Presentation is loading. Please wait.

Presentation is loading. Please wait.

Volume 6, Issue 6, Pages (November 2013)

Published byCharla Norton Modified over 5 years ago

Similar presentations

Presentation on theme: "Volume 6, Issue 6, Pages (November 2013)"— Presentation transcript:

1 Volume 6, Issue 6, Pages 1945-1960 (November 2013)
Control of Rice Embryo Development, Shoot Apical Meristem Maintenance, and Grain Yield by a Novel Cytochrome P450  Weibing Yang, Mingjun Gao, Xin Yin, Jiyun Liu, Yonghan Xu, Longjun Zeng, Qun Li, Shubiao Zhang, Junmin Wang, Xiaoming Zhang, Zuhua He  Molecular Plant  Volume 6, Issue 6, Pages (November 2013) DOI: /mp/sst107 Copyright © 2013 The Authors. All rights reserved. Terms and Conditions

2 Figure 1 Characterization of ge Mutant.
(A) Morphology of wild-type (WT) and ge seeds during grain filling stages. DAP, days after pollination. The gray dots indicate the interface of embryo and endosperm. Bar = 1mm. (B) Comparison of mature seed between WT (left) and ge (right). Bar = 1mm. (C–E) Statistical analysis of embryo area (C), endosperm area (D), and embryo/endosperm ratio (E). The data were presented as means ± SE (n > 90) and statistically analyzed by Student’s t-test (P < 0.01). Molecular Plant 2013 6, DOI: ( /mp/sst107) Copyright © 2013 The Authors. All rights reserved. Terms and Conditions

3 Figure 2 Morphogenesis of Wild-Type and ge Embryos.
(A–H) Sections of wild-type (WT) (A–D) and ge (E–H) embryos during developmental stages. (A, B, E, F): Bar = 50 μm. (C, D, G, H): Bar = 100 μm. (I, J) Morphology of WT (I) and ge (J) scutellum epithelial cells. Bar = 10 μm. (K, L) Morphology of WT (K) and ge (L) scutellum parenchyma cells. Bar = 10 μm. (M) Statistical analysis of scutellum parenchyma cell size (n > 150, P < 0.01). (N) Calculated number of scutellum cells (n = 8). (O, P) In situ hybridization analysis of rice histone H4 expression during WT (O) and ge (P) embryo development. 3, 5, and 7 DAP embryos: Bar = 50 μm. 10 DAP embryo: Bar = 100 μm. Molecular Plant 2013 6, DOI: ( /mp/sst107) Copyright © 2013 The Authors. All rights reserved. Terms and Conditions

4 Figure 3 GE Is Required for Shoot Apical Meristem (SAM) Maintenance.
(A–C) Nine-day-old seedlings of wild-type (WT) (A) and ge (B, C). White arrows indicate calluses formed in ge seedlings. Bar = 2mm. (D–F) Longitudinal sections of WT (D) and ge (E, F) seedlings. SAMs are indicated by black arrows. Bar = 100 μm. (G–I) OSH1 expression in WT (G) and ge (H, I) SAMs. SAM boundary is marked by black dots. (J–L) H4 expression in WT (J) and ge (K, L) SAMs. SAM boundary is marked by white dots. Molecular Plant 2013 6, DOI: ( /mp/sst107) Copyright © 2013 The Authors. All rights reserved. Terms and Conditions

5 Figure 4 Map-Based Cloning of GE Gene and Subcellular Localization of GE Protein. (A) Segregation of large embryo and normal embryo seeds in F2 plants. (B) Seeds produced by different crosses between wild-type and ge. (C) Fine mapping of GE gene and characterization of the ge mutation. (D, E) Complementation analysis of ge mutant. (F–I) Co-localization of GE-GFP (F) and RFP-HDEL (G), an endoplasmic reticulum (ER) marker, in rice protoplast. Molecular Plant 2013 6, DOI: ( /mp/sst107) Copyright © 2013 The Authors. All rights reserved. Terms and Conditions

