Sweetness determinant sites of brazzein, a small, heat-stable, sweet-tasting protein

Brazzein, originally isolated from the fruit of the African plant Pentadiplandra brazzeana Baillon, is the smallest, most heat-stable and pH-stable member of the set of proteins known to have intrinsic sweetness. These properties make brazzein an ideal system for investigating the chemical and structural requirements of a sweet-tasting protein. We have used the three-dimensional structure of the protein (J. E. Caldwell et al. (1998) Nat. Struct. Biol. 5, 427-431) as a guide in designing 15 synthetic genes in expression constructs aimed at delineating the sweetness determinants of brazzein. Protein was produced heterologously in Escherichia coli, isolated, and purified as described in the companion paper (Assadi-Porter, F. M., Aceti, D., Cheng, H., and Markley, J. L., this issue). Analysis by one-dimensional (1)H NMR spectroscopy indicated that all but one of these variants had folded properly under the conditions used. A taste panel compared the gustatory properties of solutions of these proteins to those of sucrose and brazzein isolated from fruit. Of the 14 mutations in the des-pGlu1-brazzein background, four exhibited almost no sweetness, six had significantly reduced sweetness, two had taste properties equivalent to des-pGlu1-brazzein (two times as sweet as the major form of brazzein isolated from fruit which contains pGlu1), and two were about twice as sweet as des-pGlu1-brazzein. Overall, the results suggest that two regions of the protein are critical for the sweetness of brazzein: a region that includes the N- and C-termini of the protein, which are located close to one another, and a region that includes the flexible loop around Arg43.     

Riboflavin-binding protein exhibits selective sweet suppression toward protein sweeteners

Riboflavin-binding protein (RBP) is well known as a riboflavin carrier protein in chicken egg and serum. A novel function of RBP was found as a sweet-suppressing protein. RBP, purified from hen egg white, suppressed the sweetness of protein sweeteners such as thaumatin, monellin, and lysozyme, whereas it did not suppress the sweetness of low molecular weight sweeteners such as sucrose, glycine, D-phenylalanine, saccharin, cyclamate, aspartame, and stevioside. Therefore, the sweet-suppressing activity of RBP was apparently selective to protein sweeteners. The sweet suppression by RBP was independent of binding of riboflavin with its molecule. Yolk RBP, with minor structural differences compared with egg white RBP, also elicited a weaker sweet suppression. However, other commercially available proteins including ovalbumin, ovomucoid, beta-lactogloblin, myoglobin, and albumin did not substantially alter the sweetness of protein sweeteners. Because a prerinse with RBP reduced the subsequent sweetness of protein sweeteners, whereas the enzymatic activity of lysozyme and the elution profile of lysozyme on gel permeation chromatography were not affected by RBP, it is suggested that the sweet suppression is caused by an interaction of RBP with a sweet taste receptor rather than with the protein sweeteners themselves. The selectivity in the sweet suppression by RBP is consistent with the existence of multiple interaction sites within a single sweet taste receptor.     

Crystal structure of Mabinlin II: a novel structural type of sweet proteins and the main structural basis for its sweetness

The crystal structure of a sweet protein Mabinlin II (Mab II) isolated from the mature seeds of Capparis masaikai Levl. grown in Southern China has been determined at 1.7A resolution by the SIRAS method. The Mab II 3D structure features in an "all alpha" fold mode consisting of A- and B-chains crosslinked by four disulfide bridges, which is distinct from all known sweet protein structures. The Mabinlin II molecule shows an amphiphilic surface, a cationic face (Face A) and a neutral face (Face B). A unique structural motif consisting of B54-B64 was found in Face B, which adopts a special sequence, NL-P-NI-C-NI-P-NI, featuring four [Asn-Leu/Ile] units connected by three conformational-constrained residues, thus is called the [NL/I] tetralet motif. The experiments for testing the possible interactions of separated A-chain and B-chain and the native Mabinlin II to the sweet-taste receptor were performed through the calcium imaging experiments with the HEK293E cells coexpressed hT1R2/T1R3. The result shows that hT1R2/T1R3 responds to both the integrated Mabinlin II and the individual B-chain in the same scale, but not to A-chain. The sweetness evaluation further identified that the separated B-chain can elicit the sweetness alone, but A-chain does not. All data in combination revealed that the sweet protein Mabinlin II can interact with the sweet-taste receptor hT1R2/T1R3 to elicit its sweet taste, and the B-chain with a unique [NL/I] tetralet motif is the essential structural element for the interaction with sweet-taste receptor to elicit the sweetness, while the A-chain may play a role in gaining a long aftertaste for the integrate Mabinlin II. The findings reported in this paper will be advantage for understanding the diversity of sweet proteins and engineering research for development of a unique sweetener for the food and agriculture based on the Mabinlin II structure as a native model.     

