Your search keyword '"Changzheng Xu"' showing total 14 results

1. Membralin is required for maize development and defines a branch of the endoplasmic reticulum-associated degradation pathway in plants.

Author

Baiyu Liu, Changzheng Xu, Qiuxia He, Ke Zhang, Shoumei Qi, Zhe Jina, Wen Cheng, Zhaohua Ding, Donghua Chen, Xiangyu Zhao, Wei Zhang, Kewei Zhang, and Kunpeng Li

Subjects

UNFOLDED protein response, CORN, GENETIC engineering, RAPESEED, LEAF development, ROOT development

Abstract

Endoplasmic reticulum (ER)-associated degradation (ERAD) plays key roles in controlling protein levels and quality in eukaryotes. The Ring Finger Protein 185 (RNF185)/membralin ubiquitin ligase complex was recently identified as a branch in mammals and is essential for neuronal function, but its function in plant development is unknown. Here, we report the map-based cloning and characterization of Narrow Leaf and Dwarfism 1 (NLD1), which encodes the ER membrane-localized protein membralin and specifically interacts with maize homologs of RNF185 and related components. The nld1 mutant shows defective leaf and root development due to reduced cell number. The defects of nld1 were largely restored by expressing membralin genes from Arabidopsis thaliana and mice, highlighting the conserved roles of membralin proteins in animals and plants. The excessive accumulation of ß-hydroxy ß-methylglutaryl-CoA reductase in nld1 indicates that the enzyme is a membralin-mediated ERAD target. The activation of bZIP60 mRNA splicing-related unfolded protein response signaling and marker gene expression in nld1, as well as DNA fragment and cell viability assays, indicate that membralin deficiency induces ER stress and cell death in maize, thereby affecting organogenesis. Our findings uncover the conserved, indispensable role of the membralin-mediated branch of the ERAD pathway in plants. In addition, ZmNLD1 contributes to plant architecture in a dose-dependent manner, which can serve as a potential target for genetic engineering to shape ideal plant architecture, thereby enhancing high-density maize yields. [ABSTRACT FROM AUTHOR]

Published

2024

2. Editorial: Contribution of phenylpropanoid metabolism to plant development and stress responses.

Author

Chaofeng Li, Yuanzhong Jiang, Changzheng Xu, and Xiupeng Mei

Subjects

LIFE sciences, BOTANY, TRANSCRIPTION factors, PLANT metabolism, PLANT cell walls, CASSAVA

Abstract

This document is an editorial published in the journal Frontiers in Plant Science. It discusses the contribution of phenylpropanoid metabolism to plant development and stress responses. Phenylpropanoids are specialized secondary metabolites in plants that play a role in various processes such as organ pigmentation, plant-microbe interactions, and protection against pathogens. The editorial highlights several research articles that explore the molecular regulatory mechanisms of lignin biosynthesis, the effects of extreme weather events on phenylpropanoid compounds, and the use of multi-omics studies to understand plant growth and development. The authors emphasize the importance of interdisciplinary collaboration in unraveling the complexity of metabolic regulatory networks in plants. [Extracted from the article]

Published

2024

3. AUXIN RESPONSE FACTOR7 integrates gibberellin and auxin signaling via interactions between DELLA and AUX/IAA proteins to regulate cambial activity in poplar.

Author

Jian Hu, Huili Su, Hui Cao, Hongbin Wei, Xiaokang Fu, Xuemei Jiang, Qin Song, Xinhua He, Changzheng Xu, and Keming Luo

Published

2022

4. The MicroRNA390/TRANS-ACTING SHORT INTERFERING RNA3 Module Mediates Lateral Root Growth under Salt Stress via the Auxin Pathway.

Author

Fu He, Changzheng Xu, Xiaokang Fu, Yun Shen, Li Guo, Mi Leng, and Keming Luo

Published

2018

5. PtoMYB170 positively regulates lignin deposition during wood formation in poplar and confers drought tolerance in transgenic Arabidopsis.

Author

Changzheng Xu, Xiaokang Fu, Rui Liu, Li Guo, Lingyu Ran, Chaofeng Li, Qiaoyan Tian, Bo Jiao, Bangjun Wang, and Keming Luo

Subjects

LIGNINS, POPLAR tree diseases & pests, DROUGHT tolerance, ARABIDOPSIS, TRANSGENIC plants, CRISPRS, PLANT genetics

