Glutathione transferases catalyze recycling of auto‐toxic cyanogenic glucosides in sorghum

Bjarnholt, Nanna; Neilson, Elizabeth Heather Jakobsen; Crocoll, Christoph; Jørgensen, Kirsten; Motawia, M. S.; Olsen, Carl Erik; Dixon, David P.; Edwards, Robert; Møller, Birger Lindberg

doi:10.1111/tpj.13923

Cited by 58 publications

(67 citation statements)

References 79 publications

(153 reference statements)

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“…However, phenylacylation of flavonoids has been reported in species of other families, albeit at a different structural position, for example in Scots pine (Jungblut et al, 1995), and indeed, periodically although relatively uncommonly occurs across the various families of the green lineage (Tohge et al, 2018). Similar advances recently have been made with regard to nitrogen containing compounds such as glucosinolates (Leong and Last, 2017), terpenes (Aharoni et al, 2003;Umehara et al, 2008;Chen et al, 2011), and fatty acid derivatives (Kachroo et al, 2003) in Arabidopsis, as well as compounds such as triterpene saponins (Achnine et al, 2005;Thimmappa et al, 2014), cyanogenic glucosides (Bjarnholt et al, 2018;Sun et al, 2018), acyl sugars (Leong and Last, 2017), and SGAs (Itkin et al, 2013;Schwahn et al, 2014) in other species.…”

Section: Number and Diversity Of Plant Metabolite Modificationsmentioning

confidence: 84%

The Structure and Function of Major Plant Metabolite Modifications

et al. 2019

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Plants produce a myriad of structurally and functionally diverse metabolites that play many different roles in plant growth and development and in plant response to continually changing environmental conditions as well as abiotic and biotic stresses. This metabolic diversity is, to a large extent, due to chemical modification of the basic skeletons of metabolites. Here, we review the major known plant metabolite modifications and summarize the progress that has been achieved and the challenges we are facing in the field. We focus on discussing both technical and functional aspects in studying the influences that various modifications have on biosynthesis, degradation, transport, and storage of metabolites, as well as their bioactivity and toxicity. Finally, we discuss some emerging insights into the evolution of metabolic pathways and metabolite functionality.

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Section: Number and Diversity Of Plant Metabolite Modificationsmentioning

confidence: 84%

The Structure and Function of Major Plant Metabolite Modifications

et al. 2019

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“…This could possibly supplement the activity of PdUGT94AF1 and PdUGT94AF2 with respect to amygdalin formation in specific cell types at some stage of cotyledon ontogeny. Alternatively, it could serve to trigger the initiation of endogenous recycling processes of prunasin (Pičmanová et al, 2015;Bjarnholt et al, 2018) or prunasin hydrolysis.…”

Section: Characterization Of Three Novel Ugt94smentioning

confidence: 99%

“…The genes encoding the enzymes required for the biosynthesis of prunasin and amygdalin are present in the genomes of both sweet and bitter almonds (Sánchez-Pérez et al, 2008). The key to unraveling the molecular basis for the sweet kernel trait, therefore, may be linked to a lack of expression of the biosynthetic genes or the complete endogenous remobilization of the amygdalin as a source of sugar and reduced nitrogen during seed development (Pičmanová et al, 2015;Bjarnholt et al, 2018). The expression analyses of the biosynthetic genes presented here documents that it is the lack of expression of PdCYP79D16 in the sweet genotype, echoed by the strongly reduced expression of PdCYP71AN24, that results in the sweet kernel trait (Fig.…”