Reduced sweetness of a monellin (MNEI) mutant results from increased protein flexibility and disruption of a distant poly-(L-proline) II helix

Monellin is a highly potent sweet-tasting protein but relatively little is known about how it interacts with the sweet taste receptor. We determined X-ray crystal structures of 3 single-chain monellin (MNEI) proteins with alterations at 2 core residues (G16A, V37A, and G16A/V37A) that induce 2- to 10-fold reductions in sweetness relative to the wild-type protein. Surprisingly, no changes were observed in the global protein fold or the positions of surface amino acids important for MNEI sweetness that could explain these differences in protein activity. Differential scanning calorimetry showed that while the thermal stability of each mutant MNEI was reduced, the least sweet mutant, G16A-MNEI, was not the least stable protein. In contrast, solution spectroscopic measurements revealed that changes in protein flexibility and the C-terminal structure correlate directly with protein activity. G16A mutation-induced disorder in the protein core is propagated via changes to hydrophobic interactions that disrupt the formation and/or position of a critical C-terminal poly-(L-proline) II helix. These findings suggest that MNEI interaction with the sweet taste receptor is highly sensitive to the relative positions of key residues across its protein surface and that loss of sweetness in G16A-MNEI may result from an increased entropic cost of binding.     

Molecular mechanisms of the action of miraculin,a taste-modifying protein

Miraculin (MCL) is a homodimeric protein isolated from the fruits of Richadella dulcifica, a shrub native to West Africa. Although it is flat in taste at neutral pH, MCL has taste-modifying activity in which sour stimuli produce a sweet perception. Once MCL enters the mouth, strong sweetness can be detected for more than 1 h each time we taste a sour solution. While the human sweet taste receptor (hT1R2–hT1R3) has been identified, the molecular mechanisms underlying the taste-modifying activity of MCL remain unclear. Recently, experimental evidence has been published demonstrating the successful quantitative evaluation of the acid-induced sweetness of MCL using a cell-based assay system. The results strongly suggested that MCL binds hT1R2–hT1R3 as an antagonist at neutral pH and functionally changes into an agonist at acidic pH. Since sweet-tasting proteins may be used as low-calorie sweeteners because they contain almost no calories, it is expected that MCL will be used in the near future as a new low-calorie sweetener or to modify the taste of sour fruits.     

Hypothesis/review: The structural basis of sweetness perception of sweet-tasting plant proteins can be deduced from sequence analysis

Human perception of sweetness, behind the felt pleasure, is thought to play a role as an indicator of energy density of foods. For humans, only a small number of plant proteins taste sweet. As non-caloric sweeteners, these plant proteins have attracted attention as candidates for the control of obesity, oral health and diabetic management. Significant advances have been made in the characterization of the sweet-tasting plant proteins, as well as their binding interactions with the appropriate receptors. The elucidation of sweet-taste receptor gene sequences represents an important step towards the understanding of sweet taste perception. However, many questions on the molecular basis of sweet-taste elicitation by plant proteins remain unanswered. In particular, why homologues of these proteins do not elicit similar responses? This question is discussed in this report, on the basis of available sequences and structures of sweet-tasting proteins, as well as of sweetness-sensing receptors. A simple procedure based on sequence comparisons between sweet-tasting protein and its homologous counterparts was proposed to identify critical residues for sweetness elicitation. The open question on the physiological function of sweet-tasting plant proteins is also considered. In particular, this review leads us to suggest that sweet-tasting proteins may interact with taste receptor in a serendipity manner.     

