Your search keyword '"Liu, Guolan"' showing total 5 results

1. Mutation of DEP1 facilitates the improvement of plant architecture in Xian rice (Oryza sativa).

Author

Zhang, Anning, Wang, Feiming, Kong, Deyan, Hou, Danping, Huang, Leda, Bi, Junguo, Zhang, Fenyun, Luo, Xingxing, Wang, Jiahong, Liu, Guolan, Yu, Xinqiao, Liu, Yi, and Luo, Lijun

Subjects

GENETIC mutation, CRISPRS, PLANT regulators, RICE, PHENOTYPES, GRAIN size

Abstract

Plant architecture is a complex trait and has a profound impact on crop performance and productivity. We applied the CRISPR/Cas9 system to mutate the DEP1 gene, which has been reported to function as regulator of plant architecture, in elite Xian cultivar 'Huhan1509'. Sequencing analysis of T0 transformed plants showed that the CRISPR/Cas9 system was highly efficient in mutagenesis of targeted DEP1 gene, with 30% of the homozygous mutations and 70% of the heterozygous mutations. T2 homozygous mutants without T‐DNA were further examined for the agronomic traits. The DEP1 mutants exhibited an altered plant architecture along with a shorter plant height and grain size and increased spikelets and grain density. Furthermore, phenotypes of raising primary branches and stem diameters were observed in the DEP1 mutants. Our results demonstrate that favourable alleles of the DEP1 gene, developed by CRISPR/Cas9 system, could be used to improve plant architecture in Xian rice. [ABSTRACT FROM AUTHOR]

Published

2023

2. Transcriptomic divergence between upland and lowland ecotypes contributes to rice adaptation to a drought‐prone agroecosystem.

Author

Luo, Zhi, Xiong, Jie, Xia, Hui, Ma, Xiaosong, Gao, Min, Wang, Lei, Liu, Guolan, Yu, Xinqiao, and Luo, Lijun

Subjects

UPLAND rice, RICE, SWITCHGRASS, DROUGHT tolerance, UPLANDS, PLANT adaptation, DROUGHT management

Abstract

Introduction: Transcriptomic divergence drives plant ecological adaptation. Upland rice is differentiated in drought tolerance from lowland rice during its adaptation to the drought‐prone environment. They provide a good system to learn the evolution of drought tolerance in rice. Methods and Results: We estimate morphological differences between the two rice ecotypes under well‐watered and drought conditions, as well as their genetic and transcriptomic divergences by the high‐throughput sequencing. Upland rice possesses higher expression diversity than lowland rice does. Thousands of genes exhibit expression divergences between the two rice ecotypes, which contributes to their morphological differences in drought tolerance. These transcriptomic divergences contribute to drought adaptation of upland rice during its domestication. Mutations in transcriptional regulatory regions, which cause presence and absence of cis‐elements, are the cause of expression divergence. About 15.3% transcriptionally selected genes also receive sequence‐based selection in upland or lowland ecotype. Some highly differentiated genes promote the transcriptomic divergence between rice ecotypes via gene co‐expression network. In addition, we also detected transcriptomic trade‐offs between drought tolerance and productivity. Discussion: Many key genes, which promote transcriptomic adaptation to drought in upland rice, have great prospective in breeding water‐saving and drought‐resistant rice. Meanwhile, appropriate strategies are required in breeding to overcome the potential transcriptomic trade‐off. [ABSTRACT FROM AUTHOR]

Published

2020

3. Cystathionine beta‐lyase is crucial for embryo patterning and the maintenance of root stem cell niche in Arabidopsis.

Author

Liu, Guolan, Yang, Weiyuan, Zhang, Xiaojing, Peng, Tao, Zou, Yi, Zhang, Tao, Wang, Hao, Liu, Xuncheng, and Tao, Li‐Zhen

