Functional Analyses of Caffeic Acid O-Methyltransferase and Cinnamoyl-CoA-Reductase Genes from Perennial Ryegrass (Lolium perenne)

Tu, Yi Fang; Rochfort, Simone; Liu, Zhiqian; Ran, Yidong; Griffith, Megan; Badenhorst, Pieter; Louie, G.V.; Bowman, M.E.; Smith, K. F.; Noel, Joseph P.; Mouradov, Aidyn; Spangenberg, Germán

doi:10.1105/tpc.109.072827

Cited by 165 publications

(140 citation statements)

References 83 publications

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“…These compounds were identified mainly as kaempferol glycosides (Table 2), which occur in many plants (Chopin and Dellamonica, 1988). Tu et al (2010), recently identified several flavonols in L. perenne, including some of the compounds identified in the present study, that is, kaempferol-3-O-rutinoside, rutin and kaempferol-3-O-glucosyl-rhamnosyl-galactoside. However, these authors did not report the presence of kaempferol, kaempferol-O-acetyl-glucoside and kaempferol-xylosyl-rhamnoside found in the present study (Table 2).…”

Section: Discussionsupporting

confidence: 54%

“…There is surprisingly little information available on the polyphenols that are present in this plant. Several studies analysed simple phenolic acids in ryegrass Jones, 1976, 1977) and two recent reports also described the presence of flavonoids (Tu et al, 2010;Qawasmeh et al, 2012). As plants belonging to the Poaceae family appear to have a narrower range of polyphenolic compounds than plants belonging to the Fabaceae family (Harborne, 1967; Although not confirmed by other means, it is likely that the flavonols are glycosylated at carbon 3.…”

Section: Discussionmentioning

confidence: 99%

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Antioxidant effects of ryegrass phenolics in lamb liver and plasma

Luciano

Vasta

Gibson

et al. 2014

Animal

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Sixteen lambs were divided into two groups and fed two different diets. Eight lambs were stall-fed with a concentrate-based diet (C), and the remaining eight lambs were allowed to graze on Lolium perenne (G). The antioxidant status was measured in the liver and plasma samples before and after solid-phase extraction (SPE) to probe the antioxidant effects that grass phenolic compounds may have conferred onto the animal tissues. The liver and plasma samples from grass-fed lambs displayed a greater antioxidant capacity than the tissues from C lamb group, but only if samples had not been passed through SPE cartridges. Finally, the feed and animal tissues, which had been purified by SPE, were analysed by liquid chromatography combined with mass spectrometry (LC-MS) to identify phenolic compounds present in L. perenne and to evaluate the results from the antioxidant assays. It would appear that the improvement of the antioxidant capacity of lamb liver and plasma from lambs fed ryegrass was not related to the direct transfer of phenolic compounds from grass to the animal tissues.

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Section: Discussionsupporting

confidence: 54%

Section: Discussionmentioning

confidence: 99%

Antioxidant effects of ryegrass phenolics in lamb liver and plasma

Luciano

Vasta

Gibson

et al. 2014

Animal

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“…This might have been due to the difference in the plant internodes/segments used for analytical pyrolysis and histochemical analysis. Maüle staining and acetyl bromide-soluble lignin content of the downregulated OMT and CCR in transgenic perennial ryegrass plants showed different lignin content and S/G ratio in different internodes of the same transgenic plant (Tu et al, 2010).…”

Section: Sl Pang Et Almentioning

confidence: 99%

Isolation and characterization of CCoAOMT in interspecific hybrid of Acacia auriculiformis x Acacia mangium - a key gene in lignin biosynthesis

Pang¹,

Ong²,

Lee³

et al. 2014

Genet. Mol. Res.

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ABSTRACT. This study was directed at the understanding of the function of CCoAOMT isolated from Acacia auriculiformis x Acacia mangium. Full length cDNA of the Acacia hybrid CCoAOMT (AhCCoAOMT) was 1024-bp long, containing 750-bp coding regions, with one major open reading frame of 249 amino acids. On the other hand, full length genomic sequence of the CCoAOMT (AhgflCCoAOMT) was 2548 bp long, containing three introns and four exons with a 5' untranslated region (5'UTR) of 391 bp in length. The 5'UTR of the characterized CCoAOMT gene contains various regulatory elements. Southern analysis revealed that the Acacia hybrid has more than three copies of the CCoAOMT gene. Real-time PCR showed that this gene was expressed in root, inner bark, leaf, flower and seed pod of the Acacia hybrid. Downregulation of the homologous CCoAOMT gene in tobacco by antisense (AS) and intron-containing hairpin (IHP) constructs containing partial AhCCoAOMT led to reduction in lignin content. Expression of the CCoAOMT in AS line (pART-HAS78-03) and IHP line (pART-HIHP78-06) was reduced respectively by 37 and 75% compared to the control, resulting in a decrease in the estimated lignin content by 24 and 56%, respectively. AhCCoAOMT was found to have altered not only S and G units but also total lignin content, which is of economic value to the pulp industry. Subsequent polymorphism analysis of this gene across eight different genetic backgrounds each of A. mangium and A. auriculiformis revealed 47 single nucleotide polymorphisms (SNPs) in A. auriculiformis CCoAOMT and 30 SNPs in A. mangium CCoAOMT.