Detection of sugar-binding sites in the fibrillar and the granular components of the nucleolus: An experimental study in cultured mammalian cells

The intranucleolar distribution of sugar-binding sites (i.e., lectin-like molecules) was analyzed in segregated nucleoli of actinomycin D-treated HeLa cells. The detection of sugar-binding sites was performed by incubation either of permeabilized nuclei in the presence of fluorescein-labeled neoglycoproteins or of ultrathin sections cut through in situ-fixed nuclei in the presence of gold-labeled neoglycoproteins. In the former case, the fluorescent nucleolar components were identified by comparison with the nucleolar components of similarly treated cells observed in electron microscopy. For the first time, this study reveals the presence of sugar-binding sites in both the fibrillar and the granular components of the nucleolus. In view of the data already reported on the biochemical composition of the nucleolus, some of our results led us to conclude that the nucleolar sugar-binding sites are lectin-like proteins. These proteins could be associated with preribosomes since the nucleolus is the site of both synthesis and stockage of ribosomal precursors. Some results from this study, however, show that the possibility of a relationship between some lectins and a structural component cannot be excluded.     

Sweet taste receptor gene variation and aspartame taste in primates and other species

Aspartame is a sweetener added to foods and beverages as a low-calorie sugar replacement. Unlike sugars, which are apparently perceived as sweet and desirable by a range of mammals, the ability to taste aspartame varies, with humans, apes, and Old World monkeys perceiving aspartame as sweet but not other primate species. To investigate whether the ability to perceive the sweetness of aspartame correlates with variations in the DNA sequence of the genes encoding sweet taste receptor proteins, T1R2 and T1R3, we sequenced these genes in 9 aspartame taster and nontaster primate species. We then compared these sequences with sequences of their orthologs in 4 other nontasters species. We identified 9 variant sites in the gene encoding T1R2 and 32 variant sites in the gene encoding T1R3 that distinguish aspartame tasters and nontasters. Molecular docking of aspartame to computer-generated models of the T1R2 + T1R3 receptor dimer suggests that species variation at a secondary, allosteric binding site in the T1R2 protein is the most likely origin of differences in perception of the sweetness of aspartame. These results identified a previously unknown site of aspartame interaction with the sweet receptor and suggest that the ability to taste aspartame might have developed during evolution to exploit a specialized food niche.     

Synaptophysin as a probable component of neurotransmission occurring in taste receptor cells

Taste signal is received in taste buds and transmitted via sensory afferent nerves to the brainstem. Although a signaling pathway involving phospholipase C-β2 has been shown to transduce taste signals of bitterness, sweetness and umami in taste receptor cells (Type II cells), these taste receptor cells appear to be different from the presynaptic cells (Type III cells) containing afferent synapses associated with nerve processes. To elucidate the neurotransmission system in the taste receptor cells expressing phospholipase C-β2, we searched for candidate molecules involved in the neurotransmission, and identified synaptophysin. Synaptophysin was expressed in the taste receptor cells expressing phospholipase C-β2, as well as in the presynaptic cells harboring synaptic structures with taste nerves and containing serotonin. Synaptophysin-immunoreactive signals were not limited to gustducin-positive bitter taste receptor cells, and sweet/umami taste receptor cells were indicated to also express synaptophysin. Expression of synaptophysin was already initiated 6 days after cell division, almost in synchrony with the initiation of phospholipase C-β2 expression. Synaptophysin-containing cells co-expressed vesicular-associated membrane protein 2, a v-SNARE molecule which is important for exocytosis. In addition, majority of the synaptophysin-expressing cells also expressed cholecystokinin, a neuropeptide expressed in taste buds. These results suggest that the taste receptor cells have a neurotransmission system involving synaptophysin, which occurs alternatively or additionally to a recently shown hemichannel system.     

Critical regions for the sweetness of brazzein

Brazzein is a small, heat-stable, intensely sweet protein consisting of 54 amino acid residues. Based on the wild-type brazzein, 25 brazzein mutants have been produced to identify critical regions important for sweetness. To assess their sweetness, psychophysical experiments were carried out with 14 human subjects. First, the results suggest that residues 29-33 and 39-43, plus residue 36 between these stretches, as well as the C-terminus are involved in the sweetness of brazzein. Second, charge plays an important role in the interaction between brazzein and the sweet taste receptor.     

