Your search keyword '"Zhu XG"' showing total 13 results

1. Knocking out NEGATIVE REGULATOR OF PHOTOSYNTHESIS 1 increases rice leaf photosynthesis and biomass production in the field.

Author

Chen F, Zheng G, Qu M, Wang Y, Lyu MA, and Zhu XG

Subjects

Biomass, Oryza genetics, Photosynthesis, Plant Leaves physiology, Plant Proteins genetics, Plant Proteins physiology, Transcription Factors genetics, Transcription Factors physiology

Abstract

Improving photosynthesis is a major approach to increasing crop yield potential. Here we identify a transcription factor as a negative regulator of photosynthesis, which can be manipulated to increase rice photosynthesis and plant biomass in the field. This transcription factor, named negative regulator of photosynthesis 1 (NRP1; Os07g0471900), was identified through a co-expression analysis using rice leaf RNA sequencing data. NRP1 expression showed significantly negative correlation with the expression of many genes involved in photosynthesis. Knocking out NRP1 led to greater photosynthesis and increased biomass in the field, while overexpression of NRP1 decreased photosynthesis and biomass. Transcriptomic data analysis shows that NRP1 can negatively regulate the expression of photosynthetic genes. Protein transactivation experiments show that NRP1 is a transcription activator, implying that NRP1 may indirectly regulate photosynthetic gene expression through an unknown regulator. This study shows that combination of bioinformatics analysis with transgenic testing can be used to identify new regulators to improve photosynthetic efficiency in crops., (© The Author(s) 2021. Published by Oxford University Press on behalf of the Society for Experimental Biology. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2021

2. Overexpression of maize transcription factor mEmBP-1 increases photosynthesis, biomass, and yield in rice.

Author

Perveen S, Qu M, Chen F, Essemine J, Khan N, Lyu MA, Chang T, Song Q, Chen GY, and Zhu XG

Subjects

Biomass, Photosynthesis, Transcription Factors, Zea mays genetics, Oryza genetics

Abstract

Identifying new options to improve photosynthetic capacity is a major approach to improve crop yield potential. Here we report that overexpression of the gene encoding the transcription factor mEmBP-1 led to simultaneously increased expression of many genes in photosynthesis, including genes encoding Chl a,b-binding proteins (Lhca and Lhcb), PSII (PsbR3 and PsbW) and PSI reaction center subunits (PsaK and PsaN), chloroplast ATP synthase subunit, electron transport reaction components (Fd1 and PC), and also major genes in the Calvin-Benson-Bassham cycle, including those encoding Rubisco, glyceraldehyde phosphate dehydrogenase, fructose bisphosphate aldolase, transketolase, and phosphoribulokinase. These increased expression of photosynthesis genes resulted in increased leaf chlorophyll pigment, photosynthetic rate, biomass growth, and grain yield both in the greenhouse and in the field. Using EMSA experiments, we showed that mEmBP-1a protein can directly bind to the promoter region of photosynthesis genes, suggesting that the direct binding of mEmBP-1a to the G-box domain of photosynthetic genes up-regulates expression of these genes. Altogether, our results show that mEmBP-1a is a major regulator of photosynthesis, which can be used to increase rice photosynthesis and yield in the field., (© The Author(s) 2020. Published by Oxford University Press on behalf of the Society for Experimental Biology. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2020

3. A wish list for synthetic biology in photosynthesis research.

Author

Zhu XG, Ort DR, Parry MAJ, and von Caemmerer S

Subjects

China, Photosynthesis, Synthetic Biology

Abstract

This perspective summarizes the presentations and discussions at the ' International Symposium on Synthetic Biology in Photosynthesis Research', which was held in Shanghai in 2018. Leveraging the current advanced understanding of photosynthetic systems, the symposium brain-stormed about the redesign and engineering of photosynthetic systems for translational goals and evaluated available new technologies/tools for synthetic biology as well as technological obstacles and new tools that would be needed to overcome them. Four major research areas for redesigning photosynthesis were identified: (i) mining natural variations of photosynthesis; (ii) coordinating photosynthesis with pathways utilizing photosynthate; (iii) reconstruction of highly efficient photosynthetic systems in non-host species; and (iv) development of new photosynthetic systems that do not exist in nature. To expedite photosynthesis synthetic biology research, an array of new technologies and community resources need to be developed, which include expanded modelling capacities, molecular engineering toolboxes, model species, and phenotyping tools., (© The Author(s) 2020. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2020

4. A three-dimensional canopy photosynthesis model in rice with a complete description of the canopy architecture, leaf physiology, and mechanical properties.

