Enhancement of sucrose sweetness with soluble starch in humans.

The effect of soluble starch (acid-modified starch) on taste intensity was investigated in human subjects. Different concentrations of sucrose (Suc), six sweeteners, NaCl, quinine-HCl (QHCl) and citric acid (Cit) were dissolved in either distilled water (DW; standard) or starch solution (test solution). The solutions were presented to naive subjects and each subject was requested to taste and compare the sweetness intensity between the standard and test solutions based on a scale ranging from +3 (enhanced) to -3 (inhibited). A greater sweetness intensity occurred with Suc at different concentration (0.1-1.0 M) dissolved in soluble starch (0.125% to 4.0%) than with Suc in DW. Similarly, five other different products of soluble starch at 0.25 and 4.0% resulted in enhancement of sweetness for 0.3 and 1.0 M Suc. With the sole exception of the taste of 0.3 M Suc, sweet enhancement did not occur with 0.43 M fructose, 0.82 M glucose, 0.82 M sorbitol, 0.0037 M aspartame, 0.0042 M saccharin-Na or 0.016 M cyclamate. Neither the saltiness of NaCl (0.01-0.3 M), the bitterness of QHCl (0.00003-0.001 M) nor the sourness of Cit (0.0003-0.01 M) were affected by the soluble starch. These results suggest that the taste enhancing effects of soluble starch on Suc sweetness might depend not only on the taste transduction mechanism, but also on the molecular interaction between Suc and soluble starch.     

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.     

Time-dependent inhibition of sucrose sweetness with gymnemic acid: Mode of action

A time-dependent study of the sweet response of sucrose allows a Lineweaver-Burk type of plot (reciprocal of magnitude estimation rate versus reciprocal of sucrose concentration) to be obtained, from which considerable deviation is observed after inhibition of sweetness with gymnemic acid. The plots after inhibition do not appear to be analogous to any of the known forms of competitive, uncompetitive or non-competitive inhibition of enzyme kinetics. Rather a “mixed-type” of inhibition is suggested, combining the attributes of competitive and non-competitive inhibition.     

Strawberry odor, but not red color, enhances the sweetness of sucrose solutions

Several investigators have recently reported that odor and colorcan influence the sweetness of stimuli containing sucrose. Theseeffects were examined further by assessing the effect of redcoloring and strawberry odorant on the sweetness ratings ofaqueous solutions of sucrose. Two methods of olfactory stimulationwere used: (i) sip and spit, and (ii) swallowing the solutions.It was anticipated that swallowing the solutions would enhancethe olfactory effects by augmenting retronasal olfactory stimulation.The strawberry odor induced a small, but significant increasein sweetness for both the sip and spit and swallowing condition.There was a tendency for this effect to be more consistent andstable in the swallowing condition. Red coloring had no effecton sweetness.     

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.     

Mechanism of sucrose uptake by isolated rat hepatocytes

The transport of molecules by nonspecific endocytosis has been described in many cell types, but it has not been characterized in hepatocytes. Because of its central role in the clearance of solutes from portal blood, endocytosis might represent a significant mode of cellular transport. We investigated the mechanism of sucrose uptake in an isolated hepatocyte system. Liver cells were isolated by perfusion and collagenization of rat liver, followed by differential centrifugation. Hepatocytes were then incubated with 14C-sucrose and harvested by spinning through oil in microfuge tubes. Radioactivity was standardized against DNA content. We found that sucrose uptake is concentration-dependent from 5 microM to 100 mM and follows first-order kinetics. Washout studies indicate that exocytosis is responsible for the dynamic equilibrium reached. Arrhenius analysis of temperature dependence yields a linear plot (Ea = 14.2 Kcal/mol). In addition, sucrose uptake is independent of cellular ATP levels. We conclude that sucrose is transported by fluid-phase micropinocytosis in isolated hepatocytes and that this transport mechanism may be important in the uptake of diverse molecules into liver cells.     

Concentrations of NaCl and sucrose: equality in perceived taste intensity

Results from previous studies suggest that sucrose and NaClsolutions have an equal perceived taste intensity when the molarconcentration of sucrose is 1.5–1.75 times the molar concentrationof NaCl. However, according to other studies, sucrose and NaClsolutions taste equally strong when their molar concentrationsare about equal. This issue was further pursued using the methodof constant stimuli, where subjects matched the perceived tasteintensity of NaCl solutions to five sucrose references and viceversa. The results concur with previous findings that sucroseand NaCl solutions have equal perceived taste intensities whenthe molar concentration of sucrose is 1.5–1.75 times themolar concentration of NaCl.     

