A novel conversion of sesamolin to sesaminol by acidic cation exchange resin

Huang, Jinian; Song, Gonghua; Zhang, Lixia; Sun, Qiang; Lü, Xin

doi:10.1002/ejlt.201100247

Cited by 15 publications

(12 citation statements)

References 26 publications

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“…We also observed that sesaminol accumulated during the first 40 min of incubation whereas the content of sesamol stayed relatively constant during the 100 min of hydrochloric acid treatment. Therefore, we agree with Huang et al [16] and consider the mechanism of the Villavecchia test for detecting sesame oil as follows. In brief, the unreliable sesamolin is firstly decomposed by concentrated hydrochloric acid into the primary products, sesamol and an intermediate oxonium ion, and afterward, the primary products undergo an electrophilic addition reaction of rearrangement for each other to generate sesaminol, and/or a portion of sesamol reacts with furfural to produce the chromogenic complex (Fig.…”

Section: Chromogenic Effect Of Sesame Oils Prepared By Different Roassupporting

confidence: 91%

“…Although both sesamolin and sesamol were contributive to the chromogenic reaction, sesamol was considered the real reactant of the Villavecchia reaction which was able to react with furfural to produce color complex. According to the results of Huang et al [16] and this study, we speculated that sesamolin was very unreliable with hydrochloric acid and would be decomposed into sesamol and an intermediate oxonium ion during the Villavecchia test, and subsequently the reactant sesamol could react with furfural to form the chromogenic complex and/or rearrange with the oxonium ion at the ortho position through the electrophilic addition to generate sesaminol. In our study, sesaminol could not be quantified directly due to the lack of a commercial standard.…”

Section: Discussionmentioning

confidence: 59%

“…However, sesamol was considerably depleted during oil deodorization, whereas sesaminol was maintained in the oil [14,15]. Recently, Huang et al [16] investigated the conversion of sesamolin to sesaminol by acidic cation exchange resin, and provided a rational mechanism of conversion in that sesamolin was decomposed under acidic conditions to produce primary products including sesamol and an oxonium intermediate, then the intermediate was able to react further with sesamol to produce sesaminol. In this work, we discovered that sesamol is a degradation product of sesamolin treated with concentrated HCl, but the amount of sesamol generation is not proportional to that of sesamolin degradation.…”

Section: Chromogenic Effect Of Sesame Oils Prepared By Different Roasmentioning

confidence: 99%

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Examination of the Modified Villavecchia Test for Detecting Sesame Oil

Lee

et al. 2013

J Americ Oil Chem Soc

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The official methods of the American Oil Chemists' Society recommend the modified Villavecchia test Cb 2-40 for detecting sesame oil in animal and vegetable fats and oils. The test is based on the reactivity of sesamol and sesamolin to furfural under acidic conditions. Although the contribution of sesamol and sesamolin to the reaction has been reported, little information is available on how the test performed with oils prepared from different sesame varieties or for effects of roasting conditions of seeds. The objective of this study was to clarify the contribution of various lignans to the Villavecchia test results. Chromogenic products of the Villavecchia test with sesame oil prepared from different varieties of sesame seeds gave different absorbance intensities at 520 nm, and the absorbance intensities were positively correlated with the content of sesamolin in sesame oil. Roasting conditions affected the content and concentration of lignans in sesame oil, and consequently the corresponding chromogenicity of the Villavecchia test. Roasting seeds at 230°C for 5 min caused a significant loss of sesamolin in oil, the level of sesamol increased, and the absorbance intensity at 520 nm of the corresponding Villavecchia testing product also increased. Roasting seeds at 280°C for 5 min caused loss of sesamin and the disappearance of sesamolin from the resultant oil, whereas the level of sesamol increased. These results provide guidance for determining the utility of the Villavecchia test for detecting sesame oil in mixtures of other foods.

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Section: Chromogenic Effect Of Sesame Oils Prepared By Different Roassupporting

confidence: 91%

Section: Discussionmentioning

confidence: 59%

Section: Chromogenic Effect Of Sesame Oils Prepared By Different Roasmentioning

confidence: 99%

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Examination of the Modified Villavecchia Test for Detecting Sesame Oil

Lee

et al. 2013

J Americ Oil Chem Soc

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“…The mechanism of these transformations has not been conclusively established. Based on their study on the conversion of sesamolin to sesaminol under anhydrous conditions catalyzed by sulfonic acid and on Fukuda’s original work [ 131 ], Huang and coworkers [ 132 ] suggested a two-step mechanism. According to their hypothesis, protonated sesamolin brakes down into sesamol and oxonium ion, both of which subsequently recombine into the products.…”

