Rice leaf inclination2, a VIN3-like protein, regulates leaf angle through modulating cell division of the collar

Shuqing, Zhao; Hu, Jiang; Guo, Longbiao; Qian, Qian; Hou, Xue

doi:10.1038/cr.2010.109

Cited by 148 publications

(145 citation statements)

References 46 publications

(68 reference statements)

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“…However, their roles in chromatin-modifying activities are largely not known. In particular, the VIN3 family of proteins is conserved throughout higher plants and play roles in diverse developmental programs (Zhao et al, 2010;Wang et al, 2013). Whether the histone binding preference of PHDfinger domains of the VIN3 family of proteins in other plant species functions in a similar manner remains to be addressed.…”

Section: Discussionmentioning

confidence: 99%

The Binding Specificity of the PHD-Finger Domain of VIN3 Moderates Vernalization Response

Kim

Sung

2016

Plant Physiol.

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Section: Discussionmentioning

confidence: 99%

The Binding Specificity of the PHD-Finger Domain of VIN3 Moderates Vernalization Response

Kim

Sung

2016

Plant Physiol.

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“…Deficiency of lamina joint structure (Lee et al, 2007), suppressed longitudinal elongation of adaxial parenchyma cells, and increased division of abaxial sclerenchyma cells of the lamina joint (Zhang et al, 2009a;Sun et al, 2015) result in leaf erectness. Conversely, increased expansion or proliferation of adaxial parenchyma cells leads to increased leaf inclination (Zhao et al, 2010(Zhao et al, , 2013Zhang et al, 2015). Abnormal vascular bundle formation and cell wall composition also result in changed leaf angle (Ning et al, 2011).…”

mentioning

confidence: 99%

“…INCREASED LEAF ANGLE1 (ILA1) encodes a Raf-like MAPKKK of group C, and the ila1 mutant presents increased leaf angle by abnormal vascular bundle formation and cell wall composition in the lamina joint (Ning et al, 2011). In addition, LEAF IN-CLINATION2 (LC2), a VIN3-like protein, controls leaf inclination by inhibiting adaxial cell division (Zhao et al, 2010). Suppression of small RNA-producing genes, including RNA-dependent RNA polymerase2, RNase III-class Dicer-like3, and OsAGO4a and OsAGO4b (members of the Argonaute family), results in the increased bending of the lamina joint (Wei et al, 2014), while increased expression of OsAGO7 leads to the leaf erectness (Shi et al, 2007).…”

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confidence: 99%

Dynamic Cytology and Transcriptional Regulation of Rice Lamina Joint Development

2017

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Rice (Oryza sativa) leaf angle is determined by lamina joint and is an important agricultural trait determining leaf erectness and, hence, the photosynthesis efficiency and grain yield. Genetic studies reveal a complex regulatory network of lamina joint development; however, the morphological changes, cytological transitions, and underlying transcriptional programming remain to be elucidated. A systemic morphological and cytological study reveals a dynamic developmental process and suggests a common but distinct regulation of the lamina joint. Successive and sequential cell division and expansion, cell wall thickening, and programmed cell death at the adaxial or abaxial sides form the cytological basis of the lamina joint, and the increased leaf angle results from the asymmetric cell proliferation and elongation. Analysis of the gene expression profiles at four distinct developmental stages ranging from initiation to senescence showed that genes related to cell division and growth, hormone synthesis and signaling, transcription (transcription factors), and protein phosphorylation (protein kinases) exhibit distinct spatiotemporal patterns during lamina joint development. Phytohormones play crucial roles by promoting cell differentiation and growth at early stages or regulating the maturation and senescence at later stages, which is consistent with the quantitative analysis of hormones at different stages. Further comparison with the gene expression profile of leaf inclination1, a mutant with decreased auxin and increased leaf angle, indicates the coordinated effects of hormones in regulating lamina joint. These results reveal a dynamic cytology of rice lamina joint that is fine-regulated by multiple factors, providing informative clues for illustrating the regulatory mechanisms of leaf angle and plant architecture.

