Elucidation of the Amygdalin Pathway Reveals the Metabolic Basis of Bitter and Sweet Almonds (<i>Prunus dulcis</i>)

Thodberg, Sara; Cueto, Jorge Del; Mazzeo, Rosa; Pavan, Stefano; Lotti, Concetta; Dicenta, F.; Neilson, Elizabeth Heather Jakobsen; Møller, Birger Lindberg; Sánchez‐Pérez, Raquel

doi:10.1104/pp.18.00922

Cited by 77 publications

(77 citation statements)

References 83 publications

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“…DDBJ/EMBL/GenBank accession numbers for UGT94AB2, UGT94AA2, and UGT94AG1 are LC484012, LC484014, and LC484013, respectively. The regio-selectivity of GGTs used in the analysis was described in the following studies: Brugliera et al (1994), Kroon et al (1994), Frydman et al (2004 (2014,2016), Di et al (2015), Ohgami et al (2015), Casas et al (2016), and Thodberg et al (2018).…”

Section: Phylogenetic Analysismentioning

confidence: 99%

Glycoside‐specific glycosyltransferases catalyze regio‐selective sequential glucosylations for a sesame lignan, sesaminol triglucoside

et al. 2019

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Summary Sesame (Sesamum indicum) seeds contain a large number of lignans, phenylpropanoid‐related plant specialized metabolites. (+)‐Sesamin and (+)‐sesamolin are major hydrophobic lignans, whereas (+)‐sesaminol primarily accumulates as a water‐soluble sesaminol triglucoside (STG) with a sugar chain branched via β1→2 and β1→6‐O‐glucosidic linkages [i.e. (+)‐sesaminol 2‐O‐β‐d‐glucosyl‐(1→2)‐O‐β‐d‐glucoside‐(1→6)‐O‐β‐d‐glucoside]. We previously reported that the 2‐O‐glucosylation of (+)‐sesaminol aglycon and β1→6‐O‐glucosylation of (+)‐sesaminol 2‐O‐β‐d‐glucoside (SMG) are mediated by UDP‐sugar‐dependent glucosyltransferases (UGT), UGT71A9 and UGT94D1, respectively. Here we identified a distinct UGT, UGT94AG1, that specifically catalyzes the β1→2‐O‐glucosylation of SMG and (+)‐sesaminol 2‐O‐β‐d‐glucosyl‐(1→6)‐O‐β‐d‐glucoside [termed SDG(β1→6)]. UGT94AG1 was phylogenetically related to glycoside‐specific glycosyltransferases (GGTs) and co‐ordinately expressed with UGT71A9 and UGT94D1 in the seeds. The role of UGT94AG1 in STG biosynthesis was further confirmed by identification of a STG‐deficient sesame mutant that predominantly accumulates SDG(β1→6) due to a destructive insertion in the coding sequence of UGT94AG1. We also identified UGT94AA2 as an alternative UGT potentially involved in sugar–sugar β1→6‐O‐glucosylation, in addition to UGT94D1, during STG biosynthesis. Yeast two‐hybrid assays showed that UGT71A9, UGT94AG1, and UGT94AA2 were found to interact with a membrane‐associated P450 enzyme, CYP81Q1 (piperitol/sesamin synthase), suggesting that these UGTs are components of a membrane‐bound metabolon for STG biosynthesis. A comparison of kinetic parameters of these UGTs further suggested that the main β‐O‐glucosylation sequence of STG biosynthesis is β1→2‐O‐glucosylation of SMG by UGT94AG1 followed by UGT94AA2‐mediated β1→6‐O‐glucosylation. These findings together establish the complete biosynthetic pathway of STG and shed light on the evolvability of regio‐selectivity of sequential glucosylations catalyzed by GGTs.

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Section: Phylogenetic Analysismentioning

confidence: 99%

Glycoside‐specific glycosyltransferases catalyze regio‐selective sequential glucosylations for a sesame lignan, sesaminol triglucoside

et al. 2019

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“…Our results suggest that TEs could be responsible for some of the genomic changes at the origin of the agronomic traits that distinguish peach from almond, such as mesocarp development and bitterness of the kernel. For one of them, sweet vs. bitter kernel, essential for the domestication of the almond, we show here that the sweet almond phenotype correlates with TE insertions surrounding gene CYP71AN24, involved in the synthesis of one of the key enzymes of the amygdalin pathway (cytochrome P450), and that could be responsible for the lower expression of this gene in the seed tegument of sweet almonds (Thodberg et al 2018).…”

Section: Discussionmentioning

confidence: 78%

“…It has been recently shown that the sweet almond phenotype is due to the reduced expression of the genes encoding two cytochrome P450 enzymes catalyzing the first steps of the amygdalin biosynthesis in sweet almond varieties as compared with bitter almond varieties (Thodberg et al 2018). It has also been shown that this reduced expression is not related with differences in the gene sequence, which points to a difference in the regulation of the expression of those genes (Thodberg et al 2018). We have compared these two almond genes with their homologs in peach, sweet cherry and P. mume and found that they are highly conserved (not shown).…”

Section: Transposon-induced Variability In Peach and Almond Traitsmentioning

confidence: 99%

Transposons played a major role in the diversification between the closely related almond (Prunus dulcis) and peach (P. persica) genomes: Results from the almond genome sequence

