Your search keyword '"Yu, Buzhu"' showing total 10 results

1. SOS2-AFP2 module regulates seed germination by inducing ABI5 degradation in response to salt stress in Arabidopsis

Author

Wang, Chuntao, Wen, Jing, Liu, Yuanyuan, Yu, Buzhu, and Yang, Shuda

Published

2024

2. Comparative profiling of membrane lipids during water stress in Thellungiella salsuginea and its relative Arabidopsis thaliana

Author

Yu, Buzhu and Li, Weiqi

Published

2014

3. Maintenance or Collapse: Responses of Extraplastidic Membrane Lipid Composition to Desiccation in the Resurrection Plant Paraisometrum mileense.

Author

Li, Aihua, Wang, Dandan, Yu, Buzhu, Yu, Xiaomei, and Li, Weiqi

Subjects

PLANT growth, MEMBRANE lipids, DEHYDRATION, PLANT habitats, PLANT physiology, PLANTS

Abstract

Resurrection plants usually grow in specific or extreme habitats and have the capacity to survive almost complete water loss. We characterized the physiological and biochemical responses of Paraisometrum mileense to extreme desiccation and found that it is a resurrection plant. We profiled the changes in lipid molecular species during dehydration and rehydration in P. mileense, and compared these with corresponding changes in the desiccation-sensitive plant Arabidopsis thaliana. One day of desiccation was lethal for A. thaliana but not for P. mileense. After desiccation and subsequent rewatering, A. thaliana showed dramatic lipid degradation accompanied by large increases in levels of phosphatidic acid (PA) and diacylglycerol (DAG). In contrast, desiccation and rewatering of P. mileense significantly decreased the level of monogalactosyldiacylglycerol and increased the unsaturation of membrane lipids, without changing the level of extraplastidic lipids. Lethal desiccation in P. mileense caused massive lipid degradation, whereas the PA content remained at a low level similar to that of fresh leaves. Neither damage nor repair processes, nor increases in PA, occurred during non-lethal desiccation in P. mileense. The activity of phospholipase D, the main source of PA, was much lower in P. mileense than in A. thaliana under control conditions, or after either dehydration or rehydration. It was demonstrated that low rates of phospholipase D-mediated PA formation in P. mileense might limit its ability to degrade lipids to PA, thereby maintaining membrane integrity following desiccation. [ABSTRACT FROM AUTHOR]

Published

2014

4. Acyl Chain Length of Phosphatidylserine Is Correlated with Plant Lifespan.

Author

Li, Yan, Zheng, Guowei, Jia, Yanxia, Yu, Xiaomei, Zhang, Xudong, Yu, Buzhu, Wang, Dandan, Zheng, Yanling, Tian, Xuejun, and Li, Weiqi

Subjects

ACYL group, PHOSPHATIDYLSERINES, PLANT physiology, ENVIRONMENTAL impact analysis, PLANT species, BOTANICAL chemistry, DEVELOPMENTAL biology

Abstract

Plant lifespan is affected by factors with genetic and environmental bases. The laws governing these two factors and how they affect plant lifespan are unclear. Here we show that the acyl chain length (ACL) of phosphatidylserine (PS) is correlated with plant lifespan. Among the detected eight head-group classes of membrane lipids with lipidomics based on triple quadrupole tandem mass spectrometry, the ACL of PS showed high diversity, in contrast to the ACLs of the other seven classes, which were highly conserved over all stages of development in all plant species and organs and under all conditions that we studied. Further investigation found that acyl chains of PS lengthened during development, senescence, and under environmental stresses and that increasing length was accelerated by promoted- senescence. The acyl chains of PS were limited to a certain carbon number and ceased to increase in length when plants were close to death. These findings suggest that the ACL of PS can count plant lifespan and could be a molecular scale ruler for measuring plant development and senescence. [ABSTRACT FROM AUTHOR]

Published

2014

5. Quantitative Profiling of Arabidopsis Polar Glycerolipids under Two Types of Heat Stress.

Author

Qin, Feng, Lin, Liang, Jia, Yanxia, Li, Weiqi, and Yu, Buzhu

Subjects

GLYCEROLIPIDS, HEAT shock proteins, HEAT, MEMBRANE lipids, ARABIDOPSIS

Abstract

At the cellular level, the remodelling of membrane lipids and production of heat shock proteins are the two main strategies whereby plants survive heat stress. Although many studies related to glycerolipids and HSPs under heat stress have been reported separately, detailed alterations of glycerolipids and the role of HSPs in the alterations of glycerolipids still need to be revealed. In this study, we profiled the glycerolipids of wild-type Arabidopsis and its HSP101-deficient mutant hot-1 under two types of heat stress. Our results demonstrated that the alterations of glycerolipids were very similar in wild-type Arabidopsis and hot-1 during heat stress. Although heat acclimation led to a slight decrease of glycerolipids, the decrease of glycerolipids in plants without heat acclimation is more severe under heat shock. The contents of 36:x monogalactosyl diacylglycerol (MGDG) were slightly increased, whereas that of 34:6 MGDG and 34:4 phosphatidylglycerol (PG) were severely decreased during moderate heat stress. Our findings suggested that heat acclimation could reduce the degradation of glycerolipids under heat shock. Synthesis of glycerolipids through the prokaryotic pathway was severely suppressed, whereas that through the eukaryotic pathway was slightly enhanced during moderate heat stress. In addition, HSP101 has a minor effect on the alterations of glycerolipids under heat stress. [ABSTRACT FROM AUTHOR]

Published

2020

6. Maintenance or Collapse: Responses of Extraplastidic Membrane Lipid Composition to Desiccation in the Resurrection Plant Paraisometrum mileense.

