had a longerduration than that given by sucrose. Also, the response evokedby these sweet tasting proteins was more pronounced at the lateraledges, whereas that evoked by sucrose was stronger at the tipof the tongue. The taste modifier, miraculin, had no noticeableeffect on the sweet taste elicited by thaumatin, monellin andsucrose. Gymnemic acid abolished the sweet taste of all threecompounds. Experiments with time intervals of less than one minute betweenstimuli showed strong crossadaptation between thaumatin andmonellin, between the two proteins and sucrose, and betweenthe two proteins and miraculin-induced sweet taste of citricacid. While the differences in response to the sweet tasting proteinsand sucrose may be taken as evidence in favor of the existenceof more than one kind of sweet receptor, the cross-adaptationnoted between the various substances tested, would seem to indicatethat, at some point, they engage a common neural mechanism. ¹On leave from Dept. of Prosthetics, Faculty of Odontology,Karolinska Institutet. Present address: Dept. of Histology,Karolinska Institutet, S-104 01 STOCKHOLM, Sweden.     

The taste responses in primates to the proteins thaumatin and monellin and their phylogenetic implications.

Electrophysiological and behavioural methods have been applied to 34 species of the primates and, for comparison, to the Madagascan hedgehog to determine their responses to the proteins thaumatin and monellin. These substances elicit an intensely sweet taste sensation in man. All Catarrhina prefer monellin to water. The responses of the Prosimii as well as those of the South American primates to monellin are different, some species show a reaction, other species are not sensitive. In the case of thaumatin neither the Prosimii--including Tupaia and Tarsius--nor the South American primates show any response to this protein. Only the Cercopithecidae, the Hylobatidae and the Pongidae respond to this protein like man and prefer this substance to water. This physiological aspect of taste constitutes a clear dichotomy within the order Primates. This capability to taste thaumatin probably developed as long as 38 million years ago.     

The cysteine-rich region of T1R3 determines responses to intensely sweet proteins

A wide variety of chemically diverse compounds taste sweet, including natural sugars such as glucose, fructose, sucrose, and sugar alcohols, small molecule artificial sweeteners such as saccharin and acesulfame K, and proteins such as monellin and thaumatin. Brazzein, like monellin and thaumatin, is a naturally occurring plant protein that humans, apes, and Old World monkeys perceive as tasting sweet but that is not perceived as sweet by other species including New World monkeys, mouse, and rat. It has been shown that heterologous expression of T1R2 plus T1R3 together yields a receptor responsive to many of the above-mentioned sweet tasting ligands. We have determined that the molecular basis for species-specific sensitivity to brazzein sweetness depends on a site within the cysteine-rich region of human T1R3. Other mutations in this region of T1R3 affected receptor activity toward monellin, and in some cases, overall efficacy to multiple sweet compounds, implicating this region as a previously unrecognized important determinant of sweet receptor function.     

Binding proteins for sweet compounds from gustatory papillae of the cow, pig and rat

The intensely sweet proteins thaumatin and monellin were covalently attached to affinity column supports. Lingual tissue extracts were incubated with the affinity columns which were then eluted with glycine-HCl pH 3.4, the sweet peptide aspartame, or gymnemic acid, which is a sweet taste modifier. SDS-PAGE analysis of eluates from the columns showed that 156 kDa and 47 kDa proteins were the main components from cow fungiform papillae which were specifically bound to thaumatin and monellin. These proteins could be displaced from the column with 0.5 mM aspartame or 0.5 mg/ml gymnemic acid. With circumvallate papillae small amounts of 47 kDa protein were also found. The 47 kDa protein was also the major component bound to a gymnemic acid affinity column and could be displaced from the column with 0.5 mg/ml gymnemic acid. Control experiments with other lingual tissue components indicated that these proteins are localised in the gustatory papillae. Similar protein patterns were also found in extracts of pig fungiform papillae and rat lingual preparations.     