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“…Lignin content increases with progressive maturity of stems; these relationships have been studied in detail in alfalfa (Jung et al, 1997;Chen et al, 2006), ryegrass (Tu et al, 2010), tall fescue (Buxton & Redfearn 1997;Chen et al, 2002) and switchgrass (Mann et al, 2009;Shen et al, 2009). Decreasing the lignin content increases the digestibility of alfalfa for ruminant animals (Baucher et al, 1999; Guo et al, 2001a,b;Reddy et al, 2005) 4 and improves processing efficiency for production of liquid biofuels through saccharification and fermentation .…”

Section: Function and Distribution Of Lignin In Plantsmentioning

confidence: 99%

“…A correlation has been shown between degradability of the cell walls in forages and the amount of G lignin, as lignin rich in G units is more highly condensed, making it less amenable to degradation (Jung & Deetz 1993). Thus, transgenic poplar plants with lignin rich in G units are, like softwoods, more difficult to pulp because of their more condensed lignin (Lapierre et al, 1999).Lignin content increases with progressive maturity of stems; these relationships have been studied in detail in alfalfa (Jung et al, 1997;Chen et al, 2006), ryegrass (Tu et al, 2010), tall fescue (Buxton & Redfearn 1997;Chen et al, 2002) and switchgrass (Mann et al, 2009;Shen et al, 2009). Decreasing the lignin content increases the digestibility of alfalfa for ruminant animals (Baucher et al, 1999; Guo et al, 2001a,b;Reddy et al, 2005) 4 and improves processing efficiency for production of liquid biofuels through saccharification and fermentation .…”

mentioning

confidence: 99%

Monolignol Biosynthesis and its Genetic Manipulation: The Good, the Bad, and the Ugly

Dixon

Reddy

Gallego‐Giraldo³

2014

Recent Advances in Polyphenol Research

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Economic and environmental factors favor the adoption of lignocellulosic bioenergy crops for production of liquid transportation fuels. However, lignocellulosic biomass is recalcitrant to saccharification (sugar release from cell walls), and this is, at least in part, due to the presence of the phenylpropanoid-derived cell wall polymer lignin. A large body of evidence exists documenting the impacts of lignin modification in plants. This technology can lead to improved forage quality and enhanced processing properties for trees (paper pulping) and lignocellulosic energy crops. We here provide a comprehensive review of the literature on lignin modification in plants. The pathway has been targeted through down-regulating expression of the enzymes of the monolignol pathway, as well as through down-regulation or over-expression of transcription factors that control lignin biosynthesis and/or programs of secondary cell wall development. Targeting lignin modification at some steps in the monolignol pathway can result in impairment of plant growth and development, often associated with the triggering of endogenous host defense mechanisms. Recent studies suggest that it may be possible to decouple negative growth impacts from lignin reduction.Keywords: monolignol biosynthesis, genetic modification, transcription factor, gene silencing, saccharification. 2 IntroductionLignin is a major component of plant secondary cell walls, and the second most abundant plant polymer on the planet. Lignin constitutes about 15-35% of the dry mass of vascular plants (Adler, 1977). Considerable attention has been given over the past several years to the reduction of lignin content in model plant species, forages, trees, and dedicated bioenergy feedstocks. This is because forage digestibility, paper pulping and liquid fuel production from biomass through fermentation are all affected by recalcitrance of lignocellulose, primarily due to the presence of lignin, which blocks accessibility of the sugar-rich cell wall polysaccharides cellulose and hemicellulose to enzymes and microorganisms (Pilate et al., 2002;Reddy et al., 2005;.Much is now known of the biosynthesis of lignin and its control at the transcriptional level. This information informs the targets that have been selected for genetic modification of lignin content and composition in transgenic plants. There is considerable variation in the effects on lignin content and composition depending on the gene that is targeted for down-or up-regulation. Equally important, lignin modification can have profound impacts on plant growth and development, ranging from good through bad to "downright ugly", but these impacts are again strongly target dependent. Understanding the mechanisms that may impact plant growth, which equate to agronomic performance, in crop species "improved" through lignin modification is critical for economic advancement of the forage and biofuels industries. Although still poorly understood, these mechanisms may also throw light on basal plant developmental and de...

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Functional Analyses of Caffeic Acid O-Methyltransferase and Cinnamoyl-CoA-Reductase Genes from Perennial Ryegrass (Lolium perenne)

Cited by 165 publications

References 83 publications

Antioxidant effects of ryegrass phenolics in lamb liver and plasma

Antioxidant effects of ryegrass phenolics in lamb liver and plasma

Isolation and characterization of CCoAOMT in interspecific hybrid of Acacia auriculiformis x Acacia mangium - a key gene in lignin biosynthesis

Monolignol Biosynthesis and its Genetic Manipulation: The Good, the Bad, and the Ugly

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