NAC-MYB-based transcriptional regulation of secondary cell wall biosynthesis in land plants

Nakano, Yoshimi; Yamaguchi, Masatoshi; Endo, Hitoshi; Rejab, Nur Ardiyana; Ohtani, Misato

doi:10.3389/fpls.2015.00288

Cited by 365 publications

(368 citation statements)

References 172 publications

Supporting

Mentioning

349

Contrasting

Unclassified

Order By: Relevance

“…Ten NAC genes were up-regulated during lignin formation, whereas six NAC genes were down-regulated (Supplemental Table S9). Similar observations were made for the R2R3-MYB transcription factor family, members of which act as second-level master regulators and/or direct regulators of secondary cell wall biosynthesis (Nakano et al, 2015;Zhong and Ye, 2015;Supplemental Table S9). In addition to NACs and MYBs, several members of the APETALA2/ethylene response element-binding protein (AP2/EREBP), LBD, WRKY, C2H2 zinc finger, and Tify transcription factor families showed up-regulation in lignin-forming conditions.…”

Section: A Broad Array Of Transcription Factor Families Were Inducedsupporting

confidence: 48%

“…MYB and WRKY transcription factor families were enriched among the differentially expressed genes (Supplemental Table S9). NAC (NAM, ATAF1/2, and CUC2) transcription factors are important for secondary cell wall development in Arabidopsis (Nakano et al, 2015;Zhong and Ye, 2015) and are likely also involved in the regulation of secondary cell wall biosynthesis in conifers Raherison et al, 2015;Lamara et al, 2016). Ten NAC genes were up-regulated during lignin formation, whereas six NAC genes were down-regulated (Supplemental Table S9).…”

Section: A Broad Array Of Transcription Factor Families Were Inducedmentioning

confidence: 99%

See 1 more Smart Citation

A Key Role for Apoplastic H₂O₂ in Norway Spruce Phenolic Metabolism

et al. 2017

View full text Add to dashboard Cite

Apoplastic events such as monolignol oxidation and lignin polymerization are difficult to study in intact trees. To investigate the role of apoplastic hydrogen peroxide (H 2 O 2 ) in gymnosperm phenolic metabolism, an extracellular lignin-forming cell culture of Norway spruce (Picea abies) was used as a research model. Scavenging of apoplastic H 2 O 2 by potassium iodide repressed lignin formation, in line with peroxidases activating monolignols for lignin polymerization. Time-course analyses coupled to candidate substrate-product pair network propagation revealed differential accumulation of low-molecular-weight phenolics, including (glycosylated) oligolignols, (glycosylated) flavonoids, and proanthocyanidins, in lignin-forming and H 2 O 2 -scavenging cultures and supported that monolignols are oxidatively coupled not only in the cell wall but also in the cytoplasm, where they are coupled to other monolignols and proanthocyanidins. Dilignol glycoconjugates with reduced structures were found in the culture medium, suggesting that cells are able to transport glycosylated dilignols to the apoplast. Transcriptomic analyses revealed that scavenging of apoplastic H 2 O 2 resulted in remodulation of the transcriptome, with reduced carbon flux into the shikimate pathway propagating down to monolignol biosynthesis. Aggregated coexpression network analysis identified candidate enzymes and transcription factors for monolignol oxidation and apoplastic H 2 O 2 production in addition to potential H 2 O 2 receptors. The results presented indicate that the redox state of the apoplast has a profound influence on cellular metabolism.

show abstract

Section: A Broad Array Of Transcription Factor Families Were Inducedsupporting

confidence: 48%

Section: A Broad Array Of Transcription Factor Families Were Inducedmentioning

confidence: 99%

A Key Role for Apoplastic H₂O₂ in Norway Spruce Phenolic Metabolism

et al. 2017

View full text Add to dashboard Cite

show abstract

“…In addition, following pathogen invasion, more secondary metabolites are induced (RRI) and these form complex polymers that are deposited in xylem vessels to enforce cell walls (Gunnaiah et al, 2012;Wang et al, 2014b;Yogendra et al, 2015a). The conjugated complex metabolites, not degraded by the enzymes produced by most pathogens, are produced in the phenylpropanoid, flavonoid, fatty acid, and alkaloid metabolic pathways (Figure 2) (Nakano et al, 2015;Yogendra et al, 2015b). These play a significant role in plant resistance; Lignin: These are three-dimensional phenolic heteropolymers resulting from the oxidative coupling of three p-hydroxycinnamoyl (p-coumaryl, coniferyl, and sinapyl) alcohols.…”

Section: B Resistance-related Metabolites (Rrm) and The Mechanisms Omentioning

confidence: 99%

“…The overexpression of VvWRKY1 induced a cinnamoyl alcohol dehydrogenase and a caffeic acid O-methyl transferase gene in grape vines, providing higher resistance to downy mildew (Marchive et al, 2013) and the transcriptional activation of StWRKY1 by heat shock protein (sHSP17.8)-induced phenylpropanoid genes in potato conferring resistance to late blight (Yogendra et al, 2015a). In plants, a battery of NAC and MYB TFs activate secondary cell wall formation based on lignin monomers (Nakano et al, 2015). WRKY29, a JA-responsive TF, was expressed only in F. graminearum-resistant genotype, Wangshuibai, but not when the QTL-Fhb1 region was deleted (Xiao et al, 2013).…”