Identification of novel sweet protein for nutritional applications

The prevalence of obesity and diabetes has increased exponentially in recent years around the globe, especially in India. Sweet proteins have the potential to substitute the sugars, by acting as natural, good and low calorie sweeteners. They also do not trigger a demand for insulin in diabetic patients unlike sucrose. In humans, the sweet taste perception is mainly due to taste-specific G protein-coupled heterodimeric receptors T1R2-T1R3. These receptors recognize diverse natural and synthetic sweeteners such as monelin, brazzein, thaumatin, curculin, mabinlin, miraculin and pentadin. Structural modeling of new sweetener proteins will be a great leap in further advancement of knowledge and their utility as sweeteners. We have explored the fingerprints of sweetness by studying the aminoacid composition and structure properties of the above proteins. The structural analysis of monellin revealed that the individual A or B chains of monellin are not contributing to its sweetness. However, the native conformation and ionic interaction between AspB7 of monellin with active site of T1R2-T1R3 receptor, along with hydrogen bonding stability of IleB6 and IleB8 are responsible for the sweet taste. Based on structural similarity search, we found a new hypothetical protein from Shewanella loihica, which has the presence of Asp(32) with adjacent isoleucine residues. Further, we examined the lead protein by two-step docking for the study of interaction of functionally conserved residues with receptors. The identified protein showed similar ionic and hydrophobic interactions with monelin. This gives a promising opportunity to explore this protein for potential health application in the low calorie sweetener industry viz., soft drinks, snacks, food, chocolate industries etc.     

Cloning of the thaumatin I cDNA and characterization of recombinant thaumatin I secreted by Pichia pastoris

Thaumatin is a sweet-tasting protein comprising a mixture of some variants. The major variants are thaumatins I and II. Although the amino acid sequence of thaumatin I was known and the nucleotide sequence of cDNA of thaumatin II was elucidated, the nucleotide sequence of thaumatin I has been controversial. We have cloned two thaumatin cDNAs from the fruit of Thaumatococcus daniellii Benth. One is the same nucleotide sequence as that of thaumatin II already reported, and the other is a novel nucleotide sequence. The amino acid sequence deduced from the novel cDNA was the same amino acid sequence as that of thaumatin I, the only exception being the residue at position 113 (Asp instead of Asn), indicating that the novel thaumatin cDNA is that for thaumatin I. This thaumatin I cDNA was transformed into Pichia pastoris X-33, and the recombinant thaumatin I expressed was purified and characterized. The threshold value of sweetness of the recombinant thaumatin I was the same as that of the plant thaumatin I, although several unexpected amino acid residues were attached to the N-terminal of the recombinant thaumatin I. These indicate that the N-terminal portion of thaumatin is not critical for the elicitation of sweetness.     

ON THE GUSTATORY EFFECTS OF MONELLIN AND THAUMATIN IN DOG, HAMSTER, PIG AND RABBIT

The electrical activity in the chorda tympani proper nerve ofdog, hamster, pig and rabbit was recorded during stimulationof the tongue with the sweet proteins, monellin and thaumatin,and stimuli representing the four taste qualities. It was observedthat these proteins, which to man taste extremely sweet andin the monkey elicit a significant neural response, caused,except for monellin in the dog, no significant change in theneural activity. On the basis of these results it is suggestedthat different types of ‘sweet’ receptor sites existin mammals.     

On the sense of taste in two Malagasy Primates (Microcebus murinus and Eulemur mongoz)

The relationship between phylogeny and taste is of growing interest.In this study we present recordings from the chorda tympaniproper (CT) nerve of two lemuriforme primates, the lesser mouselemur (Microcebus murinus) and the mongoose lemur (Eulemur mongoz),to an array of taste stimuli which included the sweeteners acesulfame-K,alitame, aspartame, D-glucose, dulcin, monellin, neohesperidindihydrochalcone (NHDHC), saccharin, sodium superaspartame, stevioside,sucralose (TGS), sucrose, suosan, thaumatin and xylitol, aswell as the non–sweet stimuli NaC1, citric acid, tanninand quinine hydrochloride. In M.murinus the effects of the tastemodifiers gymnemic acid and miraculin on the CT response wererecorded. Conditioned taste aversion (CTA) experiments in M.murinusand two-bottle preference (TBP) tests in E.mongoz were alsoconducted. We found that all of the above tastants except thaumatinelicited a CT response in both species. The CTA technique showedthat M.murinus generalized from sucrose to monellin but notto thaumatin. The intake of aspartame, ranging in concentrationfrom 0.1 to 30 mM was measured in E.mongoz with TBP tests. Atno concentration did we see a preference, but there was a significantrejection of 10 and 30 mM aspartame (P     

植物甜蛋白的研究进展

本文简要介绍了近年来在植物中发现的几种甜味蛋白质的分子结构及其化学性质。讨论了它们在结构上的相关性及可能的甜味机制,并对甜蛋白在食品工业及植物改良方面的应用进行了展望。     