Abstract

Wood formation is a complex developmental process under multi-level transcriptional control executed by a large set of transcription factors. However, only limited members have been characterized to be key regulators of lignin biosynthesis in poplar. Here we report the conserved and unique functions of PtoMYB170, a transcription factor identified from Populus tomentosa (Chinese white poplar), in lignin deposition and drought tolerance in comparison with its duplicate paralog PtoMYB216. PtoMYB170 is preferentially expressed in young leaves and xylem tissues. Overexpression of PtoMYB170 in transgenic poplar plants resulted in stronger lignification and more thickened secondary wall in xylem compared with wild-type plants, whereas the CRISPR/Cas9- generated mutation of PtoMYB170 weakened lignin deposition, thereby leading to a more flexible and collapsed xylem phenotype. Transient expression experiments demonstrated that PtoMYB170 specifically activated the expression of lignin biosynthetic genes, consistent with the function of PtoMYB216. However, GUS staining assays revealed that PtoMYB170 was specifically expressed in guard cells of transgenic Arabidopsis while PtoMYB216 was not. Heterologous expression of PtoMYB170 in Arabidopsis enhanced stomatal closure in the dark and resulted in drought tolerance of the transgenic plants through reduced water loss, indicating a diversified role from PtoMYB216. These results revealed the PtoMYB170-dependent positive transcriptional regulation on lignin deposition in poplar and its coordinated function in enhancing drought tolerance by promoting darkinduced stomatal closure. [ABSTRACT FROM AUTHOR]

Published

2017

6. A new method based on cluster analysis for solving one-dimensional parabolic equations.

Author

Changzheng Xu, Linlin Chen, Cheng Liu, and Jing Chen

Published

2015

7. Identification of a 467 bp Promoter of Maize Phosphatidylinositol Synthase Gene (ZmPIS) Which Confers High-Level Gene Expression and Salinity or Osmotic Stress Inducibility in Transgenic Tobacco.

Author

Hongli Zhang, Jiajia Hou, Pingping Jiang, Shoumei Qi, Changzheng Xu, Qiuxia He, Zhaohua Ding, Zhiwu Wang, Kewei Zhang, and Kunpeng Li

Subjects

PROMOTERS (Genetics), CORN genetics, ABIOTIC stress

Abstract

Salinity and drought often affect plant growth and crop yields. Cloning and identification of salinity and drought stress inducible promoters is of great significance for their use in the genetic improvement of crop resistance. Previous studies showed that phosphatidylinositol synthase is involved in plant salinity and drought stress responses but its promoter has not been characterized by far. In the study, the promoter (pZmPIS, 1834 bp upstream region of the translation initiation site) was isolated from maize genome. To functionally validate the promoter, eight 5 deletion fragments of pZmPIS in different lengths were fused to GUS to produce pZmPIS::GUS constructs and transformed into tobacco, namely PZ1-PZ8. The transcription activity and expression pattern obviously changed when the promoter was truncated. Previous studies have demonstrated that NaCl and PEG treatments are usually used to simulate salinity and drought treatments. The results showed that PZ1-PZ7 can respond well upon NaCl and PEG treatments, while PZ8 not. PZ7 (467 bp) displayed the highest transcription activity in all tissues of transgenic tobacco amongst 5 deleted promoter fragments, which corresponds to about 20 and 50% of CaMV35S under normal and NaCl or PEG treatment, respectively. This implied that PZ7 is the core region of pZmPIS which confers high-level gene expression and NaCl or PEG inducible nature. The 113 bp segment between PZ7 and PZ8 (-467 to -355 bp) was considered as the key sequence for ZmPIS responding to NaCl or PEG treatment. GUS transient assay in tobacco leaves showed that this segment was sufficient for the NaCl or PEG stress response. Bioinformatic analysis revealed that the 113 bp sequence may contain new elements that are crucial for ZmPIS response to NaCl or PEG stress. These results promote our understanding on transcriptional regulation mechanism of ZmPIS and the characterized PZ7 promoter fragment would be an ideal candidate for the overexpression of drought and salinity responsive gene to improve crop resistance. [ABSTRACT FROM AUTHOR]

Published

2016

8. Concept Alignment in Attribute Based Access Control.

Author

Tianyang Zhou, Qingxian Wang, and Changzheng Xu

Published

2010

9. Towards Semantic Matching of Attributes in Multi-domain Access Control.

Author

Ke Ke, Ou Li, and Changzheng Xu

Published

2010

10. Temporal Access Control Based on Multiple Subjects.

Author

Changzheng Xu, Qingxian Wang, Weiming Zhang, and Yali Ding

Published

2009

11. A Novel Trust Model Based on Temporal Historical Data for Access Control.

Author

Changzheng Xu, Yaqi Wang, Qiang Wei, and Qingxian Wang

Published

2009

12. Molecular interactions of ROOTLESS CONCERNING CROWN AND SEMINAL ROOTS, a LOB domain protein regulating shoot-borne root initiation in maize (Zea mays L.).