Author

Chang TG, Zhao H, Wang N, Song QF, Xiao Y, Qu M, and Zhu XG

Subjects

Algorithms, Light, Nitrogen metabolism, Oryza physiology, Plant Leaves physiology, Oryza metabolism, Photosynthesis physiology, Plant Leaves metabolism

Abstract

In current rice breeding programs, morphological parameters such as plant height, leaf length and width, leaf angle, panicle architecture, and tiller number during the grain filling stage are used as major selection targets. However, so far, there is no robust approach to quantitatively define the optimal combinations of parameters that can lead to increased canopy radiation use efficiency (RUE). Here we report the development of a three-dimensional canopy photosynthesis model (3dCAP), which effectively combines three-dimensional canopy architecture, canopy vertical nitrogen distribution, a ray-tracing algorithm, and a leaf photosynthesis model. Concurrently, we developed an efficient workflow for the parameterization of 3dCAP. 3dCAP predicted daily canopy RUE for different nitrogen treatments of a given rice cultivar under different weather conditions. Using 3dCAP, we explored the influence of three canopy architectural parameters-tiller number, tiller angle and leaf angle-on canopy RUE. Under different weather conditions and different nitrogen treatments, canopy architecture optimized by manipulating these parameters can increase daily net canopy photosynthetic CO2 uptake by 10-52%. Generally, a smaller tiller angle was predicted for most elite rice canopy architectures, especially under scattered light conditions. Results further show that similar canopy RUE can be obtained by multiple different parameter combinations; these combinations share two common features of high light absorption by leaves in the canopy and a high level of coordination between the nitrogen concentration and the light absorbed by each leaf within the canopy. Overall, this new model has potential to be used in rice ideotype design for improved canopy RUE., (© The Author(s) 2019. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2019

5. Source-sink interaction: a century old concept under the light of modern molecular systems biology.

Author

Chang TG, Zhu XG, and Raines C

Subjects

Carbon metabolism, Crops, Agricultural growth & development, Molecular Biology methods, Nitrogen metabolism, Photosynthesis, Plant Leaves physiology, Plant Roots physiology, Plant Shoots physiology, Plants, Genetically Modified, Crops, Agricultural physiology, Models, Biological, Plant Breeding methods, Systems Biology methods

Abstract

Many approaches to engineer source strength have been proposed to enhance crop yield potential. However, a well-co-ordinated source-sink relationship is required finally to realize the promised increase in crop yield potential in the farmer's field. Source-sink interaction has been intensively studied for decades, and a vast amount of knowledge about the interaction in different crops and under different environments has been accumulated. In this review, we first introduce the basic concepts of source, sink and their interactions, then summarize current understanding of how source and sink can be manipulated through both environmental control and genetic manipulations. We show that the source-sink interaction underlies the diverse responses of crops to the same perturbations and argue that development of a molecular systems model of source-sink interaction is required towards a rational manipulation of the source-sink relationship for increased yield. We finally discuss both bottom-up and top-down routes to develop such a model and emphasize that a community effort is needed for development of this model., (© The Author 2017. Published by Oxford University Press on behalf of the Society for Experimental Biology. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2017

6. The influence of leaf anatomy on the internal light environment and photosynthetic electron transport rate: exploration with a new leaf ray tracing model.

Author

Xiao Y, Tholen D, and Zhu XG

Subjects

Cell Wall metabolism, Chloroplasts metabolism, Light, Models, Biological, Plant Leaves metabolism, Vacuoles metabolism, Electron Transport physiology, Photosynthesis physiology, Plant Leaves anatomy & histology

Abstract

Leaf photosynthesis is determined by biochemical properties and anatomical features. Here we developed a three-dimensional leaf model that can be used to evaluate the internal light environment of a leaf and its implications for whole-leaf electron transport rates (J). This model includes (i) the basic components of a leaf, such as the epidermis, palisade and spongy tissues, as well as the physical dimensions and arrangements of cell walls, vacuoles and chloroplasts; and (ii) an efficient forward ray-tracing algorithm, predicting the internal light environment for light of wavelengths between 400 and 2500nm. We studied the influence of leaf anatomy and ambient light on internal light conditions and J The results show that (i) different chloroplasts can experience drastically different light conditions, even when they are located at the same distance from the leaf surface; (ii) bundle sheath extensions, which are strips of parenchyma, collenchyma or sclerenchyma cells connecting the vascular bundles with the epidermis, can influence photosynthetic light-use efficiency of leaves; and (iii) chloroplast positioning can also influence the light-use efficiency of leaves. Mechanisms underlying leaf internal light heterogeneity and implications of the heterogeneity for photoprotection and for the convexity of the light response curves are discussed., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2016