Expression of Genes Encoding Multi-Transmembrane Proteins in Specific Primate Taste Cell Populations

Background

Using fungiform (FG) and circumvallate (CV) taste buds isolated by laser capture microdissection and analyzed using gene arrays, we previously constructed a comprehensive database of gene expression in primates, which revealed over 2,300 taste bud-associated genes. Bioinformatics analyses identified hundreds of genes predicted to encode multi-transmembrane domain proteins with no previous association with taste function. A first step in elucidating the roles these gene products play in gustation is to identify the specific taste cell types in which they are expressed.

Methodology/Principal Findings

Using double label in situ hybridization analyses, we identified seven new genes expressed in specific taste cell types, including sweet, bitter, and umami cells (TRPM5-positive), sour cells (PKD2L1-positive), as well as other taste cell populations. Transmembrane protein 44 (TMEM44), a protein with seven predicted transmembrane domains with no homology to GPCRs, is expressed in a TRPM5-negative and PKD2L1-negative population that is enriched in the bottom portion of taste buds and may represent developmentally immature taste cells. Calcium homeostasis modulator 1 (CALHM1), a component of a novel calcium channel, along with family members CALHM2 and CALHM3; multiple C2 domains; transmembrane 1 (MCTP1), a calcium-binding transmembrane protein; and anoctamin 7 (ANO7), a member of the recently identified calcium-gated chloride channel family, are all expressed in TRPM5 cells. These proteins may modulate and effect calcium signalling stemming from sweet, bitter, and umami receptor activation. Synaptic vesicle glycoprotein 2B (SV2B), a regulator of synaptic vesicle exocytosis, is expressed in PKD2L1 cells, suggesting that this taste cell population transmits tastant information to gustatory afferent nerve fibers via exocytic neurotransmitter release.

Conclusions/Significance

Identification of genes encoding multi-transmembrane domain proteins expressed in primate taste buds provides new insights into the processes of taste cell development, signal transduction, and information coding. Discrete taste cell populations exhibit highly specific gene expression patterns, supporting a model whereby each mature taste receptor cell is responsible for sensing, transmitting, and coding a specific taste quality.     

Detection of sugar-binding proteins in membrane-depleted nuclei

Nuclear sugar-binding proteins were detected in membrane-depleted nuclei isolated from hamster BHK cells and mouse L 1210 leukemia cells by means of fluorescein-labelled neoglycoproteins. In fluorescence microscopy, the fluorescence was seen throughout the nucleus but was generally brighter over the nucleoli than over the rest of the nucleus. Flow cytofluorometry analysis demonstrated the presence of nuclear sugar-binding proteins for synthetic glycoproteins associated with different sugar residues. Among the nine neoglycoproteins used, four neoglycoproteins (namely alpha-rhamnosylated, alpha-glucosylated, N-acetyl-beta-glucosaminylated and alpha-mannosylated-6P-serum albumin) strongly labelled nuclei. Various controls strongly argue for the specificity of the nuclear labelling. The possibility that some of the sugar-binding proteins might correspond to endogenous nuclear lectins is considered.     

Identification and modulation of the key amino acid residue responsible for the pH sensitivity of neoculin, a taste-modifying protein

Neoculin occurring in the tropical fruit of Curculigo latifolia is currently the only protein that possesses both a sweet taste and a taste-modifying activity of converting sourness into sweetness. Structurally, this protein is a heterodimer consisting of a neoculin acidic subunit (NAS) and a neoculin basic subunit (NBS). Recently, we found that a neoculin variant in which all five histidine residues are replaced with alanine elicits intense sweetness at both neutral and acidic pH but has no taste-modifying activity. To identify the critical histidine residue(s) responsible for this activity, we produced a series of His-to-Ala neoculin variants and evaluated their sweetness levels using cell-based calcium imaging and a human sensory test. Our results suggest that NBS His11 functions as a primary pH sensor for neoculin to elicit taste modification. Neoculin variants with substitutions other than His-to-Ala were further analyzed to clarify the role of the NBS position 11 in the taste-modifying activity. We found that the aromatic character of the amino acid side chain is necessary to elicit the pH-dependent sweetness. Interestingly, since the His-to-Tyr variant is a novel taste-modifying protein with alternative pH sensitivity, the position 11 in NBS can be critical to modulate the pH-dependent activity of neoculin. These findings are important for understanding the pH-sensitive functional changes in proteinaceous ligands in general and the interaction of taste receptor-taste substance in particular.     