Chorda tympani proper nerve responses to intra-arterial and surface stimulation of the tongue in rhesus monkey and rat

The effect of intra-arterial injection of the proteins monellin,thaumatin and miraculin on the activity of the chorda tympaniproper nerve were recorded in the rhesus monkey (Macaca mulatto)and the rat (Sprague–Dawley). The substances were injectedinto the blood stream to the lingual artery. It was found thatmonellin and thaumatin elicited a response only in the monkeyand not in the rat. Acetylated thaumatin, a tasteless substance,gave no increase of the nerve activity. Miraculin had no effectin either species. NaCl, sucrose and citric acid injected intra-arteriallygave a response in both species. It is concluded that the responsesto intra-arterial injections were caused by stimulation of thetaste buds and not nerve fibers. The results suggest there aretaste receptors also on the parts of the taste cells not facingthe oral cavity. The finding that there was no cross-adaptationbetween intra-arterial and oral application supports this conclusion.     

Recent developments in the characterization and biotechnological production of sweet-tasting proteins

 The state of the art regarding the six known sweet-tasting proteins (thaumatin, monellin, mabinlin, pentadin, brazzein and curculin) and the taste-modifying protein miraculin is reviewed. Their biochemical properties, molecular genetics and biotechnological production are assessed. All of these proteins have been isolated from plants that grow in tropical rainforests. They share no sequence homology or structural similarities. Nonetheless, one of them, thaumatin, shares extensive homology with certain non-sweet proteins found in other plants. The potential industrial applications of the sweet-tasting proteins are also discussed, placing special emphasis on the barriers that a recombinant product of these characteristics will have to overcome before it reaches the market. Received: 14 June 1999 / Received revision: 30 August 1999 / Accepted: 3 September 1999     

Cloning, expression and characterization of recombinant sweet-protein thaumatin II using the methylotrophic yeast Pichia pastoris

Thaumatin, an intensely sweet-tasting protein, was secreted by the methylotrophic yeast Pichia pastoris. The mature thaumatin II gene was directly cloned from Taq polymerase-amplified PCR products by using TA cloning methods and fused the pPIC9K expression vector that contains Saccharomyces cerevisiae prepro alpha-mating factor secretion signal. Several additional amino acid residues were introduced at both the N- and C-terminal ends by genetic modification to investigate the role of the terminal end region for elicitation of sweetness in the thaumatin molecule. The secondary and tertiary structures of purified recombinant thaumatin were almost identical to those of the plant thaumatin molecule. Recombinant thaumatin II elicited a sweet taste as native plant thaumatin II; its threshold value of sweetness to humans was around 50 nM, which is the same as that of plant thaumatin II. These results demonstrate that the functional expression of thaumatin II was attained by Pichia pastoris systems and that the N- and C-terminal regions of the thaumatin II molecule do not -play an important role in eliciting the sweet taste of thaumatin.     

Critical molecular regions for elicitation of the sweetness of the sweet-tasting protein, thaumatin I

Thaumatin is an intensely sweet-tasting protein. To identify the critical amino acid residue(s) responsible for elicitation of the sweetness of thaumatin, we prepared mutant thaumatin proteins, using Pichia pastoris, in which alanine residues were substituted for lysine or arginine residues, and the sweetness of each mutant protein was evaluated by sensory analysis in humans. Four lysine residues (K49, K67, K106 and K163) and three arginine residues (R76, R79 and R82) played significant roles in thaumatin sweetness. Of these residues, K67 and R82 were particularly important for eliciting the sweetness. We also prepared two further mutant thaumatin I proteins: one in which an arginine residue was substituted for a lysine residue, R82K, and one in which a lysine residue was substituted for an arginine residue, K67R. The threshold value for sweetness was higher for R82K than for thaumatin I, indicating that not only the positive charge but also the structure of the side chain of the arginine residue at position 82 influences the sweetness of thaumatin, whereas only the positive charge of the K67 side chain affects sweetness.     

