The peach (Prunus persica L. Batsch) genome harbours 10 KNOX genes, which are differentially expressed in stem development, and the class 1 KNOPE1 regulates elongation and lignification during primary growth

Testone, Giulio; Condello, E.; Verde, Ignazio; Nicolodi, Chiara; Caboni, E.; Dettori, Maria Teresa; Vendramin, Elisa; Bruno, Leonardo; Bitonti, Maria Beatrice; Mele, Giovanni; Giannino, Donato

doi:10.1093/jxb/ers194

Cited by 30 publications

(51 citation statements)

References 86 publications

(116 reference statements)

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“…The loss-of-function mutants fail to maintain shoot meristems [16][17][18]. In addition, class I KNOX genes are involved in distinct aspects of developmental processes, such as leaf dissection in compound leaf species, internode elongation, inflorescence architecture and establishment of vascular connections between parasitic plants and their hosts [19][20][21][22][23][24]. Thus, the class I KNOX gene regulatory module has been recruited to various developmental processes during the evolution of shoot systems.…”

Section: Diverse Functions Of Knox Genes In the Plant Lineagementioning

confidence: 99%

Diverse functions of KNOX transcription factors in the diploid body plan of plants

Tsuda

Hake

2015

Current Opinion in Plant Biology

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KNOX genes were initially found as shoot meristem regulators in angiosperms. Recent studies in diverse plant lineages however, have revealed the divergence of KNOX gene function during the evolution of diploid body plans. Using genomic approaches, class I KNOX transcription factors have been shown to regulate multiple hormone pathways including auxin and brassinosteroid as well as many transcription factors that play important roles in plant development. Class I KNOX proteins appear to be activators, whereas class II proteins act as repressors in transcriptional regulation of their target genes.

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Section: Diverse Functions Of Knox Genes In the Plant Lineagementioning

confidence: 99%

Diverse functions of KNOX transcription factors in the diploid body plan of plants

Tsuda

Hake

2015

Current Opinion in Plant Biology

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“…In Arabidopsis, a mutation in the second enzyme (C4H) of lignin biosynthesis pathway decreased levels of several different classes of phenylpropanoid end products and exhibited reduced lignin deposition, altered lignin monomer content, and a collapsed xylem phenotype (Schilmiller et al 2009). In this context of cross talk between establishment and development of the cambium meristem on the one hand and lignification on the other, it is interesting to note that a class I knotted-like gene (knope1) prevented cell lignification by repressing lignin genes during peach stem primary growth (Testone et al 2012), suggesting the role of knox genes in suppressing lignin biosynthesis during storage root formation in sweet potato.…”

