Evolution of a Novel Phenolic Pathway for Pollen Development

Matsuno, Michiyo; Compagnon, Vincent; Schoch, Guillaume A.; Schmitt, Martine; Debayle, Delphine; Bassard, Jean‐Etienne; Pollet, Brigitte; Hehn, Alain; Heintz, Dimitri; Ullmann, Pascaline; Lapierre, Catherine; Bernier, François; Ehlting, Jürgen; Werck‐Reichhart, Danièle

doi:10.1126/science.1174095

Cited by 147 publications

(162 citation statements)

References 30 publications

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“…Thus, these genes are likely paralogs, where one gene results from the gene duplication of the other. This is consistent with a theory that explains the evolution of enzyme function (Ober, 2005;Des Marais and Rausher, 2008;Matsuno et al, 2009), which states that a set of enzymes with similar (but different) catalytic functions can be generated by gene duplication. As implicated from the genomic map and the phylogenetic tree (Figure 1), gene duplication of cluster I UGTs appears to have occurred in the grapevine genome, resulting in a small subcluster of functionally differentiated UGTs.…”

Section: Evolution Of Sugar Donor Specificitysupporting

confidence: 73%

Functional Differentiation of the Glycosyltransferases That Contribute to the Chemical Diversity of Bioactive Flavonol Glycosides in Grapevines (Vitis vinifera)

et al. 2010

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We identified two glycosyltransferases that contribute to the structural diversification of flavonol glycosides in grapevine (Vitis vinifera): glycosyltransferase 5 (Vv GT5) and Vv GT6. Biochemical analyses showed that Vv GT5 is a UDP-glucuronic acid:flavonol-3-O-glucuronosyltransferase (GAT), and Vv GT6 is a bifunctional UDP-glucose/UDP-galactose:flavonol-3-Oglucosyltransferase/galactosyltransferase. The Vv GT5 and Vv GT6 genes have very high sequence similarity (91%) and are located in tandem on chromosome 11, suggesting that one of these genes arose from the other by gene duplication. Both of these enzymes were expressed in accordance with flavonol synthase gene expression and flavonoid distribution patterns in this plant, corroborating their significance in flavonol glycoside biosynthesis. The determinant of the specificity of Vv GT5 for UDP-glucuronic acid was found to be Arg-140, which corresponded to none of the determinants previously identified for other plant GATs in primary structures, providing another example of convergent evolution of plant GAT. We also analyzed the determinants of the sugar donor specificity of Vv GT6. Gln-373 and Pro-19 were found to play important roles in the bifunctional specificity of the enzyme. The results presented here suggest that the sugar donor specificities of these Vv GTs could be determined by a limited number of amino acid substitutions in the primary structures of protein duplicates, illustrating the plasticity of plant glycosyltransferases in acquiring new sugar donor specificities. INTRODUCTIONGrapevine (Vitis vinifera) ( Figure 1A) has been one of the most important fruit crops from the beginning of human civilization (McGovern et al., 1997). Dietary intake of grapevine-based products results in diverse biological effects that are beneficial to human health, in part due to polyphenols, such as flavonoids (e.g., flavonols, proanthocyanidins, and anthocyanins) (Renaud and de Lorgeril, 1992;Corder et al., 2001Corder et al., , 2006Baur et al., 2006). Flavonols, such as kaempferol, quercetin, and isorhamnetin, are an important class of bioactive flavonoids, which are most abundant as their 3-O-glycosides (i.e., glucoside, glucuronoside, galactoside, and rutinoside) in the berries, seeds, and leaves of grapevine (Hmamouchi et al., 1996;Castillo-Munoz et al., 2009).In this plant, biosynthesis of flavonol glycosides primarily serves to protect the plant from excess UV light (Price et al., 1995;Matus et al., 2009). Flavonol aglycons are biosynthesized from dihydroflavonols by the action of flavonol synthase (Vv FLS), a 2-oxoglutarate-dependent dioxygenase, which is temporally regulated by an R2R3-Myb transcription factor, Vv MYBF1 (Fujita et al., 2006;Czemmel et al., 2009). Subsequently, glycosylation of flavonols enhances their water solubility, such that high concentrations of flavonols can accumulate in plant cells.From a food chemistry perspective, flavonol glycosides define the color of wine grapes and products by acting as copigments (Yoshitama et al., 1992;Boulto...

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Section: Evolution Of Sugar Donor Specificitysupporting

confidence: 73%

Functional Differentiation of the Glycosyltransferases That Contribute to the Chemical Diversity of Bioactive Flavonol Glycosides in Grapevines (Vitis vinifera)

et al. 2010

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“…Matsuno and co-workers observed that the young members showed, for this family, an unusual lack of intronic sequence and were clustered on chromosome 1. Consequently, it was suggested that the family's expansion was the result of a series of events starting with retrotransposition and tandem duplication, concomitant with neofuntionalization and subsequent further specialization, or broadening of the function [23]. The positions of amino acids under strong positive selection and structure homology modelling indicated enlargement of the substrate access channel and active site cavity in comparison with the ancestral CYP98A.…”

Section: Cyp98a Bridges General and Specialized Phenylpropanoid Metabmentioning

confidence: 99%

Plant P450s as versatile drivers for evolution of species-specific chemical diversity