Subjects

*STEM cell niches, *CYSTATHIONINE, *PLANT development, *EMBRYOS, *ROOT growth

Abstract

Summary: The growth and development of roots in plants depends on the specification and maintenance of the root apical meristem. Here, we report the identification of CBL, a gene required for embryo and root development in Arabidopsis, and encodes cystathionine beta‐lyase (CBL), which catalyzes the penultimate step in methionine (Met) biosynthesis, and which also led to the discovery of a previous unknown, but crucial, metabolic contribution by the Met biosynthesis pathway. CBL is expressed in embryos and shows quiescent center (QC)‐enriched expression pattern in the root. cbl mutant has impaired embryo patterning, defective root stem cell niche, stunted root growth, and reduces accumulation of the root master regulators PLETHORA1 (PLT1) and PLT2. Furthermore, mutation in CBL severely decreases abundance of several PIN‐FORMED (PIN) proteins and impairs auxin‐responsive gene expression in the root tip. cbl seedlings also exhibit global reduction in histone H3 Lys‐4 trimethylation (H3K4me3) and DNA methylation. Importantly, mutation in CBL reduces the abundance of H3K4me3 modification in PLT1/2 genes and downregulates their expression. Overexpression of PLT2 partially rescues cbl root meristem defect, suggesting that CBL acts in part through PLT1/2. Moreover, exogenous supplementation of Met also restores the impaired QC activity and the root growth defects of cbl. Taken together, our results highlight the unique role of CBL to maintain the root stem cell niche by cooperative actions between Met biosynthesis and epigenetic modification of key developmental regulators. Significance Statement: Growth and development depend on metabolic activities that properly support fundamental cellular functions, but mechanistic links are scarce. Here, we demonstrate that a quiescent center‐enriched CBL gene, encoding the second committed enzyme in methionine (Met) biosynthesis, plays a crucial role in root apical meristem maintenance by epigenetically influencing expression of the root master regulators PLETHORA (PTL1/2), elucidating a functional link between Met metabolic contribution and auxin‐dependent PLT‐mediated maintenance of root stem cell niche. [ABSTRACT FROM AUTHOR]

Published

2019

4. A Piezo‐Fenton System with Rapid Iron Cycling and Hydrogen Peroxide Self‐Supply Driven by Ultrasound.

Author

Ge, Lin, Xiao, Jie, Liu, Wencheng, Ren, Guolan, Zhou, Chi, Liu, Junan, Zou, Ji‐Jun, and Yang, Zixin

Subjects

HYDROGEN peroxide, HABER-Weiss reaction, ULTRASONIC imaging, HYDROXYL group, CATALYTIC converters for automobiles, EYE tracking

Abstract

The piezo‐Fenton system has attracted attention not only because it can enhance the Fenton reaction activity by mechanical energy input, but also because it is expected to realize a class of stimuli‐responsive advanced oxidation systems by regulating energy input and hydrogen peroxide self‐supply, thus greatly enriching the application possibilities of Fenton chemistry. In this work, a series of Fe‐doped g‐C3N4 (g‐C3N4‐Fe) as a piezo‐Fenton system were synthesized where the iron stably immobilized through Fe−N interaction. The piezo‐induced electrons generate on g‐C3N4 matrix support the conversion of Fe(III) to Fe(II) and promote rate‐limiting step of Fenton reaction. With the optimal Fe loading, g‐C3N4‐0.5Fe can achieve methylene blue (MB) degradation under ultrasonic treatment with first‐order kinetic rate constants of 75×10−3 min−1. Most importantly, the g‐C3N4‐Fe can maintain good catalytic activity in a wide pH range (pH=2.0∼9.0) and be cyclic used without iron leaching to solution (<0.001 μg ⋅ L−1), overcoming the disadvantage of traditional Fe‐based Fenton catalysts that can only be applied under acidic conditions and prone to secondary pollution. In addition, g‐C3N4‐0.5Fe also exhibits antibacterial properties of Escherichia coli and Staphylococcus aureus under ultrasound. Hydroxyl radicals mainly contribute to the degradation of MB and the sterilization process. Our work is an attempt to clarify the role of g‐C3N4‐Fe in the conversion of mechanical energy to ROS and provide inspirations for the piezo‐Fenton system design. [ABSTRACT FROM AUTHOR]

Published

2022

5. A Cleavage‐Modification‐Reassembly Process Catalyzed by Rhodium and Brønsted Acid for the Synthesis of Multi‐Substituted Anilines.

Author

Liu, Xiangrong, Xiao, Guolan, Xu, Xinfang, Kang, Zhenghui, Zhang, Dan, and Hu, Wenhao

Subjects

BRONSTED acids, DIAZO compounds, ANILINE, RHODIUM, SCISSION (Chemistry), RHODIUM compounds, PHOSPHORIC acid, POLYANILINES

Abstract

A synergistic rhodium‐ and Brønsted acid‐ catalyzed reaction of quinone imine ketals with diazo compounds to access multi‐substituted anilines is presented here. This reaction takes place through a process involving C−O bond cleavage, modification of the leaving alcoholic fragment, and selective reassembly of the reactive fragments. Moderate enantioselectivities are achieved when a chiral 1,1'‐bi(2‐naphthol)‐based phosphoric acid is used. [ABSTRACT FROM AUTHOR]

Published

2020