7. Systems analysis of cis-regulatory motifs in C4 photosynthesis genes using maize and rice leaf transcriptomic data during a process of de-etiolation.

Author

Xu J, Bräutigam A, Weber AP, and Zhu XG

Subjects

Etiolation physiology, Gene Expression Profiling, Gene Expression Regulation, Plant genetics, Gene Expression Regulation, Plant physiology, Genes, Plant physiology, Oryza physiology, Photosynthesis physiology, Zea mays physiology, Etiolation genetics, Genes, Plant genetics, Oryza genetics, Photosynthesis genetics, Plant Leaves physiology, Zea mays genetics

Abstract

Identification of potential cis-regulatory motifs controlling the development of C4 photosynthesis is a major focus of current research. In this study, we used time-series RNA-seq data collected from etiolated maize and rice leaf tissues sampled during a de-etiolation process to systematically characterize the expression patterns of C4-related genes and to further identify potential cis elements in five different genomic regions (i.e. promoter, 5'UTR, 3'UTR, intron, and coding sequence) of C4 orthologous genes. The results demonstrate that although most of the C4 genes show similar expression patterns, a number of them, including chloroplast dicarboxylate transporter 1, aspartate aminotransferase, and triose phosphate transporter, show shifted expression patterns compared with their C3 counterparts. A number of conserved short DNA motifs between maize C4 genes and their rice orthologous genes were identified not only in the promoter, 5'UTR, 3'UTR, and coding sequences, but also in the introns of core C4 genes. We also identified cis-regulatory motifs that exist in maize C4 genes and also in genes showing similar expression patterns as maize C4 genes but that do not exist in rice C3 orthologs, suggesting a possible recruitment of pre-existing cis-elements from genes unrelated to C4 photosynthesis into C4 photosynthesis genes during C4 evolution., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2016

8. Perspectives for a better understanding of the metabolic integration of photorespiration within a complex plant primary metabolism network.

Author

Hodges M, Dellero Y, Keech O, Betti M, Raghavendra AS, Sage R, Zhu XG, Allen DK, and Weber AP

Subjects

Metabolic Networks and Pathways physiology, Plant Physiological Phenomena, Plants enzymology, Photosynthesis physiology, Plants metabolism

Abstract

Photorespiration is an essential high flux metabolic pathway that is found in all oxygen-producing photosynthetic organisms. It is often viewed as a closed metabolic repair pathway that serves to detoxify 2-phosphoglycolic acid and to recycle carbon to fuel the Calvin-Benson cycle. However, this view is too simplistic since the photorespiratory cycle is known to interact with several primary metabolic pathways, including photosynthesis, nitrate assimilation, amino acid metabolism, C1 metabolism and the Krebs (TCA) cycle. Here we will review recent advances in photorespiration research and discuss future priorities to better understand (i) the metabolic integration of the photorespiratory cycle within the complex network of plant primary metabolism and (ii) the importance of photorespiration in response to abiotic and biotic stresses., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Experimental Biology. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2016

9. Three distinct biochemical subtypes of C4 photosynthesis? A modelling analysis.

Author

Wang Y, Bräutigam A, Weber AP, and Zhu XG

Subjects

Carbon metabolism, Cell Respiration, Light, Malate Dehydrogenase, Mesophyll Cells, Models, Theoretical, Nitrogen metabolism, Phosphoenolpyruvate Carboxykinase (ATP), Phosphoenolpyruvate Carboxylase metabolism, Plant Leaves metabolism, Plant Leaves radiation effects, Plants radiation effects, Carbon Dioxide metabolism, Photosynthesis, Plant Proteins metabolism, Plants metabolism

