Occurrence of Benzoic Acid Esters as Putative Catabolites of Prunasin in Senescent Leaves of <i>Prunus laurocerasus</i>

Sendker, Jandirk; Ellendorff, Therese; Hölzenbein, Aljoscha

doi:10.1021/acs.jnatprod.5b01090

Cited by 12 publications

(7 citation statements)

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“…In all studied cultivars, the peak of prunasin amide coincided with a decrease in prunasin levels, indicating turnover of prunasin into its amide. The conversion of prunasin to prunasin amide may occur non-enzymatically via the Radziszewski reaction in the presence of hydrogen peroxide (Sendker et al, 2016). Hydrogen peroxide is produced during flower development (Kuroda et al, 2002).…”

Section: Resultsmentioning

confidence: 99%

“… Proposed turnover pathways (1, 2, 3, and R) for prunasin without the release of hydrogen cyanide (after Pičmanová et al, 2015; Sendker et al, 2016). In pathway 1, prunasin is sequentially converted into its amide and/or acid and anitrile; moreover, β- D -glucose-1-benzoate may be formed from prunasin acid.…”

Section: Resultsmentioning

confidence: 99%

“…In senescent leaves of P. laurocerasus L., novel benzoic acid esters have recently been reported as formed from prunasin (Sendker et al, 2016). This inspired us to investigate the possible presence of benzoic acid derivatives in almond and sweet cherry flower buds.…”

Section: Resultsmentioning

confidence: 99%

“…A compound identified as β- D -glucose-1-benzoate was indeed found to be present in high amounts compared to prunasin in the flower buds of all studied almond cultivars as well as in the cherry cultivar ( Figures 5C , 6B ). β- D -Glucose-1-benzoate was suggested to be formed as a novel extension of the oxidative catabolism of prunasin (Sendker et al, 2016). The amount of accumulated β- D -glucose-1-benzoate is high compared to the prunasin level implying that β- D -glucose-1-benzoate might also be synthesized by a different route in the flower buds.…”

Section: Resultsmentioning

confidence: 99%

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Cyanogenic Glucosides and Derivatives in Almond and Sweet Cherry Flower Buds from Dormancy to Flowering

et al. 2017

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Almond and sweet cherry are two economically important species of the Prunus genus. They both produce the cyanogenic glucosides prunasin and amygdalin. As part of a two-component defense system, prunasin and amygdalin release toxic hydrogen cyanide upon cell disruption. In this study, we investigated the potential role within prunasin and amygdalin and some of its derivatives in endodormancy release of these two Prunus species. The content of prunasin and of endogenous prunasin turnover products in the course of flower development was examined in five almond cultivars – differing from very early to extra-late in flowering time – and in one sweet early cherry cultivar. In all cultivars, prunasin began to accumulate in the flower buds shortly after dormancy release and the levels dropped again just before flowering time. In almond and sweet cherry, the turnover of prunasin coincided with increased levels of prunasin amide whereas prunasin anitrile pentoside and β-D-glucose-1-benzoate were abundant in almond and cherry flower buds at certain developmental stages. These findings indicate a role for the turnover of cyanogenic glucosides in controlling flower development in Prunus species.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Cyanogenic Glucosides and Derivatives in Almond and Sweet Cherry Flower Buds from Dormancy to Flowering

et al. 2017

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“…The TM was prepared as a tea using freshly dried aerial parts as described by traditional healers [15]. The lyophilised powder was analysed using a modification of the methods described by Sendker et al [34]. The corresponding LC/MS chromatographic fingerprint shows the main components of the extract (Fig.…”

Section: Resultsmentioning

confidence: 99%

Antidiabetic Activities of an LC/MS Fingerprinted Aqueous Extract of Fagonia cretica L. in Preclinical Models

