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2015年 第57卷 第3期 刊出日期：2015-03-01

2015年 第57卷 第3期
刊出日期：2015-03-01

  

AUXIN BINDING PROTEIN 1 (ABP1): A matter of fact

Chun-Ming Liu

2015, 57(3):  234-235.  doi:10.1111/jipb.12339

摘要 ( 2428 )  

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A putative plant organelle RNA recognition protein gene is essential for maize kernel development

Antony M. Chettoor, Gibum Yi, Elisa Gomez, Gregorio Hueros, Robert B. Meeley, and Philip W. Becraft

2015, 57(3):  236-246.  doi:10.1111/jipb.12234

摘要 ( 2060 )  

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A mutation in a maize gene encoding a mitochondrial protein causes seed lethality showing it is essential for grain development. Defects in transfer cells suggest either that this cell type has a particularly high energy requirement or that mitochondria could provide functions required for specific developmental processes.

Organ-specific effects of brassinosteroids on stomatal production coordinate with the action of TOO MANY MOUTHS

Ming Wang, Kezhen Yang, and Jie Le

2015, 57(3):  247-255.  doi:10.1111/jipb.12285

摘要 ( 2606 )  

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Brassinosteroid (BR) has been shown organ-specific effects in control stomatal production. Mutation of TOO MANY MOUTHS (TMM) leads stomatal clusters in cotyledons but no stomata in hypocotyls. Here, Wang et al. found that BR induced stomatal clusters in tmm hypocotyls, indicating a crosstalk between BR- and TMM-mediated signaling pathways.

Identification of mRNA-like non-coding RNAs and validation of a mighty one named MAR in Panax ginseng

Meizhen Wang, Bin Wu, Chao Chen and Shanfa Lu

2015, 57(3):  256-270.  doi:10.1111/jipb.12239

摘要 ( 2379 )  

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MlncRNAs are a class of lncRNAs playing vital roles in plants. Through an integrative analysis of transcriptome, sRNAome and degradome, 3688 mlncRNAs were identified and characterized in Panax ginseng. One of them, termed MAR, was found to play significant regulatory roles in multiple metabolic pathways in a small RNA-dependent manner.

ZmGns, a maize class I β-1,3-glucanase, is induced by biotic stresses and possesses strong antimicrobial activity

Yu-Rong Xie, Yenjit Raruang, Zhi-Yuan Chen, Robert L. Brown, and Thomas E. Cleveland

2015, 57(3):  271-283.  doi:10.1111/jipb.12286

摘要 ( 2446 )  

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ZmGns, a maize glucanase, shows strong antifungal and antibacterial activity in vivo and in vitro. ZmGns also plays great roles in maize growth and development by response to growth hormones such as salicylic acid. In addition, ZmGns was up-regulated when exposed to abiotic stresses including salinity, wound and copper.

Population transcriptomics reveals a potentially positive role of expression diversity in adaptation

Qin Xu, Shilai Xing, Caiyun Zhu, Wei Liu, Yangyang Fan, Qian Wang, Zhihong Song, Wenhui Yang, Fan Luo, Fei Shang, Lifang Kang, Wenli Chen, Juan Yan, Jianqiang Li, and Tao Sang

2015, 57(3):  284-299.  doi:10.1111/jipb.12287

摘要 ( 3181 )  

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This study shows that the increase in variation of gene expression, while a population being exposed to a new stressful environment, may enhance its adaptability, when has implications in the domestication of new energy crops, control of invasive species, and conservation of biodiversity during climate change.

The regulatory network mediated by circadian clock genes is related to heterosis in rice

Guojing Shen, Wei Hu, Bo Zhang and Yongzhong Xing

2015, 57(3):  300-312.  doi:10.1111/jipb.12240

摘要 ( 2658 )  

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Heterosis is a common phenomenon in plants, which greatly contributes to global food security. Circadian clock is a biochemical mechanism in organisms that coordinates their biology and behavior with daily and seasonal changes. We found the circadian rhythm is highly associated with the magnitude of heterosis.

The CONSTANS-like 4 transcription factor, AtCOL4, positively regulates abiotic stress tolerance through an abscisic acid-dependent manner in Arabidopsis

Ji-Hee Min, Jung-Sung Chung, Kyeong-Hwan Lee, and Cheol Soo Kim

2015, 57(3):  313-324.  doi:10.1111/jipb.12246

摘要 ( 3388 )  

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The overexpression of AtCOL4 in Arabidopsis plants conferred increased insensitivity to ABA and salt stress, while atcol4 mutant gained sensitivity to ABA and high salinity condition during seed germination and the cotyledon greening process.