Abstract

C4 photosynthesis has higher light-use, nitrogen-use, and water-use efficiencies than C3 photosynthesis. Historically, most of C4 plants were classified into three subtypes (NADP-malic enzyme (ME), NAD-ME, or phosphoenolpyruvate carboxykinase (PEPCK) subtypes) according to their major decarboxylation enzyme. However, a wealth of historic and recent data indicates that flexibility exists between different decarboxylation pathways in many C4 species, and this flexibility might be controlled by developmental and environmental cues. This work used systems modelling to theoretically explore the significance of flexibility in decarboxylation mechanisms and transfer acids utilization. The results indicate that employing mixed C4 pathways, either the NADP-ME type with the PEPCK type or the NAD-ME type with the PEPCK type, effectively decreases the need to maintain high concentrations and concentration gradients of transport metabolites. Further, maintaining a mixture of C4 pathways robustly affords high photosynthetic efficiency under a broad range of light regimes. A pure PEPCK-type C4 photosynthesis is not beneficial because the energy requirements in bundle sheath cells cannot be fulfilled due to them being shaded by mesophyll cells. Therefore, only two C4 subtypes should be considered as distinct subtypes, the NADP-ME type and NAD-ME types, which both inherently involve a supplementary PEPCK cycle., (© The Author 2014. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2014

10. Was low CO2 a driving force of C4 evolution: Arabidopsis responses to long-term low CO2 stress.

Author

Li Y, Xu J, Haq NU, Zhang H, and Zhu XG

Subjects

Arabidopsis genetics, Arabidopsis radiation effects, Arabidopsis ultrastructure, Biological Evolution, Biomass, Cell Respiration, Chloroplasts ultrastructure, Light, Plant Stomata genetics, Plant Stomata physiology, Plant Stomata radiation effects, Plant Stomata ultrastructure, Plant Vascular Bundle genetics, Plant Vascular Bundle physiology, Plant Vascular Bundle radiation effects, Plant Vascular Bundle ultrastructure, Seedlings genetics, Seedlings physiology, Seedlings radiation effects, Seedlings ultrastructure, Arabidopsis physiology, Carbon Dioxide metabolism, Gene Expression Regulation, Plant, Photosynthesis, Stress, Physiological, Transcriptome

Abstract

The responses of long-term growth of plants under elevated CO2 have been studied extensively. Comparatively, the responses of plants to subambient CO2 concentrations have not been well studied. This study aims to investigate the responses of the model C3 plant, Arabidopsis thaliana, to low CO2 at the molecular level. Results showed that low CO2 dramatically decreased biomass productivity, together with delayed flowering and increased stomatal density. Furthermore, alteration of thylakoid stacking in both bundle sheath and mesophyll cells, upregulation of PEPC and PEPC-K together with altered expression of a number of regulators known involved in photosynthesis development were observed. These responses to low CO2 are discussed with regard to the fitness of C3 plants under low CO2. This work also briefly discusses the relevance of the data to C4 photosynthesis evolution., (© The Author 2014. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2014

11. Exploiting the engine of C(4) photosynthesis.

Author

Sage RF and Zhu XG

Subjects

Carbon Dioxide metabolism, Crops, Agricultural enzymology, Crops, Agricultural genetics, Crops, Agricultural growth & development, Photosynthesis genetics, Plant Proteins metabolism, Plants, Genetically Modified genetics, Plants, Genetically Modified growth & development, Plants, Genetically Modified physiology, Ribulose-Bisphosphate Carboxylase metabolism, Setaria Plant enzymology, Setaria Plant genetics, Setaria Plant growth & development, Bioengineering methods, Crops, Agricultural physiology, Photosynthesis physiology, Setaria Plant physiology

Abstract

Ever since the discovery of C(4) photosynthesis in the mid-1960s, plant biologists have envisaged the introduction of the C(4) photosynthetic pathway into C(3) crops such as rice and soybeans. Recent advances in genomics capabilities, and new evolutionary and developmental studies indicate that C(4) engineering will be feasible in the next few decades. Furthermore, better understanding of the function of C(4) photosynthesis provides new ways to improve existing C(4) crops and bioenergy species, for example by creating varieties with ultra-high water and nitrogen use efficiencies. In the case of C(4) engineering, the main enzymes of the C(4) metabolic cycle have already been engineered into various C(3) plants. In contrast, knowledge of the genes controlling Kranz anatomy lags far behind. Combining traditional genetics, high-throughput sequencing technologies, systems biology, bioinformatics, and the use of the new C(4) model species Setaria viridis, the discovery of the key genes controlling the expression of C(4) photosynthesis can be dramatically accelerated. Sustained investment in the research areas directly related to C(4) engineering has the potential for substantial return in the decades to come, primarily by increasing crop production at a time when global food supplies are predicted to fall below world demand.