19F NMR studies of the D-galactose chemosensory receptor. 1. Sugar binding yields a global structural change.

The Escherichia coli D-galactose and D-glucose receptor is an aqueous sugar-binding protein and the first component in the distinct chemosensory and transport pathways for these sugars. Activation of the receptor occurs when the sugar binds and induces a conformational change, which in turn enables docking to specific membrane proteins. Only the structure of the activated receptor containing bound D-glucose is known. To investigate the sugar-induced structural change, we have used 19F NMR to probe 12 sites widely distributed in the receptor molecule. Five sites are tryptophan positions probed by incorporation of 5-fluorotryptophan; the resulting 19F NMR resonances were assigned by site-directed mutagenesis. The other seven sites are phenylalanine positions probed by incorporation of 3-fluorophenylalanine. Sugar binding to the substrate binding cleft was observed to trigger a global structural change detected via 19F NMR frequency shifts at 10 of the 12 labeled sites. Two of the altered sites lie in the substrate binding cleft in van der Waals contact with the bound sugar molecule. The other eight altered sites, specifically two tryptophans and six phenylalanines distributed equally between the two receptor domains, are distant from the cleft and therefore experience allosteric structural changes upon sugar binding. The results are consistent with a model in which multiple secondary structural elements, known to extend between the substrate cleft and the protein surface, undergo shifts in their average positions upon sugar binding to the cleft. Such structural coupling provides a mechanism by which sugar binding to the substrate cleft can cause structural changes at one or more docking sites on the receptor surface.     

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.     

The effect of the sweetness inhibitor 2(-4-methoxyphenoxy)propanoic acid (sodium salt) (Na-PMP) on the taste of bitter-sweet stimuli

The effect of the sweetness inhibitor 2(-4-niethoxyphenoxy)propanoicacid (sodium gait) (Na-PMP) on the taste and temporal propertiesof a range of bitter-sweet stimuli was determined using a trainedsensory panel. Na-PMP was found to be an effective inhibitorof the sweetness response of all stimuli tested, reducing bothsweetness intensity and persistence. The inhibitor was foundto be specific to sweet taste, no reduction in bitterness intensityor persistence was observed at the concentrations of Na-PMPemployed in this study. The results therefore do not supportthe claim of Fuller and Kurtz (1991), that Na-PMP is a potentbitterness inhibitor, but rather support the existence of twodistinct receptor sites/loci in sweet and bitter chemoreception.     

Taste-modifying sweet protein, neoculin, is received at human T1R3 amino terminal domain

This study examines taste reception of neoculin, a Curculigo latifolia sweet protein with taste-modifying activity which converts sourness to sweetness. Neoculin tastes sweet to humans, but not to mice, and is received by the human sweet taste receptor hT1R2-hT1R3. In the present study with calcium imaging analysis of HEK cells expressing human and mouse T1Rs, we demonstrated that hT1R3 is required for the reception of neoculin. Further experiments using human/mouse chimeric T1R3s revealed that the extracellular amino terminal domain (ATD) of hT1R3 is essential for the reception of neoculin. Although T1R2-T1R3 is known to have multiple potential ligand-binding sites to receive a wide variety of sweeteners, the present study is apparently the first to identify the ATD of hT1R3 as a new sweetener-binding region.     

PERCEPTION OF TASTE MIXTURES BY EXPERIENCED AND NOVICE ASSESSORS1

The total intensity, sweetness, and acidity of sucrose/citric acid mixtures were judged by two types of taste panel: experienced assessors, most of whom had had many years of experience in sensory evaluation; and novice assessors, none of whom had previously taken part in a taste experiment. In other respects the experimental conditions remained almost constant. There was good correspondence between the two panels, particularly for judgments of total intensity, indicating that novice and experienced assessors evaluate taste mixtures in the same way. However, there was also an indication that experience on sensory panels may attenuate taste suppression, the suppression of acidity by sweetness being less pronounced for the experienced panel than for the novice panel. The implications for mixture perception are noted.