Section: Bitterness In Almond Is Regulated At the Cyp Expression Levelmentioning

confidence: 99%

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

et al. 2018

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Almond (Prunus dulcis) is the principal Prunus species in which the consumed and thus commercially important part of the fruit is the kernel. As a result of continued selection, the vast majority of almonds have a nonbitter kernel. However, in the field, there are trees carrying bitter kernels, which are toxic to humans and, consequently, need to be removed. The toxicity of bitter almonds is caused by the accumulation of the cyanogenic diglucoside amygdalin, which releases toxic hydrogen cyanide upon hydrolysis. In this study, we identified and characterized the enzymes involved in the amygdalin biosynthetic pathway: PdCYP79D16 and PdCYP71AN24 as the cytochrome P450 (CYP) enzymes catalyzing phenylalanine-to-mandelonitrile conversion, PdUGT94AF3 as an additional monoglucosyl transferase (UGT) catalyzing prunasin formation, and PdUGT94AF1 and PdUGT94AF2 as the two enzymes catalyzing amygdalin formation from prunasin. This was accomplished by constructing a sequence database containing UGTs known, or predicted, to catalyze a β(1→6)-O-glycosylation reaction and a Basic Local Alignment Search Tool search of the draft version of the almond genome versus these sequences. Functional characterization of candidate genes was achieved by transient expression in Nicotiana benthamiana. Reverse transcription quantitative polymerase chain reaction demonstrated that the expression of PdCYP79D16 and PdCYP71AN24 was not detectable or only reached minute levels in the sweet almond genotype during fruit development, while it was high and consistent in the bitter genotype. Therefore, the basis for the sweet kernel phenotype is a lack of expression of the genes encoding the two CYPs catalyzing the first steps in amygdalin biosynthesis.

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“…Afterward, nitrilase complexes ( Sb NIT4B2/A or Sb NIT4B1/A) produce ammonia (NH 3 ) and L-aspartic acid, and/or L-asparagine from β -cyanoalanine [ 15 ]. The second is a non-toxic catabolic recycling pathway in which unknown enzyme which could be glutathione S-transferase (GST) or BGD catalyze the conversion of dhurrin to p -hydroxyphenylacetonitrile (pHPAN) and glutathione (GSH) is needed to detach a glucose from dhurrin [ 15 , 16 , 17 ]. The glutathionylated-pHPAN (GS-pHPAN) conjugate is converted to pHPAN by GST-like enzymes (GSTL1 or GSTL2) and GSHs [ 17 ].…”

Section: Introductionmentioning

confidence: 99%

Prediction of Dhurrin Metabolism by Transcriptome and Metabolome Analyses in Sorghum

Choi

Chung

Lee

et al. 2020

Plants

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Sorghum (Sorghum bicolor (L.)) Moench is an important food for humans and feed for livestock. Sorghum contains dhurrin which can be degraded into toxic hydrogen cyanide. Here, we report the expression patterns of 14 candidate genes related to dhurrin ((S)-4-Hydroxymandelnitrile-β-D-glucopyranoside) metabolism and the effects of the gene expression on specific metabolite content in selected sorghum accessions. Dhurrin-related metabolism is vigorous in the early stages of development of sorghum. The dhurrin contents of most accessions tested were in the range of approximately 6–22 μg mg−1 fresh leaf tissue throughout growth. The p-hydroxybenzaldehyde (pHB) contents were high at seedling stages, but almost nonexistent at adult stages. The contents of p-hydroxyphenylacetic acid (pHPAAc) were relatively low throughout growth compared to those of dhurrin or pHB. Generally, the expression of the candidate genes was higher at seedling stage than at other stages and decreased gradually as plants grew. In addition, we identified significant SNPs, and six of them were potentially associated with non-synonymous changes in CAS1. Our results may provide the basis for choosing breeding materials to regulate cyanide contents in sorghum varieties to prevent HCN toxicity of livestock or to promote drought tolerance or pathogen resistance.

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Glutathione transferases catalyze recycling of auto‐toxic cyanogenic glucosides in sorghum

Cited by 58 publications

References 79 publications

The Structure and Function of Major Plant Metabolite Modifications

The Structure and Function of Major Plant Metabolite Modifications

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

Prediction of Dhurrin Metabolism by Transcriptome and Metabolome Analyses in Sorghum

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