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“…More than 40 additional quantitative trait loci (QTL) have been identified in the maize nested association mapping (NAM) and recombinant inbred lines (RIL) populations (McMullen et al 2009;Tian et al 2011;Li et al 2015). In rice, osdwarf4-1 and leaf inclination2 have been identified and shown to play roles in plant hormone responses that result in changes in leaf angle (Sakamoto et al 2006;Zhao et al 2010). Progress in identifying leaf angle QTL has been made in sorghum, the fifth most widely produced grain and forage crop, but a gene that regulates leaf angle has yet to be identified as has been done in maize and rice (Hart et al 2001;Gill et al 2014;Perez et al 2014;Xin et al 2015).…”

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Harnessing Genetic Variation in Leaf Angle to Increase Productivity of Sorghum bicolor

et al. 2015

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The efficiency with which a plant intercepts solar radiation is determined primarily by its architecture. Understanding the genetic regulation of plant architecture and how changes in architecture affect performance can be used to improve plant productivity. Leaf inclination angle, the angle at which a leaf emerges with respect to the stem, is a feature of plant architecture that influences how a plant canopy intercepts solar radiation. Here we identify extensive genetic variation for leaf inclination angle in the crop plant Sorghum bicolor, a C4 grass species used for the production of grain, forage, and bioenergy. Multiple genetic loci that regulate leaf inclination angle were identified in recombinant inbred line populations of grain and bioenergy sorghum. Alleles of sorghum dwarf-3, a gene encoding a P-glycoprotein involved in polar auxin transport, are shown to change leaf inclination angle by up to 34°(0.59 rad). The impact of heritable variation in leaf inclination angle on light interception in sorghum canopies was assessed using functionalstructural plant models and field experiments. Smaller leaf inclination angles caused solar radiation to penetrate deeper into the canopy, and the resulting redistribution of light is predicted to increase the biomass yield potential of bioenergy sorghum by at least 3%. These results show that sorghum leaf angle is a heritable trait regulated by multiple loci and that genetic variation in leaf angle can be used to modify plant architecture to improve sorghum crop performance.KEYWORDS leaf angle; crop modeling; sorghum canopy; bioenergy sorghum; dwarf-3; P-glycoprotein; auxin transport S USTAINABLY increasing the productivity of crops on land currently used for agriculture without depleting natural resources is a global priority (Foley et al. 2011;Drewry et al. 2014). Improving the efficiency with which plants intercept solar radiation is one means to sustainably improve crop productivity. Leaf angle, or leaf erectness, is a plant canopy parameter that has drawn considerable attention because of the predicted improvement in photosynthetic efficiency and reduction in plant stress afforded by the redistribution of solar radiation from upper to lower levels of canopies (Tollenaar and Wu 1999;Duvick 2005;Murchie et al. 2009;Zhu et al. 2010;Murchie and Reynolds 2012;Drewry et al. 2014;Mansfield and Mumm 2014). Performance improvements predicted by theoretical models are corroborated by positive correlations between small leaf angles and cereal crop yields; post-green revolution rice cultivars have smaller leaf inclination angles and higher yields relative to their pre-green revolution predecessors (Yoshida 1972;Sinclair and Sheehy 1999;Sakamoto et al. 2006), and modern maize is also characterized by small inclination angles as a consequence of selection for increased grain yield in breeding programs (Duvick 2005;Lee and Tollenaar 2007;Hammer et al. 2009;Tian et al. 2011;Mansfield and Mumm 2014).Despite the association of leaf angle with increased productivity, its g...

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Rice leaf inclination2, a VIN3-like protein, regulates leaf angle through modulating cell division of the collar

Cited by 148 publications

References 46 publications

The Binding Specificity of the PHD-Finger Domain of VIN3 Moderates Vernalization Response

The Binding Specificity of the PHD-Finger Domain of VIN3 Moderates Vernalization Response

Dynamic Cytology and Transcriptional Regulation of Rice Lamina Joint Development

Harnessing Genetic Variation in Leaf Angle to Increase Productivity of Sorghum bicolor

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