Author

Li, Aihua, Wang, Dandan, Yu, Buzhu, Yu, Xiaomei, and Li, Weiqi

Subjects

*PLANT growth, *MEMBRANE lipids, *DEHYDRATION, *PLANT habitats, *PLANT physiology, *PLANTS

Abstract

Resurrection plants usually grow in specific or extreme habitats and have the capacity to survive almost complete water loss. We characterized the physiological and biochemical responses of Paraisometrum mileense to extreme desiccation and found that it is a resurrection plant. We profiled the changes in lipid molecular species during dehydration and rehydration in P. mileense, and compared these with corresponding changes in the desiccation-sensitive plant Arabidopsis thaliana. One day of desiccation was lethal for A. thaliana but not for P. mileense. After desiccation and subsequent rewatering, A. thaliana showed dramatic lipid degradation accompanied by large increases in levels of phosphatidic acid (PA) and diacylglycerol (DAG). In contrast, desiccation and rewatering of P. mileense significantly decreased the level of monogalactosyldiacylglycerol and increased the unsaturation of membrane lipids, without changing the level of extraplastidic lipids. Lethal desiccation in P. mileense caused massive lipid degradation, whereas the PA content remained at a low level similar to that of fresh leaves. Neither damage nor repair processes, nor increases in PA, occurred during non-lethal desiccation in P. mileense. The activity of phospholipase D, the main source of PA, was much lower in P. mileense than in A. thaliana under control conditions, or after either dehydration or rehydration. It was demonstrated that low rates of phospholipase D-mediated PA formation in P. mileense might limit its ability to degrade lipids to PA, thereby maintaining membrane integrity following desiccation. [ABSTRACT FROM AUTHOR]

Published

2014

7. Elevated CO2 enhances growth and differentially affects saponin content in Paris polyphylla var. yunnanensis.

Author

Qiang, Qi, Gao, Yanfen, Yu, Buzhu, Wang, Mulan, Ni, Wei, Li, Shenghong, Zhang, Tie, Li, Weiqi, and Lin, Liang

Subjects

*SAPONINS, *PHOTOSYNTHETIC rates, *DIOSGENIN, *METABOLITES, *INDUSTRIAL capacity, *ATMOSPHERIC carbon dioxide, *BIOACTIVE compounds

Abstract

• Two Paris polyphylla var. yunnanensis cultivars differ in photosynthesis and saponin contents under ambient CO 2. • Short-term responses of western and central Yunnan cultivars to elevated CO 2 show similar patterns but different intensity. • Western Yunnan cultivar shows higher photosynthesis and growth rate than central Yunnan cultivar under elevated CO 2. • The effects of elevated CO 2 on diosgenin and pennogenin contents differ between western and central Yunnan cultivars. • Western Yunnan cultivar is sensitive to elevated CO 2 and is a potential candidate for industrial cultivation in high-CO 2. Paris polyphylla var. yunnanensis produces specific diosgenins and pennogenins of high medicinal value and is an increasingly important industrial biomedical resource. Attempts to meet the strong demand for its secondary metabolites are hampered by its slow growth rate, and in consequence natural populations are increasingly under threat, with increased yields required for large-scale cultivation. The response of P. polyphylla to artificial environmental conditions is therefore of considerable biological and industrial importance. In this study, we characterized the responses of two P. polyphylla cultivars to elevated CO 2. The cultivar WY (western Yunnan), which originated from a cold, dry habitat, showed stronger photosynthetic activity and higher contents of bioactive compounds under ambient CO 2 than the cultivar CY (central Yunnan), which is adapted to a warm, humid habitat. Cultivar WY showed higher photosynthetic activity and enhanced growth compared with CY under elevated CO 2. Contents of the bioactive compound diosgenin of WY increased under elevated CO 2 and thus total saponin content was maintained, consistent with the enhanced growth. The present results suggest that the responses of P. polyphylla cultivars to elevated CO 2 may be due to the effects of their natural habitats. Photosynthesis, growth and diosgenin accumulation in WY are sensitive to elevated CO 2 , implying that WY is a potential candidate for industrial cultivation in a high-CO 2 environment. [ABSTRACT FROM AUTHOR]

Published

2020

8. Identification of the toxin components of Rhizoctonia solani AG1-IA and its destructive effect on plant cell membrane structure.