6 Figure 5 Expression Pattern of GE.
(A–E) In situ hybridization analysis of GE expression in rice developmental embryos. (F) GE expression pattern in the growing seeds of pGE::GUS transgenic plants, as revealed by GUS staining. (G) GE expression pattern in 10 DAP seed of pGE::Venus plant, as determined by YFP fluorescence microscopy analysis. Molecular Plant 2013 6, DOI: ( /mp/sst107) Copyright © 2013 The Authors. All rights reserved. Terms and Conditions

7 Figure 6 GE Promoted Cell Proliferation and Plant Growth.
(A) Confirmation of GE overexpression in transgenic plants by quantitative RT–PCR and RT–PCR. For quantitative RT–PCR, the rice Actin1 gene was used as an internal control. Error bars, SD (n = 3). For RT–PCR, rice UBI1was used as an internal control and 36 cycles were performed for GE with 26 cycles for UBI1. (B) Phenotype of 45-day-old wild-type (WT) and GE overexpression plants. Bar = 2cm. (C) Leaves of WT and GE overexpression plants. Bar = 1cm. (D) Morphology of leaf epidermis cells of WT and GE overexpression plants. Bar = 50 μm. (E, F) Statistical analysis of leaf length (E) (n = 24, P < 0.01) and epidermis cell length (F) (n > 300). (G) Quantitative RT–PCR analysis of cell cycle marker genes in leaves of WT and GE overexpression plants. The rice Actin1 gene was used as an internal control. Error bars, SD (n = 3). Molecular Plant 2013 6, DOI: ( /mp/sst107) Copyright © 2013 The Authors. All rights reserved. Terms and Conditions

8 Figure 7 GE Overexpression Enhanced Rice Grain Yield.
(A, B) Morphology of wild-type (WT) (A) and GE OE-12 (B) spikelet hull. Bar = 1mm. (C, D) Cross-section of WT (C) and GE OE-12 (D) hull. Bar = 1mm. (E, F) Morphology of WT (E) and GE OE-12 (F) cells. Bar = 25 μm. (G) Statistical analysis of hull cell size (n > 180, P < 0.01). (H) Calculated number of hull cells (n = 8). (I, J) GE overexpression increased transcript levels of cell cycle marker genes in young panicles (2–4cm). The expression levels were normalized to rice Actin1 gene and expressed relative to the WT. (K) Grains of WT and GE overexpression plants. Bar = 1mm. (L) 1000-grain weight of WT and GE overexpression seeds (n = 24). (M–O) Quantitative RT–PCR analysis of rice yield-related gene expression, including GS5 (M), GW8/OsSPL16 (N), and OsSPL14/IPA1/WFP (O) in WT and GE-OE panicles. The rice Actin1 gene was used as an internal control. Error bars, SD (n = 3). Molecular Plant 2013 6, DOI: ( /mp/sst107) Copyright © 2013 The Authors. All rights reserved. Terms and Conditions

9 Figure 8 GE Restricted Embryo Growth.
(A, B) Seeds of wild-type (WT) (A) and GE OE-9 (B) plants. Bar = 1mm. (C, D) Detection of GE transcripts in WT (C) and GE OE-9 (D) by in situ hybridization. Black arrows indicate the expression of GE in scutellar epithelium. (E, F) Sections of WT (E) and GE OE-12 (F) mature embryos. Bar = 100 μm. (G–I) Statistical analysis of embryo area (G), endosperm area (H), and embryo/endosperm ratio (I) (n > 80, P < 0.01). Molecular Plant 2013 6, DOI: ( /mp/sst107) Copyright © 2013 The Authors. All rights reserved. Terms and Conditions

10 Figure 9 Analysis of CYP78A10 in Arabidopsis.
(A) Phylogenetic analysis of GE and Arabidopsis CYP78A family members. Numbers in branches indicate bootstrap values (percent). (B) CYP78A10 expression in seeds of pCYP78A10::Venus transgenic plants. Bar = 100 μm. (C) Expression levels of CYP78A10 in different transgenic lines by quantitative RT–PCR analysis. The Arabidopsis Actin2 gene was used as an internal control. Error bars, SD (n = 3). (D) Seed morphology of Col-0 and CYP78A10 overexpression plants. Bar = 100 μm. (E, F) Statistical analysis of seed area (E) (n > 400, P < 001) and seed weight (F) (n = 8, P < 001). Molecular Plant 2013 6, DOI: ( /mp/sst107) Copyright © 2013 The Authors. All rights reserved. Terms and Conditions

Download ppt "Volume 6, Issue 6, Pages (November 2013)"

Similar presentations

Figure S1. Figure S1. Relative expression levels of YUC family member transcripts in roots under high and low N conditions. Seedlings 4 days after germination.