Published

2011

12. Raising yield potential of wheat. II. Increasing photosynthetic capacity and efficiency.

Author

Parry MA, Reynolds M, Salvucci ME, Raines C, Andralojc PJ, Zhu XG, Price GD, Condon AG, and Furbank RT

Subjects

Carbon Dioxide metabolism, Plant Proteins genetics, Plant Proteins metabolism, Ribulose-Bisphosphate Carboxylase genetics, Ribulose-Bisphosphate Carboxylase metabolism, Triticum enzymology, Triticum genetics, Breeding methods, Photosynthesis, Triticum growth & development, Triticum metabolism

Abstract

Past increases in yield potential of wheat have largely resulted from improvements in harvest index rather than increased biomass. Further large increases in harvest index are unlikely, but an opportunity exists for increasing productive biomass and harvestable grain. Photosynthetic capacity and efficiency are bottlenecks to raising productivity and there is strong evidence that increasing photosynthesis will increase crop yields provided that other constraints do not become limiting. Even small increases in the rate of net photosynthesis can translate into large increases in biomass and hence yield, since carbon assimilation is integrated over the entire growing season and crop canopy. This review discusses the strategies to increase photosynthesis that are being proposed by the wheat yield consortium in order to increase wheat yields. These include: selection for photosynthetic capacity and efficiency, increasing ear photosynthesis, optimizing canopy photosynthesis, introducing chloroplast CO(2) pumps, increasing RuBP regeneration, improving the thermal stability of Rubisco activase, and replacing wheat Rubisco with that from other species with different kinetic properties.

Published

2011

13. The slow reversibility of photosystem II thermal energy dissipation on transfer from high to low light may cause large losses in carbon gain by crop canopies: a theoretical analysis.

Author

Zhu XG, Ort DR, Whitmarsh J, and Long SP

Subjects

Carbon Dioxide metabolism, Cold Temperature, Light, Photons, Photosynthesis, Plant Leaves cytology, Temperature, Time Factors, Carbon metabolism, Models, Theoretical, Photosystem II Protein Complex metabolism, Plant Leaves metabolism

Abstract

Regulated thermal dissipation of absorbed light energy within the photosystem II antenna system helps protect photosystem II from damage in excess light. This reversible photoprotective process decreases the maximum quantum yield of photosystem II (Fv)/Fm) and CO2 assimilation (phiCO2), and decreases the convexity of the non-rectangular hyperbola describing the response of leaf CO2 assimilation to photon flux (theta). At high light, a decrease in phiCO2 has minimal impact on carbon gain, while high thermal energy dissipation protects PSII against oxidative damage. Light in leaf canopies in the field is continually fluctuating and a finite period of time is required for recovery of phiCO2 and when light drops below excess levels. Low phiCO2) and can limit the rate of photosynthetic carbon assimilation on transfer to low light, an effect prolonged by low temperature. What is the cost of this delayed reversal of thermal energy dissipation and phiCO2 recovery to potential CO2 uptake by a canopy in the field? To address this question a reverse ray-tracing algorithm for predicting the light dynamics of 120 randomly selected individual points in a model canopy was used to describe the discontinuity and heterogeneity of light flux within the canopy. Because photoprotection is at the level of the cell, not the leaf, light was simulated for small points of 10(4) micro m rather than as an average for a leaf. The predicted light dynamics were combined with empirical equations simulating the dynamics of the light-dependent decrease and recovery of phiCO2 and and their effects on the integrated daily canopy carbon uptake (A'c). The simulation was for a model canopy of leaf area index 3 with random inclination and orientation of foliage, on a clear sky day (latitude 44 degrees N, 120th day of the year). The delay in recovery of photoprotection was predicted to decrease A'c by 17% at 30 degrees C and 32% at 10 degrees C for a chilling-susceptible species, and by 12.8% at 30 degrees C and 24% at 10 degrees C for a chilling-tolerant species. These predictions suggest that the selection, or engineering, of genotypes capable of more rapid recovery from the photoprotected state would substantially increase carbon uptake by crop canopies in the field., (Copyright 2004 Society for Experimental Biology)

Published

2004