Section: F Lignification Of Sweet Potato Roots and Related Gene Exprmentioning

confidence: 99%

Molecular Regulation of Storage Root Formation and Development in Sweet Potato

Ravi¹,

Chakrabarti²,

Makeshkumar³

et al. 2014

Horticultural Reviews: Volume 42

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Storage root formation and development in sweet potato [Ipomoea batatas (L) Lam. Convolvulaceae] is a complex process characterized by the cessation of root elongation, genesis of vascular cambium, anomalous and interstitial cambia, and increase in radial growth by increased cell proliferation and expansion concomitant with the massive deposition of starch and storage proteins that eventually result in storage root enlargement. Phytohormones play a crucial role in the formation of storage roots. Three class I knotted-like homeobox (KNOX1) genes-SRF1, SRF5, and SRF6-modulate carbohydrate metabolism and cell division. The genes Ibkn1 and Ibkn2 activate cytokinin biosynthesis. Transcription factors derived from MADS box genes IbMADS1, IbMADS3, IbMADS4, and IbAGL17 induce signal transduction pathway leading to storage root formation and development. The occurrence of SRD1 transcripts mainly in the actively dividing cells, including the vascular and cambium cells, and the increase in endogenous indole-3-acetic acid (IAA) content and three auxin-inducible AUX/IAA gene transcripts concomitantly with SRD1 transcripts suggest the involvement of SRD1 during the early stage of storage root development. Along with IbMADS1 induction, two storage root marker genes, which encode a major storage protein sporamin and IbAGPase that encodes AGPase for ADP-glucose production in starch biosynthesis, are up-regulated during the early period of storage root development. A class III HD-Zip protein 8 regulating the development of cambia and secondary vascular tissues, a short-root protein that is a key regulator in root 157 radial patterning, meristem maintenance, and asymmetric cell division, the expansin gene IbEXP1 encoding a cell wall loosening protein, genes encoding cyclin A-and cyclin D-like proteins, and five cyclin-dependent kinases are upregulated during storage root formation. Genes encoding ADP-glucose pyrophosphorylase, granule-bound starch synthase, starch synthase, and phosphoglucomutase are up-regulated, whereas genes encoding pyruvate decarboxylase and lactate dehydrogenase are down-regulated during storage root development. The endogenous sucrose levels influence the expression of two AGPase isoforms: ibAGP1 and ibAGP2. The expression of cell wall-bound (extracellular/apoplast) acid invertase activity gene (cwINV) predominates during early period, whereas the expression of cytosolic activity of sucrose synthase gene (SuSy) predominates during later period of storage root enlargement. The competition between lignification and formation of anomalous cambia and the associated starchaccumulating cells determine storage root development. Genes encoding enzymes such as coumaroyl-CoA synthase, caffeoyl-CoA O-methyltransferase, and cinnamyl alcohol dehydrogenase during storage root formation reduce lignification in tissue sections of storage roots.

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“…The expression pattern of CCOMT and CAD indicated that lignin biosynthesis was reduced during the early stage of SR development. In addition, upregulation of KNOX1 in I-stage and S-stage was negatively correlated with the expression of lignin biosynthesis key genes (CCOMT and CAD) (Guo et al 2001;Townsley et al 2013) suggesting that reduction of lignin biosynthesis corresponds to SR development (Firon et al 2013;Testone et al 2012).…”

Section: Functional Analysis Of Significant Genes During Phase Transimentioning

confidence: 99%

Genome-wide analysis reveals phytohormone action during cassava storage root initiation

et al. 2015

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Development of storage roots is a process associated with a phase change from cell division and elongation to radial growth and accumulation of massive amounts of reserve substances such as starch. Knowledge of the regulation of cassava storage root formation has accumulated over time; however, gene regulation during the initiation and early stage of storage root development is still poorly understood. In this study, transcription profiling of fibrous, intermediate and storage roots at eight weeks old were investigated using a 60-mer-oligo microarray. Transcription and gene expression were found to be the key regulating processes during the transition stage from fibrous to intermediate roots, while homeostasis and signal transduction influenced regulation from intermediate roots to storage roots. Clustering analysis of significant genes and transcription factors (TF) indicated that a number of phytohormone-related TF were differentially expressed; therefore, phytohormone-related genes were assembled into a network of correlative nodes. We propose a model showing the relationship between KNOX1 and phytohormones during storage root initiation. Exogeneous treatment of phytohormones N (6) -benzylaminopurine and 1-Naphthaleneacetic acid were used to induce the storage root initiation stage and to investigate expression patterns of the genes involved in storage root initiation. The results support the hypothesis that phytohormones are acting in concert to regulate the onset of cassava storage root development. Moreover, MeAGL20 is a factor that might play an important role at the onset of storage root initiation when the root tip becomes swollen.

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The peach (Prunus persica L. Batsch) genome harbours 10 KNOX genes, which are differentially expressed in stem development, and the class 1 KNOPE1 regulates elongation and lignification during primary growth

Cited by 30 publications

References 86 publications

Diverse functions of KNOX transcription factors in the diploid body plan of plants

Diverse functions of KNOX transcription factors in the diploid body plan of plants

Molecular Regulation of Storage Root Formation and Development in Sweet Potato

Genome-wide analysis reveals phytohormone action during cassava storage root initiation

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