A moment-by-moment comparsion of sucrose and saccharin drinking by the rat

Comparisons were made between the ingestion patterns in ratsto a 0.2% sodium saccharin solution and to a 32% sucrose solutionin both short-term (30 min, one solution only) and long-term(23 h, solution versus water) tests. The resolution of measurementin the short- and long-term tests was 0.5 and 30 s respectively.Analysis programs for both procedures allowed for a quantificationof the ingestion patterns over time, showing details of thelick bursts in the short-term tests and ingestion bouts in the23-h tests. Although the quantities of sucrose and saccharinconsumed in the long-term tests were equal, the drinking patternsfor water, saccharin and sucrose were markedly different duringthe three testing periods, (i) There were fewer drinking boutsto the sucrose than to the saccharin or water, (ii) The averagebout of sucrose was much larger than the saccharin or waterbouts, (iii) The inter-bout intervals for sucrose were muchlonger than those for saccharin, (iv) Nearly half of the sucroseintake occurred during the ‘lights-on’ portion ofthe 23-h drinking period as compared to less than one-thirdfor saccharin or water, (v) Food intake when saccharin was presentwas equal to normal food intake when only water was available.However, in the presence of sucrose, the number and the sizeof feeding bouts decreased resulting in a 36% reduction in foodintake. Similar results were found in the short-term tests whencomparing sucrose and saccharin ingestion in that the quantitiesconsumed were not reliably different, but the ingestion patternswere, (i) The rats had many more bursts of licking saccharinthan sucrose, (ii) The saccharin bursts were much shorter thanthose for sucrose, (iii) Saccharin licking occurred off andon throughout the 30-min testing period while sucrose was consumedat a rapid rate at first and then terminated in 10–15min from the period onset. Inferences about the different tastesof saccharin and sucrose to the rat arc drawn from the detailedpattern analyses.     

Enhancement of frost tolerance in olive shoots in vitro by cold acclimation and sucrose increase in the culture medium

The evaluation of frost tolerance in olive shoots in vitro has been successfully accomplished. The behavior of in vitro shoots at freezing temperatures was comparable to that of intact plants. Cold acclimation was found to increase frost tolerance in cv. Moraiolo and the LT₅₀ was about 4 °C lower compared to nonacclimated shoots. Damage in acclimated shoots occurred at –15 °C, whereas control shoots were damaged at –10 °C. Olive shoots were unable to withstand freezing temperatures of –20 °C, even when acclimated. The effects of sucrose were also determined. 6% (w/v) sucrose in the medium conferred the highest frost tolerance in both acclimated and nonacclimated plants.     

Inhibition of sucrose phosphatase by sucrose

1. Partially purified sucrose phosphatase from immature stem tissue of sugarcane is inhibited by sucrose. The enzyme was also inhibited by maltose, melezitose and 6-kestose but not by eight other sugars, including glucose and fructose. 2. The relative effectiveness of sucrose, maltose and melezitose as inhibitors is different for sucrose phosphatase from different plants. 3. The inhibition of the sugar-cane enzyme by sucrose was shown to be partially competitive. The K(i) for sucrose is about 10mm. 4. Melezitose is also a partially competitive inhibitor of the enzyme but the inhibition by maltose is probably mixed. 5. The possibility that sucrose controls both the rate of accumulation of sucrose in stems of sugar-cane and sucrose synthesis in leaves by inhibiting sucrose phosphatase is discussed.     

Oral sucrose stimulation increases accumbens dopamine in the rat

Although taste can influence meal size and body weight, the neural substrate for these effects remains obscure. Dopamine, particularly in the nucleus accumbens, has been implicated in both natural and nonnatural rewards. To isolate the orosensory effects of taste from possible postingestive consequences, we investigated the quantitative relationship between sham feeding of sucrose and extracellular dopamine in the nucleus accumbens with microdialysis in rats. Sucrose intake linearly increased as a function of concentration (0.03 M, 18.07 +/- 2.41 ml; 0.1 M, 30.92 +/- 2.60 ml; 0.3 M, 43.28 +/- 2.88 ml). Sham feeding also stimulated accumbens dopamine overflow as a function of sucrose solution concentration (0.03 M, 120.76 +/- 2.6%; 0.1 M, 140.28 +/- 7.8%; 0.3 M, 146.27 +/- 5.05%). A second experiment used the same protocol but clamped the amount of sucrose ingested and revealed a similar, concentration-dependent dopamine activation in the nucleus accumbens. This is the first demonstration of a quantitative relationship between the concentration-dependent rewarding effect of orosensory stimulation by sucrose during eating and the overflow of dopamine in the nucleus accumbens. This finding provides new and strong support for accumbens dopamine in the rewarding effect of sucrose.     