et al. 2017

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Diabetes mellitus is a chronic disease and one of the most important public health challenges facing mankind. is a medicinal plant used widely in the Punjab in Pakistan. A recent survey has demonstrated that traditional healers and herbalists frequently use this plant to treat diabetes. In the current study, the traditional medicine was prepared as a tea, and the profile of the main metabolites present in the traditional medicine was analysed via LC/MS/MS. The extract was shown to contain a number of phenolic glycosides including quercetin-3-O-rutinoside, kaempferol-3-O-rutinoside, kaempferol-3-O-glycoside, kaempferol-3(6'-malonylglucoside), isorhamnetin-3-O-rutinoside, and isorhamnetin 3-(6″-malonylglucoside) in addition to two unidentified sulphonated saponins. The traditional medicine inhibits-glucosidase with an IC of 4.62 µg/mL. The hypoglycaemic effect of the traditional medicine was evaluated in normoglycaemic and streptozotocin-treated diabetic rats, using glibenclamide as an internal control. The preparation (250 or 500 mg/kg body weight) was administered once a day for 21 consecutive days. The dose of 500 mg/kg was effective in the management of the disease, causing a 45 % decrease in the plasma glucose level at the end of the experimental period. Histological analysis of pancreatic sections confirmed that streptozotocin/nictotinamide treatment caused destruction of pancreatic islet cells, while pancreatic sections from the treatment groups showed that both the extract and glibenclamide partially prevented this deterioration. The mechanism of this protective effect is unclear. However, such a finding suggests that ingestion of the tea could confer additional benefits and should be investigated further.

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Cyanogenic Glycosides and Biogenetically Related Compounds in Higher Plants and Animals

Lechtenberg

2021

Encyclopedia of Life Sciences

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Cyanogenesis describes the ability of living organisms to liberate hydrogen cyanide from stored cyanogenic glycosides upon tissue damage by hydrolysis and/or decomposition. It has been described for more than 3000 species of higher plants. Chemically, cyanogenic glycosides are glycosides of α‐hydroxynitriles (cyanohydrins). Cyanogenic glycosides together with plant glycosidases and hydroxynitrile lyases form a preformed defence system. The structures are biogenetically related to only a few precursor amino acids. In the biosynthetic pathway, two multifunctional P450 enzymes and a glucosyltransferase act in a sequence. Biogenetically, glucosides of β‐ and γ‐hydroxynitriles are closely related. Cyanogenic glycosides and their related nitriles also may serve as storage forms for reduced nitrogen. A recycling pathway has been proposed to recover reduced nitrogen for primary metabolism. Many food plants are cyanogenic, and great efforts are made to optimise their detoxification. The presence of cyanogenic glycosides in the animal kingdom appears to be restricted to arthropods. Some insects, often aposematically coloured, synthesise cyanogenic glycosides de novo and/or sequester them from their host plants. Cyanogenic glycosides are secondary metabolites known from more than 3000 different higher plant species. Cyanogenic plants are able to liberate hydrogen cyanide from their cyanogenic glycosides upon disruption of plant tissue. Cyanogenic glycosides and their corresponding degrading enzymes are part of a preformed defence system. Thus, they can be regarded as phytoanticipins. Cyanogenic glycosides are glycosides of α‐hydroxynitriles, derived from five proteinogenic amino acids (Phe, Tyr, Val, Ile and Leu) and from the nonproteinogenic amino acid cyclopentenyl glycine. Acalyphin is apparently derived from nicotinic acid. A biogenetically related class consists of β‐ and γ‐hydroxynitrile glucosides, apparently derived from the aliphatic amino acids (Val, Ile and Leu). Up to now more than 100 different glycosylated α‐, β‐ and γ‐hydroxynitriles are known from higher plants and arthropods. Additional roles and functions of cyanogenic glycosides include storage of reduced nitrogen, transportation of nitrogen and the turnover of nitrogen into primary metabolism. The presence of cyanogenic glycosides in animals appears to be restricted to arthropods. Some insects are strongly associated with their cyanogenic host plants. They sequester the cyanogenic glycosides from these plants and additionally carry out de novo biosynthesis of these compounds. Convergent evolution in plants and insects has resulted in two identical biosynthesis pathways: two multifunctional P450 enzymes and a glucosyltransferase, acting sequentially.

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Occurrence of Benzoic Acid Esters as Putative Catabolites of Prunasin in Senescent Leaves of Prunus laurocerasus

Cited by 12 publications

References 32 publications

Cyanogenic Glucosides and Derivatives in Almond and Sweet Cherry Flower Buds from Dormancy to Flowering

Cyanogenic Glucosides and Derivatives in Almond and Sweet Cherry Flower Buds from Dormancy to Flowering

Antidiabetic Activities of an LC/MS Fingerprinted Aqueous Extract of Fagonia cretica L. in Preclinical Models

Cyanogenic Glycosides and Biogenetically Related Compounds in Higher Plants and Animals

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