Author

Majer, Christine, Changzheng Xu, Berendzen, Kenneth W., and Hochholdinger, Frank

Subjects

CORN research, PLANT roots, CYTOPLASM, AUXIN, ELECTROPHORESIS

Abstract

Rootless concerning crown and seminal roots (Rtcs) encodes a LATERAL ORGAN BOUNDARIES domain (LBD) protein that regulates shoot-borne root initiation in maize (Zea mays L.). GREEN FLUORESCENT PROTEIN (GFP)-fusions revealed RTCS localization in the nucleus while its paralogue RTCS-LIKE (RTCL) was detected in the nucleus and cytoplasm probably owing to an amino acid exchange in a nuclear localization signal. Moreover, enzyme-linked immunosorbent assay (ELISA) experiments demonstrated that RTCS primarily binds to LBD DNA motifs. RTCS binding to an LBD motif in the promoter of the auxin response factor (ARF) ZmArf34 and reciprocally, reciprocal ZmARF34 binding to an auxin responsive element motif in the promoter of Rtcs was shown by electrophoretic mobility shift assay experiments. In addition, comparative qRT-PCR of wild-type versus rtcs coleoptilar nodes suggested RTCS-dependent activation of ZmArf34 expression. Consistently, luciferase reporter assays illustrated the capacity of RTCS, RTCL and ZmARF34 to activate downstream gene expression. Finally, RTCL homo- and RTCS/RTCL hetero-interaction were demonstrated in yeast-two-hybrid and bimolecular fluorescence complementation experiments, suggesting a role of these complexes in downstream gene regulation. In summary, the data provide novel insights into the molecular interactions resulting in crown root initiation in maize. [ABSTRACT FROM AUTHOR]

Published

2012

13. Phosphate starvation of maize inhibits lateral root formation and alters gene expression in the lateral root primordium zone.

Author

Zhaoxia Li, Changzheng Xu, Kunpeng Li, Shi Yan, Xun Qu, and Juren Zhang

Subjects

PLANT hormones, GENE expression, BIOCHEMISTRY, CORN, FERTILIZERS

Abstract

Background: Phosphorus (P) is an essential macronutrient for all living organisms. Maize (Zea mays) is an important human food, animal feed and energy crop throughout the world, and enormous quantities of phosphate fertilizer are required for maize cultivation. Thus, it is important to improve the efficiency of the use of phosphate fertilizer for maize. Results: In this study, we analyzed the maize root response to phosphate starvation and performed a transcriptomic analysis of the 1.0-1.5 cm lateral root primordium zone. In the growth of plants, the root-to-shoot ratio (R/L) was reduced in both low-phosphate (LP) and sufficient-phosphate (SP) solutions, but the ratio (R/L) exhibited by the plants in the LP solution was higher than that of the SP plants. The growth of primary roots was slightly promoted after 6 days of phosphate starvation, whereas the numbers of lateral roots and lateral root primordia were significantly reduced, and these differences were increased when associated with the stress caused by phosphate starvation. Among the results of a transcriptomic analysis of the maize lateral root primordium zone, there were two highlights: 1) auxin signaling participated in the response and the modification of root morphology under low-phosphate conditions, which may occur via local concentration changes due to the biosynthesis and transport of auxin, and LOB domain proteins may be an intermediary between auxin signaling and root morphology; and 2) the observed retardation of lateral root development was the result of co-regulation of DNA replication, transcription, protein synthesis and degradation and cell growth. Conclusions: These results indicated that maize roots show a different growth pattern than Arabidopsis under low-phosphate conditions, as the latter species has been observed to halt primary root growth when the root tip comes into contact with low-phosphate media. Moreover, our findings enrich our understanding of plant responses to phosphate deficits and of root morphogenesis in maize. [ABSTRACT FROM AUTHOR]

Published

2012

14. Comparative proteome analyses of phosphorus responses in maize ( Zea mays L.) roots of wild-type and a low-P-tolerant mutant reveal root characteristics associated with phosphorus efficiency.

Author

Kunpeng Li, Changzheng Xu, Zhaoxia Li, Kewei Zhang, Aifang Yang, and Juren Zhang

Subjects

CORN, PLANT growth, PLANT development, PHOSPHORUS, PLANT cells & tissues, CELL proliferation, PLANTS

Abstract

Low phosphorus (P) availability is a major limitation for plant growth. To better understand the molecular mechanism of P efficiency in maize, comparative proteome analyses were performed on the roots of the low-P-tolerant mutant 99038 and wild-type Qi-319 grown under P-sufficient (+P) or P-deficient (−P) conditions. Over 10% of proteins detected on two-dimensional electrophoresis (2-DE) gels showed expression that was altered twofold or more between the genotypes under +P or −P conditions. We identified 73 (+P) and 95 (−P) differentially expressed proteins in response to phosphate (Pi) starvation. These proteins were involved in a large number of cellular and metabolic processes, with an obvious functional skew toward carbon metabolism and regulation of cell proliferation. Further analysis of proteome data, physiological measurements and cell morphological observations showed that, compared to the wild-type, the low-P-tolerant mutant could accumulate and secrete more citrate under Pi starvation, which facilitates solubilization of soil Pi and enhances Pi absorption. The proportion of sucrose in the total soluble sugars of the low-P-tolerant mutant was significantly higher, and cell proliferation in root meristem was accelerated. This resulted in better developed roots and more advantageous root morphology for Pi uptake. These results indicate that differences in citrate secretion, sugar metabolism and root-cell proliferation are the main reasons for higher tolerance to low-P conditions in the mutant compared to the wild-type. Thus, the mutant displayed specialized P-efficient root systems with a higher capacity for mobilization of external Pi and increased cell division in the root meristem under Pi starvation. [ABSTRACT FROM AUTHOR]

Published

2008