Section: Transcription Factor (Tf) Genes and Regulation Of Resistamentioning

confidence: 99%

“…The pathogens also try to neutralize the effect of these phytoalexins by converting them to less toxic oxidized forms or conjugate with glycosides through production of enzymes (Jeandet et al, 2014). Primary cell walls produced by cellulose and pectins are constitutively enforced by the deposition of secondary metabolites (RRC) (Bashline et al, 2014;Eudes et al, 2014;Nakano et al, 2015). In addition, following pathogen invasion, more secondary metabolites are induced (RRI) and these form complex polymers that are deposited in xylem vessels to enforce cell walls (Gunnaiah et al, 2012;Wang et al, 2014b;Yogendra et al, 2015a).…”

Section: B Resistance-related Metabolites (Rrm) and The Mechanisms Omentioning

confidence: 99%

See 1 more Smart Citation

Plant Innate Immune Response: Qualitative and Quantitative Resistance

Kushalappa

Yogendra

Karre

2016

Critical Reviews in Plant Sciences

147

102

View full text Add to dashboard Cite

Plant diseases, caused by microbes, threaten world food, feed, and bioproduct security. Plant resistance has not been effectively deployed to improve resistance in plants for lack of understanding of biochemical mechanisms and genetic bedrock of resistance. With the advent of genome sequencing, the forward and reverse genetic approaches have enabled deciphering the riddle of resistance. Invading pathogens produce elicitors and effectors that are recognized by the host membrane-localized receptors, which in turn induce a cascade of downstream regulatory and resistance metabolite and protein biosynthetic genes (R) to produce resistance metabolites and proteins, which reduce pathogen advancement through their antimicrobial and cell wall enforcement properties. The resistance in plants to pathogen attack is expressed as reduced susceptibility, ranging from high susceptibility to hypersensitive response, the shades of gray. The hypersensitive response or cell death is considered as qualitative resistance, while the remainder of the reduced susceptibility is considered as quantitative resistance. The resistance is due to additive effects of several resistance metabolites and proteins, which are produced through a network of several hierarchies of plant R genes. Plants recognize the pathogen elicitors or receptors and then induce downstream genes to eventually produce resistance metabolites and proteins that suppress the pathogen advancement in plant. These resistance genes (R), against qualitative and quantitative resistance, can be identified in germplasm collections and replaced in commercial cultivars, if nonfunctional, based on genome editing to improve plant resistance.

show abstract

Morphological Innovation Drives Sperm Release in Bryophytes

Zhang,

Bian,

Yang

et al. 2024

Advanced Science

View full text Add to dashboard Cite

Plant movements for survival are nontrivial. Antheridia in the moss Physcomitrium patens (P. patens) use motion to eject sperm in the presence of water. However, the biological and mechanical mechanisms that actuate the process are unknown. Here, the burst of the antheridium of P. patens, triggered by water, results from elastic instability and is determined by an asymmetric change in cell geometry. The tension generated in jacket cell walls of antheridium arises from turgor pressure, and is further promoted when the inner walls of apex burst in hydration, causing water and cellular contents of apex quickly influx into sperm chamber. The outer walls of the jacket cells are strengthened by NAC transcription factor VNS4 and serve as key morphomechanical innovations to store hydrostatic energy in a confined space in P. patens. However, the antheridium in liverwort Marchantia polymorpha (M. polymorpha) adopts a different strategy for sperm release; like jacket cell outer walls of P. patens, the cells surrounding the antheridium of M. polymorpha appear to play a similar role in the storage of energy. Collectively, the work shows that plants have evolved different ingenious devices for sperm discharge and that morphological innovations can differ.

show abstract

NAC-MYB-based transcriptional regulation of secondary cell wall biosynthesis in land plants

Cited by 365 publications

References 172 publications

A Key Role for Apoplastic H₂O₂ in Norway Spruce Phenolic Metabolism

A Key Role for Apoplastic H₂O₂ in Norway Spruce Phenolic Metabolism

Plant Innate Immune Response: Qualitative and Quantitative Resistance

Morphological Innovation Drives Sperm Release in Bryophytes

Contact Info

Product

Resources

About

NAC-MYB-based transcriptional regulation of secondary cell wall biosynthesis in land plants

Cited by 365 publications

References 172 publications

A Key Role for Apoplastic H2O2 in Norway Spruce Phenolic Metabolism

A Key Role for Apoplastic H2O2 in Norway Spruce Phenolic Metabolism

Plant Innate Immune Response: Qualitative and Quantitative Resistance

Morphological Innovation Drives Sperm Release in Bryophytes

Contact Info

Product

Resources

About

A Key Role for Apoplastic H₂O₂ in Norway Spruce Phenolic Metabolism

A Key Role for Apoplastic H₂O₂ in Norway Spruce Phenolic Metabolism