Author

Xu S, Ren S, Bao W, Li X, Zhang Y, Yu B, Li W, Li C, Dong W, and Yang G

Abstract

Rice sheath blight is a fungal disease caused mainly by Rhizoctonia solani AG1-IA. Toxins are a major pathogenic factor of R. solani , and some studies have reported their toxin components; however, there is no unified conclusion. In this study, we reported the toxin components and their targets that play a role in R. solani AG1-IA. First, toxins produced by R. solani AG1-IA were examined. Several important phytotoxins, including benzoic acid (BZA), 5-hydroxymethyl-2-furanic aid (HFA), and catechol (CAT), were identified by comparative analysis of secondary metabolites from AG1-IA, AG1-IB, and healthy rice. Follow-up studies have shown that the toxin components of this fungus can rapidly disintegrate the biofilm structure while maintaining the content of host plant membrane components, thereby affecting the organelles, which may also explain the lack of varieties highly resistant to sheath blight., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 Xu, Ren, Bao, Li, Zhang, Yu, Li, Li, Dong and Yang.)

Published

2024

9. Heat shock protein 101 (HSP101) promotes flowering under nonstress conditions.

Author

Qin F, Yu B, and Li W

Subjects

Arabidopsis growth & development, Flowers genetics, Plant Proteins metabolism, Transcription Factors metabolism, Arabidopsis genetics, Flowers growth & development, Plant Proteins genetics, Stress, Physiological, Transcription Factors genetics

Abstract

Heat shock proteins (HSPs) are stress-responsive proteins that are conserved across all organisms. Heat shock protein 101 (HSP101) has an important role in thermotolerance owing to its chaperone activity. However, if and how it functions in development under nonstress conditions is not yet known. By using physiological, molecular, and genetic methods, we investigated the role of HSP101 in the control of flowering in Arabidopsis (Arabidopsis thaliana (L.) Heynh.) under nonstress conditions. Knockout and overexpression of HSP101 cause late and early flowering, respectively. Late flowering can be restored by rescue of HSP101. HSP101 regulates the expression of genes involved in the six known flowering pathways; the most negatively regulated genes are FLOWERING LOCUS C (FLC) and SHORT VEGETATIVE PHASE (SVP); downstream integrators of the flowering pathways are positively regulated. The late-flowering phenotype of loss-of-HSP101 mutants is suppressed by both the mutations of FLC and SVP. The responses of flowering time to exogenous signals do not change in HSP101 mutants. HSP101 is also found in nonspecific regions according to subcellular localization. We found that HSP101 promotes flowering under nonstress conditions and that this promotion depends on FLC and SVP. Our data suggest that this promotion could occur through a multiple gene regulation mechanism., (© American Society of Plant Biologists 2021. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2021

10. Maintenance or collapse: responses of extraplastidic membrane lipid composition to desiccation in the resurrection plant Paraisometrum mileense.

Author

Li A, Wang D, Yu B, Yu X, and Li W

Subjects

Arabidopsis chemistry, Arabidopsis metabolism, Arabidopsis physiology, Chlorophyll metabolism, Craterostigma metabolism, Craterostigma physiology, Dehydration, Diglycerides analysis, Malondialdehyde metabolism, Membrane Lipids metabolism, Phosphatidic Acids analysis, Phospholipase D metabolism, Plant Leaves chemistry, Plant Leaves metabolism, Plant Leaves physiology, Proline metabolism, Species Specificity, Sucrose metabolism, Time Factors, Water metabolism, Craterostigma chemistry, Desiccation methods, Membrane Lipids analysis, Stress, Physiological

Abstract

Resurrection plants usually grow in specific or extreme habitats and have the capacity to survive almost complete water loss. We characterized the physiological and biochemical responses of Paraisometrum mileense to extreme desiccation and found that it is a resurrection plant. We profiled the changes in lipid molecular species during dehydration and rehydration in P. mileense, and compared these with corresponding changes in the desiccation-sensitive plant Arabidopsis thaliana. One day of desiccation was lethal for A. thaliana but not for P. mileense. After desiccation and subsequent rewatering, A. thaliana showed dramatic lipid degradation accompanied by large increases in levels of phosphatidic acid (PA) and diacylglycerol (DAG). In contrast, desiccation and rewatering of P. mileense significantly decreased the level of monogalactosyldiacylglycerol and increased the unsaturation of membrane lipids, without changing the level of extraplastidic lipids. Lethal desiccation in P. mileense caused massive lipid degradation, whereas the PA content remained at a low level similar to that of fresh leaves. Neither damage nor repair processes, nor increases in PA, occurred during non-lethal desiccation in P. mileense. The activity of phospholipase D, the main source of PA, was much lower in P. mileense than in A. thaliana under control conditions, or after either dehydration or rehydration. It was demonstrated that low rates of phospholipase D-mediated PA formation in P. mileense might limit its ability to degrade lipids to PA, thereby maintaining membrane integrity following desiccation.

Published

2014