Alioto

Alexiou

Bardil

et al. 2019

Preprint

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Combining both short and long-read sequencing, we have estimated the almond Prunus dulcis cv. Texas genome size in 235 Mbp and assembled 227.6 Mb of its sequence. The highly heterozygous compact genome of Texas comprises eight chromosomes, to which we have anchored over 91% of the assembly. We annotated 27,042 protein-coding genes and 6,800 non-coding transcripts. High levels of genetic variability were characterized after resequencing a collection of ten almond accessions. Phylogenomic comparison with the genomes of 16 other close and distant species allowed estimating that almond and peach diverged around 5.88 Mya. Comparison between peach and almond genomes confirmed the high synteny between these close relatives, but also revealed high numbers of presence-absence variants, many attributable to the movement of transposable elements (TEs). The number and distribution of TEs between peach and almond was similar, but the history of TE movement was distinct, with peach having a larger proportion of recent transpositions and almond preserving a higher level of polymorphism in the older TEs. When focusing on specific genes involved in key characters such as the bitter vs. sweet kernel taste and the formation of a fleshy mesocarp, we found that for one gene associated with the biosynthesis of amygdalin that confers the bitter kernel taste, several TEs were inserted in its vicinity only in sweet almond cultivars but not in bitter cultivars and Prunus bitter kernel relatives, including P. webbii, P. mume, and other species like peach and cherry. TE insertions likely to produce affects in the expression of six more genes involved in the formation of the fleshy mesocarp were also identified.Altogether, our results suggest a key role of TEs in the recent history and diversification of almond with respect to peach.3

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“…5). Interestingly, PdUGT94AF1 and PdUGT94AF2 derived from Prunus dulcis involved in the formation 1,6-β-D-glucosidic linkage of Prunasin [24] were clustered in group A but had a long genetic distance between them and SrUGTs of this group, implying that the SrUGTs in this group may have no related specificity. Due to the lack of other glycosyltransferases capable of forming 1,6-glucosidic bonds, this tree cannot predict the glycosyltransferases involved in the synthesis of steviol glycosides containing 1,6-glucosidic bonds (such as Reb L).…”

Section: Content Of Glucosides In Samplesmentioning

confidence: 99%

Characterizing glycosyltransferases by a combination of sequencing platforms applied to the leaf tissues of Stevia rebaudian

Zhang

Liu

Lyu

et al. 2020

Preprint

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Background: Stevia rebaudiana (Bertoni) is considered one of the most valuable plants because of the steviol glycosides (SGs) that can be extracted from its leaves. Glycosyltransferases (GTs), which can transfer sugar moieties from activated sugar donors onto saccharide and nonsaccharide acceptors, are widely distributed in the genome of S. rebaudiana and play important roles in the synthesis of steviol glycosides.Results: Six stevia genotypes with significantly different concentrations of SGs were obtained by induction through various mutagenic methods, and the contents of seven glycosides (stevioboside, Reb B, ST, Reb A, Reb F, Reb D and Reb M) in their leaves were considerably different. Then, NGS and single-molecule real-time (SMRT) sequencing were combined to analyse leaf tissue from these six different genotypes to generate a more complete and correct full-length transcriptome of S. rebaudiana. Two phylogenetic trees of glycosyltransferases (SrUGTs) were constructed by the neighbour-joining method and successfully predicted the functions of SrUGTs involved in SG biosynthesis. With further insight into glycosyltransferases (SrUGTs) involved in SG biosynthesis, the weighted gene co-expression network analysis (WGCNA) method was used to characterize the relationships between SrUGTs and SGs, and forty-four potential SrUGTs were finally obtained. Of these potential SrUGTs, twenty-seven have complete ORFs and have not been verified to date, and enzyme assays were subsequently performed, but none of them had activity towards SGs. In addition, SrUGT (SrUGT88B1-1) could utilize UDP-glucose as a sugar donor to glycosylate isoquercetin to form three products containing one, two, and three glucoses, respectively. Conclusion:Combined with the results obtained by previous studies and those of this work, we systematically characterized glycosyltransferases in S. rebaudiana and confirmed that four enzymes (SrUGT85C2, SrUGT74G1, SrUGT76G1 and SrUGT91D2) are primarily involved in the glycosylation of steviol glucosides. Moreover, the complete and correct full-length transcriptome obtained in this study will provide valuable support for further research investigating S. rebaudiana.(S. rebaudiana and S. phlebophylla) in this genus to produce steviol glycosides (SGs), compounds that appeal to people looking for more natural plant-based ingredients in their diet because of their natural-origin, plant-based and zero-calorie sustainable sweeteners [1,2]. Indeed, finding nonnutritive sweeteners to reduce sugar intake is one valuable path to solve some serious health problems at present, especially for those with obesity or diabetes. Therefore, making stevia a leaf crop with significant economic value and the food industry has a very positive outlook regarding the opportunities for SGs. Consequently, the value of the SG market is expected to exceed $1 billion USD by 2021 [3]. To date, more than thirty-five SGs have been isolated and identified from S. rebaudiana, including steviolbioside, rebaudioside A-Q (Reb A-Q), 1,2-stevioside (...

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Elucidation of the Amygdalin Pathway Reveals the Metabolic Basis of Bitter and Sweet Almonds (Prunus dulcis)

Cited by 77 publications

References 83 publications

Glycoside‐specific glycosyltransferases catalyze regio‐selective sequential glucosylations for a sesame lignan, sesaminol triglucoside

Glycoside‐specific glycosyltransferases catalyze regio‐selective sequential glucosylations for a sesame lignan, sesaminol triglucoside

Transposons played a major role in the diversification between the closely related almond (Prunus dulcis) and peach (P. persica) genomes: Results from the almond genome sequence

Characterizing glycosyltransferases by a combination of sequencing platforms applied to the leaf tissues of Stevia rebaudian

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