Hamberger

Bak

2013

Phil. Trans. R. Soc. B

256

231

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The irreversible nature of reactions catalysed by P450s makes these enzymes landmarks in the evolution of plant metabolic pathways. Founding members of P450 families are often associated with general (i.e. primary) metabolic pathways, restricted to single copy or very few representatives, indicative of purifying selection. Recruitment of those and subsequent blooms into multi-member gene families generates genetic raw material for functional diversification, which is an inherent characteristic of specialized (i.e. secondary) metabolism. However, a growing number of highly specialized P450s from not only the CYP71 clan indicate substantial contribution of convergent and divergent evolution to the observed general and specialized metabolite diversity. We will discuss examples of how the genetic and functional diversification of plant P450s drives chemical diversity in light of plant evolution. Even though it is difficult to predict the function or substrate of a P450 based on sequence similarity, grouping with a family or subfamily in phylogenetic trees can indicate association with metabolism of particular classes of compounds. Examples will be given that focus on multi-member gene families of P450s involved in the metabolic routes of four classes of specialized metabolites: cyanogenic glucosides, glucosinolates, mono-to triterpenoids and phenylpropanoids.

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“…In line with our observation of the manufacture of a specific set of metabolites in this tissue (Dataset S1), previous studies have shown that metabolites, notably certain phenolic derivatives, are abundant and highly specific for the tapetum (specialized layer of nutritive cells and source of precursors for the pollen coat within anthers) of anthers and pollen grains (39)(40)(41). The biosynthesis of these phenolic derivatives, with potential roles in pollen coat composition and establishment of fertilization barriers, has been linked to rapid metabolic gene evolution through retroposition and neofunctionalization (42). In a cross-species study on transcriptome evolutionary divergence, the fastest rates of gene expression divergence and signatures of transcriptome specialization were detected in anthers, whereas the lowest rates of evolution were detected in roots (43).…”

Section: Cross-tissue Intensity Variationmentioning

confidence: 99%

Illuminating a plant’s tissue-specific metabolic diversity using computational metabolomics and information theory

Heiling

Baldwin

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Secondary metabolite diversity is considered an important fitness determinant for plants' biotic and abiotic interactions in nature. This diversity can be examined in two dimensions. The first one considers metabolite diversity across plant species. A second way of looking at this diversity is by considering the tissue-specific localization of pathways underlying secondary metabolism within a plant. Although these cross-tissue metabolite variations are increasingly regarded as important readouts of tissue-level gene function and regulatory processes, they have rarely been comprehensively explored by nontargeted metabolomics. As such, important questions have remained superficially addressed. For instance, which tissues exhibit prevalent signatures of metabolic specialization? Reciprocally, which metabolites contribute most to this tissue specialization in contrast to those metabolites exhibiting housekeeping characteristics? Here, we explore tissue-level metabolic specialization in Nicotiana attenuata, an ecological model with rich secondary metabolism, by combining tissue-wide nontargeted mass spectral data acquisition, information theory analysis, and tandem MS (MS/MS) molecular networks. This analysis was conducted for two different methanolic extracts of 14 tissues and deconvoluted 895 nonredundant MS/MS spectra. Using information theory analysis, anthers were found to harbor the most specialized metabolome, and most unique metabolites of anthers and other tissues were annotated through MS/MS molecular networks. Tissuemetabolite association maps were used to predict tissue-specific gene functions. Predictions for the function of two UDP-glycosyltransferases in flavonoid metabolism were confirmed by virus-induced gene silencing. The present workflow allows biologists to amortize the vast amount of data produced by modern MS instrumentation in their quest to understand gene function.secondary metabolism | mass spectrometry | metabolomics | information theory | Nicotiana attenuata P lants are elegant synthetic chemists making use of their metabolic prowess to produce complex blends of structurally diverse chemicals. Commonly quoted estimates state that plants produce somewhere on the order of 200,000 chemical structures. Secondary metabolites, also referred to as specialized metabolites or natural products, contribute to the largest fraction of this structural diversity. Compared with their counterparts in central metabolism (primary metabolites), secondary metabolite groups have diversified to the extreme in plant lineages, likely as a result of the multiple ecological roles they fulfill (1). The high degree of plasticity of secondary metabolism pathways is consistent with the existence of large families of metabolism-related genes such as cytochrome P450s and UDP-glycosyltransferases in plant genomes that can create structural and chemical modifications almost without limits. The majority of metabolic gene functions remain unknown, however, either because the metabolites that they produce are unknown or signi...

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Evolution of a Novel Phenolic Pathway for Pollen Development

Cited by 147 publications

References 30 publications

Functional Differentiation of the Glycosyltransferases That Contribute to the Chemical Diversity of Bioactive Flavonol Glycosides in Grapevines (Vitis vinifera)

Functional Differentiation of the Glycosyltransferases That Contribute to the Chemical Diversity of Bioactive Flavonol Glycosides in Grapevines (Vitis vinifera)

Plant P450s as versatile drivers for evolution of species-specific chemical diversity

Illuminating a plant’s tissue-specific metabolic diversity using computational metabolomics and information theory

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