Behavioral study in the gray mouse lemur (Microcebus murinus) using compounds considered sweet by humans

This study presents the results from two-bottle preference (TBP) tests performed on the gray mouse lemur (Microcebus murinus), a small Malagasy primate. We found that of 18 compounds considered sweet by humans, M. murinus preferred only six: D-tryptophan, dulcin, fructose, sucrose, SC45647, and xylitol. The animals neither preferred nor rejected acesulfame-K, alitame, aspartame, N-4-cyanophenyl-N'-cyanoguanidineacetate (CCGA), cyanosuosan, cyclamate, monellin, saccharin, suosan, super-aspartame, N-trifluoroacetyl-L-glutamyl-4-aminophenylcarbonitrile (TGC), and thaumatin. Together with previously recorded taste-nerve responses in M. murinus to acesulfame-K, alitame, aspartame, cyclamate, monellin, saccharin, and suosan [Hellekant et al., Chem Senses 18:307-320, 1993b], the current results suggest that these compounds either do not taste sweet to M. murinus or they have an aversive taste component. In this work we also relate these findings to phylogeny.     

Crystal structure of the sweet-tasting protein thaumatin II at 1.27Å

Thaumatin, an intensely sweet-tasting protein, elicits a sweet taste sensation at 50 nM. Here the X-ray crystallographic structure of one of its variants, thaumatin II, was determined at a resolution of 1.27 ?. Overall structure of thaumatin II is similar to thaumatin I, but a slight shift of the Cα atom of G96 in thaumatin II was observed. Furthermore, the side chain of residue 67 in thaumatin II is highly disordered. Since residue 67 is one of two residues critical to the sweetness of thaumatin, the present results suggested that the critical positive charges at positions 67 and 82 are disordered and the flexibility and fluctuation of these side chains would be suitable for interaction of thaumatin molecules with sweet receptors.     

An enzyme immunoassay and immunoblot analysis for curculin,a new type of taste-modifying protein; cross-reactivity of curculin and miraculin to both antibodies

We have developed an enzyme immunoassay method for curculin, a new type of taste-modifying protein. This method can accurately quantify 0.05–20 ng of curculin, a sensitivity about 3000-times that of the psychometric method. The content of curculin in the fruit of Curculigo latifolia increased gradually until 3 weeks after artificial pollination and dramatically at 4 weeks, to finally reach 1.3 mg per fruit. Immunoblot analysis indicated that antiserum to curculin was faintly reactive with miraculin, but not with thaumatin or monellin.     

Crystal structure of the sweet-tasting protein thaumatin II at 1.27 Å

Thaumatin, an intensely sweet-tasting protein, elicits a sweet taste sensation at 50 nM. Here the X-ray crystallographic structure of one of its variants, thaumatin II, was determined at a resolution of 1.27 Å. Overall structure of thaumatin II is similar to thaumatin I, but a slight shift of the Cα atom of G96 in thaumatin II was observed. Furthermore, the side chain of residue 67 in thaumatin II is highly disordered. Since residue 67 is one of two residues critical to the sweetness of thaumatin, the present results suggested that the critical positive charges at positions 67 and 82 are disordered and the flexibility and fluctuation of these side chains would be suitable for interaction of thaumatin molecules with sweet receptors.     

Characterization of osmotin : a thaumatin-like protein associated with osmotic adaptation in plant cells

Cultured tobacco (Nicotiana tabacum var Wisconsin 38) cells adapted to grow under osmotic stress synthesize and accumulate a 26 kilodalton protein (osmotin) which can constitute as much as 12% of total cellular protein. In cells adapted to NaCl, osmotin occurs in two forms: an aqueous soluble form (osmotin-I) and a detergent soluble form (osmotin II) in the approximate ratio of 2:3. Osmotin-I has been purified to electrophoretic homogeneity, and osmotin-II has been purified to 90% electrophoretic homogeneity. The N-terminal amino acid sequences of osmotins I and II are identical through position 22. Osmotin-II appears to be much more resistant to proteolysis than osmotin-I. However, it cross-reacts with polyclonal antibodies raised in rabbits against osmotin-I. Osmotin strongly resembles the sweet protein thaumatin in its molecular weight, amino acid composition, N-terminal sequence, and the presence of a signal peptide on the precursor protein. Thaumatin does not cross-react with antiosmotin. An osmotin solution could not be detected as sweet at a concentration at least 100 times that of thaumatin which could be detected as sweet. Immunocytochemical detection of osmotin revealed that osmotin is concentrated in dense inclusion bodies within the vacuole. Although antiosmotin did not label organelles, cell walls, or membranes, osmotin appeared sparsely distributed in the cytoplasm.