Section: Chemistry Of Sesame Lignansmentioning

confidence: 99%

Lignans of Sesame (Sesamum indicum L.): A Comprehensive Review

et al. 2021

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Major lignans of sesame sesamin and sesamolin are benzodioxol--substituted furofurans. Sesamol, sesaminol, its epimers, and episesamin are transformation products found in processed products. Synthetic routes to all lignans are known but only sesamol is synthesized industrially. Biosynthesis of furofuran lignans begins with the dimerization of coniferyl alcohol, followed by the formation of dioxoles, oxidation, and glycosylation. Most genes of the lignan pathway in sesame have been identified but the inheritance of lignan content is poorly understood. Health-promoting properties make lignans attractive components of functional food. Lignans enhance the efficiency of insecticides and possess antifeedant activity, but their biological function in plants remains hypothetical. In this work, extensive literature including historical texts is reviewed, controversial issues are critically examined, and errors perpetuated in literature are corrected. The following aspects are covered: chemical properties and transformations of lignans; analysis, purification, and total synthesis; occurrence in Seseamum indicum and related plants; biosynthesis and genetics; biological activities; health-promoting properties; and biological functions. Finally, the improvement of lignan content in sesame seeds by breeding and biotechnology and the potential of hairy roots for manufacturing lignans in vitro are outlined.

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“…It is important to note that STG displays only a negligible level of antioxidant activity in vitro [8], [9]. Moreover, the formation of bioactive sesaminol in sesame oils does not arise from the hydrolysis of STG; it is produced from sesamolin through acid catalysis during the bleaching step of the refining process of sesame oil production [10], [11]. STG occurs abundantly in sesame oil cake, and is produced as a by-product of sesame oil production in a large amount and can serve as an inexpensive source for the industrial production of sesaminol.…”

Section: Introductionmentioning

confidence: 99%

Purification, Gene Cloning, and Biochemical Characterization of a β-Glucosidase Capable of Hydrolyzing Sesaminol Triglucoside from Paenibacillus sp. KB0549

Nair¹,

Kuwahara

Nagase

et al. 2013

PLoS ONE

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The triglucoside of sesaminol, i.e., 2,6-O-di(β-D-glucopyranosyl)-β-D- glucopyranosylsesaminol (STG), occurs abundantly in sesame seeds and sesame oil cake and serves as an inexpensive source for the industrial production of sesaminol, an anti-oxidant that displays a number of bioactivities beneficial to human health. However, STG has been shown to be highly resistant to the action of β-glucosidases, in part due to its branched-chain glycon structure, and these circumstances hampered the efficient utilization of STG. We found that a strain (KB0549) of the genus Paenibacillus produced a novel enzyme capable of efficiently hydrolyzing STG. This enzyme, termed PSTG, was a tetrameric protein consisting of identical subunits with an approximate molecular mass of 80 kDa. The PSTG gene was cloned on the basis of the partial amino acid sequences of the purified enzyme. Sequence comparison showed that the enzyme belonged to the glycoside hydrolase family 3, with significant similarities to the Paenibacillus glucocerebrosidase (63% identity) and to Bgl3B of Thermotoga neapolitana (37% identity). The recombinant enzyme (rPSTG) was highly specific for β-glucosidic linkage, and k cat and k cat/K m values for the rPSTG-catalyzed hydrolysis of p-nitrophenyl-β-glucopyraniside at 37°C and pH 6.5 were 44 s−1 and 426 s−1 mM−1, respectively. The specificity analyses also revealed that the enzyme acted more efficiently on sophorose than on cellobiose and gentiobiose. Thus, rPSTG is the first example of a β-glucosidase with higher reactivity for β-1,2-glucosidic linkage than for β-1,4- and β-1,6-glucosidic linkages, as far as could be ascertained. This unique specificity is, at least in part, responsible for the enzyme’s ability to efficiently decompose STG.

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A novel conversion of sesamolin to sesaminol by acidic cation exchange resin

Cited by 15 publications

References 26 publications

Examination of the Modified Villavecchia Test for Detecting Sesame Oil

Examination of the Modified Villavecchia Test for Detecting Sesame Oil

Lignans of Sesame (Sesamum indicum L.): A Comprehensive Review

Purification, Gene Cloning, and Biochemical Characterization of a β-Glucosidase Capable of Hydrolyzing Sesaminol Triglucoside from Paenibacillus sp. KB0549

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