Enhancement of maximal thermogenesis by reducing endogenous adenosine activity in the rat

Adenosine has been shown in vitro to be a potent antilipolytic agent and an inhibitor of insulin-stimulated glucose utilization in skeletal muscle. To test whether endogenously produced adenosine (e.g., from ATP hydrolysis) shares these deleterious effects on substrate mobilization and utilization and thus limits maximum thermogenesis in vivo, adenosine deaminase (converts adenosine to inosine) was given to rats 15 min before cold exposure. Significant (P less than 0.05) increases in thermogenesis were observed under both well-fed (100 units/kg ip) and food-rationed (200 units/kg ip) states. Significant (P less than 0.05) increases in thermogenesis and cold resistance were also observed after pretreatment with selective adenosine receptor antagonists [8-cyclopentyltheophylline (1 microgram/kg ip) greater than 1,3-dipropyl-8-p-sulfophenylxanthine (1.25 mg/kg ip) greater than aminophylline (18.7 mg/kg ip)], indicating an A1-receptor-mediated effect. These results indicate that endogenously released adenosine can indeed attenuate the thermogenic capacity in severe cold and that adenosine antagonists, especially those selective for A1-receptor, are useful in improving cold resistance under varying nutritional states.     

Structural investigation of the sweet-tasting proteins thaumatin and monellin by immunological studies

Rabbit antibodies were produced against thaumatin I, a sweet-tastingprotein from plant origin using the technique of double diffusionin agar. Cross-reactions were observed between these antibodiesand thaumatin I, monellin and chemically modified thaumatins.No cross-reaction was observed between the antibodies of thaumatinI and the not sweet-tasting iodinated monellin. This lack ofcross-reaction may be due to the fact that iodination splitsmonellin into its A and B chain, resulting in a disturbanceof the tertiary structure of the molecule. The appearance ofprecipitation lines from thaumatin I as well as from monellinin reaction with the antibodies of thaumatin in the immunodiffusionassay indicates that thaumatin and monellin are immunologicallyclosely related. An identical conformational antigenic determinantin both molecules is probably responsible for this relationship.It is tentatively concluded that the identical conformationaldeterminant coincides with the active site responsible for thesweet-taste sensation.     

Assignment of the disulphide bonds in the sweet-tasting protein thaumatin I

The disulphide linkages of the 16 half-cystine residues in the sweet-tasting protein thaumatin have been investigated by enzymatic hydrolysis of the intact molecule. The peptides obtained after proteolytic cleavage with trypsin and pepsin, and in one case with chymotrypsin have been purified by gel filtration, high-performance liquid chromatography and peptide mapping by paper high-voltage electrophoresis in one direction and paper chromatography in the second dimension. Disulphide bonds appeared to be formed by cysteine residues in positions 9-204, 56-66, 71-77, 121-193, 126-177, 134-149, 145-158 and 159-164. The labile disulphide bond responsible for the enzymatic properties of the sweet tasting protein thaumatin appeared to be between Cys-145 and Cys-158.     

Enhancement of renal medulla prostaglandin synthetase activity by dexamethasone treatment in the rat

We studied in rats the effect of dexamethasone (2.5 mg/kg per week) on the conversion of radiolabeled arachidonic acid to prostaglandins by renal medulla slices, microsomes, and homogenates. The steroid did not affect the rate of conversion of arachidonic acid to prostaglandins by renal medulla slices, but significantly increased the rate of conversion by both the microsomes and the 10,000 × g supernatatant of renal medulla homogenates. We conclude (a) that dexamethasone treatment increases the activity of renal medulla prostaglandin synthetase measured in broken cells preparations, and (b) that such a change in enzyme activity is not manifested by augmentation of prostaglandin synthesis in renal medulla slices incubated with exogenous arachidonic acid.     

Expression of synthetic thaumatin genes in yeast

Thaumatin is a plant protein that contains 8 disulfides and 207 amino acids in the mature form. The protein is of potential commercial interest since microgram quantities elicit an intense sweetness sensation. Two major variants of thaumatin have been identified in our laboratory by using sequence data obtained from thaumatin tryptic peptides. These differ by one amino acid at position 46 (asparagine or lysine), and both proteins differ from previously published sequences. We have synthesized DNA-coding sequences for three of these thaumatin variants using yeast preferred codons. The genes were inserted into an expression vector that contained a yeast 3-phosphoglycerate kinase promoter and terminator, and the vectors were transformed into yeast for expression of the recombinant protein. Upon lysis of the yeast cells, all thaumatin was localized in the insoluble cell fraction. Analysis of the sodium dodecyl sulfate solubilized yeast extracts by gel electrophoresis and Western blotting showed that thaumatin represented about 20% of the insoluble yeast protein. Although expressed at high levels, none of the thaumatins was biologically active (sweet). Preliminary protein folding experiments showed that two of three thaumatin variants could be folded to the sweet conformation.