Figure S1. Figure S1. Relative expression levels of YUC family member transcripts in roots under high and low N conditions. Seedlings 4 days after germination.
Cui-Cui Zhang, Wen-Ya Yuan, Qi-Fa Zhang  Molecular Plant 

Cui-Cui Zhang, Wen-Ya Yuan, Qi-Fa Zhang  Molecular Plant 
Potassium Transporter KUP7 Is Involved in K+ Acquisition and Translocation in Arabidopsis Root under K+-Limited Conditions  Min Han, Wei Wu, Wei-Hua Wu,

Potassium Transporter KUP7 Is Involved in K+ Acquisition and Translocation in Arabidopsis Root under K+-Limited Conditions  Min Han, Wei Wu, Wei-Hua Wu,
A Histone H3 Lysine-27 Methyltransferase Complex Represses Lateral Root Formation in Arabidopsis thaliana  Gu Xiaofeng , Xu Tongda , He Yuehui   Molecular.

A Histone H3 Lysine-27 Methyltransferase Complex Represses Lateral Root Formation in Arabidopsis thaliana  Gu Xiaofeng , Xu Tongda , He Yuehui   Molecular.
Rice Male Development under Drought Stress: Phenotypic Changes and Stage- Dependent Transcriptomic Reprogramming  Yue Jin, Hongxing Yang, Zheng Wei, Hong.

Rice Male Development under Drought Stress: Phenotypic Changes and Stage- Dependent Transcriptomic Reprogramming  Yue Jin, Hongxing Yang, Zheng Wei, Hong.
The Mitochondrion-Targeted PENTATRICOPEPTIDE REPEAT78 Protein Is Required for nad5 Mature mRNA Stability and Seed Development in Maize  Ya-Feng Zhang,

The Mitochondrion-Targeted PENTATRICOPEPTIDE REPEAT78 Protein Is Required for nad5 Mature mRNA Stability and Seed Development in Maize  Ya-Feng Zhang,
Volume 5, Issue 1, Pages (January 2012)

Volume 5, Issue 1, Pages (January 2012)
Spatial Auxin Signaling Controls Leaf Flattening in Arabidopsis

Spatial Auxin Signaling Controls Leaf Flattening in Arabidopsis
Volume 4, Issue 2, Pages (March 2011)

Volume 4, Issue 2, Pages (March 2011)
Volume 10, Issue 3, Pages (March 2017)

Volume 10, Issue 3, Pages (March 2017)
Volume 7, Issue 8, Pages (August 2014)

Volume 7, Issue 8, Pages (August 2014)
Volume 4, Issue 1, Pages (January 2011)

Volume 4, Issue 1, Pages (January 2011)
A Rare Allele of GS2 Enhances Grain Size and Grain Yield in Rice

A Rare Allele of GS2 Enhances Grain Size and Grain Yield in Rice
Volume 8, Issue 11, Pages (November 2015)

Volume 8, Issue 11, Pages (November 2015)
Volume 10, Issue 11, Pages (March 2015)

Volume 10, Issue 11, Pages (March 2015)
Annexin5 Is Essential for Pollen Development in Arabidopsis

Annexin5 Is Essential for Pollen Development in Arabidopsis
Zhongjuan Zhang, Elise Tucker, Marita Hermann, Thomas Laux 

Zhongjuan Zhang, Elise Tucker, Marita Hermann, Thomas Laux 
Volume 27, Issue 1, Pages (October 2013)

Volume 27, Issue 1, Pages (October 2013)
Volume 5, Issue 2, Pages (March 2012)

Volume 5, Issue 2, Pages (March 2012)
Volume 10, Issue 5, Pages (May 2017)

Volume 10, Issue 5, Pages (May 2017)

Similar presentations

Ads by Google