Your search keyword '"Manfei Li"' showing total 21 results

1. GIF1 controls ear inflorescence architecture and floral development by regulating key genes in hormone biosynthesis and meristem determinacy in maize

Author

Manfei Li, Yuanyuan Zheng, Di Cui, Yanfang Du, Dan Zhang, Wei Sun, Hewei Du, and Zuxin Zhang

Subjects

Spikelet pair meristem, Branch meristem, Carpel, Clavata3/esr-related gene, Inflorescence, Botany, QK1-989

Abstract

Abstract Background Inflorescence architecture and floral development in flowering plants are determined by genetic control of meristem identity, determinacy, and maintenance. The ear inflorescence meristem in maize (Zea mays) initiates short branch meristems called spikelet pair meristems, thus unlike the tassel inflorescence, the ears lack long branches. Maize growth-regulating factor (GRF)-interacting factor1 (GIF1) regulates branching and size of meristems in the tassel inflorescence by binding to Unbranched3. However, the regulatory pathway of gif1 in ear meristems is relatively unknown. Result In this study, we found that loss-of-function gif1 mutants had highly branched ears, and these extra branches repeatedly produce more branches and florets with unfused carpels and an indeterminate floral apex. In addition, GIF1 interacted in vivo with nine GRFs, subunits of the SWI/SNF chromatin-remodeling complex, and hormone biosynthesis-related proteins. Furthermore, key meristem-determinacy gene RAMOSA2 (RA2) and CLAVATA signaling-related gene CLV3/ENDOSPERM SURROUNDING REGION (ESR) 4a (CLE4a) were directly bound and regulated by GIF1 in the ear inflorescence. Conclusions Our findings suggest that GIF1 working together with GRFs recruits SWI/SNF chromatin-remodeling ATPases to influence DNA accessibility in the regions that contain genes involved in hormone biosynthesis, meristem identity and determinacy, thus driving the fate of axillary meristems and floral organ primordia in the ear-inflorescence of maize.

Published

2022

2. A serine/threonine protein kinase encoding gene KERNEL NUMBER PER ROW6 regulates maize grain yield

Author

Haitao Jia, Manfei Li, Weiya Li, Lei Liu, Yinan Jian, Zhixing Yang, Xiaomeng Shen, Qiang Ning, Yanfang Du, Ran Zhao, David Jackson, Xiaohong Yang, and Zuxin Zhang

Subjects

Science

Abstract

Selection of kernel number per ear has improved maize yield, but the genetic base is unclear. Here, the authors reveal that a serine/threonine protein kinase KNR6 is a positive regulator of the trait and show in vitro evidences that KNR6 may function through phosphorylating an Arf GTPase-activating protein.

Published

2020

3. UNBRANCHED3 Expression and Inflorescence Development is Mediated by UNBRANCHED2 and the Distal Enhancer, KRN4, in Maize.

Author

Yanfang Du, Lei Liu, Yong Peng, Manfei Li, Yunfu Li, Dan Liu, Xingwang Li, and Zuxin Zhang

Subjects

Genetics, QH426-470

Abstract

Enhancers are cis-acting DNA segments with the ability to increase target gene expression. They show high sensitivity to DNase and contain specific DNA elements in an open chromatin state that allows the binding of transcription factors (TFs). While numerous enhancers are annotated in the maize genome, few have been characterized genetically. KERNEL ROW NUMBER4 (KRN4), an intergenic quantitative trait locus for kernel row number, is assumed to be a cis-regulatory element of UNBRANCHED3 (UB3), a key inflorescence gene. However, the mechanism by which KRN4 controls UB3 expression remains unclear. Here, we found that KRN4 exhibits an open chromatin state, harboring sequences that showed high enhancer activity toward the 35S and UB3 promoters. KRN4 is bound by UB2-centered transcription complexes and interacts with the UB3 promoter by three duplex interactions to affect UB3 expression. Sequence variation at KRN4 enhances ub2 and ub3 mutant ear fasciation. Therefore, we suggest that KRN4 functions as a distal enhancer of the UB3 promoter via chromatin interactions and recruitment of UB2-centered transcription complexes for the fine-tuning of UB3 expression in meristems of ear inflorescences. These results provide evidence that an intergenic region helps to finely tune gene expression, providing a new perspective on the genetic control of quantitative traits.

Published

2020

4. The Coordinated KNR6–AGAP–ARF1 Complex Modulates Vegetative and Reproductive Traits by Participating in Vesicle Trafficking in Maize

Author

Manfei Li, Ran Zhao, Yanfang Du, Xiaomeng Shen, Qiang Ning, Yunfu Li, Dan Liu, Qing Xiong, and Zuxin Zhang

Subjects

ADP-ribosylation factor (Arf) GTPase, Arf GTPase-activating protein, inflorescence, vesicle transport, kernel number, Golgi apparatus, Cytology, QH573-671

Abstract

The KERNEL NUMBER PER ROW6 (KNR6)-mediated phosphorylation of an adenosine diphosphate ribosylation factor (Arf) GTPase-activating protein (AGAP) forms a key regulatory module for the numbers of spikelets and kernels in the ear inflorescences of maize (Zea mays L.). However, the action mechanism of the KNR6–AGAP module remains poorly understood. Here, we characterized the AGAP-recruited complex and its roles in maize cellular physiology and agronomically important traits. AGAP and its two interacting Arf GTPase1 (ARF1) members preferentially localized to the Golgi apparatus. The loss-of-function AGAP mutant produced by CRISPR/Cas9 resulted in defective Golgi apparatus with thin and compact cisternae, together with delayed internalization and repressed vesicle agglomeration, leading to defective inflorescences and roots, and dwarfed plants with small leaves. The weak agap mutant was phenotypically similar to knr6, showing short ears with fewer kernels. AGAP interacted with KNR6, and a double mutant produced shorter inflorescence meristems and mature ears than the single agap and knr6 mutants. We hypothesized that the coordinated KNR6–AGAP–ARF1 complex modulates vegetative and reproductive traits by participating in vesicle trafficking in maize. Our findings provide a novel mechanistic insight into the regulation of inflorescence development, and ear length and kernel number, in maize.

Published

2021

5. The Ruminant Farm Systems Animal Module: A Biophysical Description of Animal Management

Author

Tayler L. Hansen, Manfei Li, Jinghui Li, Chris J. Vankerhove, Militsa A. Sotirova, Juan M. Tricarico, Victor E. Cabrera, Ermias Kebreab, and Kristan F. Reed

Subjects

dairy management, Monte Carlo simulation, RuFaS, Veterinary medicine, SF600-1100, Zoology, QL1-991

Abstract

Dairy production is an important source of nutrients in the global food supply, but environmental impacts are increasingly a concern of consumers, scientists, and policy-makers. Many decisions must be integrated to support sustainable production—which can be achieved using a simulation model. We provide an example of the Ruminant Farm Systems (RuFaS) model to assess changes in the dairy system related to altered animal feed efficiency. RuFaS is a whole-system farm simulation model that simulates the individual animal life cycle, production, and environmental impacts. We added a stochastic animal-level parameter to represent individual animal feed efficiency as a result of reduced residual feed intake and compared High (intake = 94% of expected) and Very High (intake = 88% of expected) efficiency levels with a Baseline scenario (intake = 100% of expected). As expected, the simulated total feed intake was reduced by 6 and 12% for the High and Very High efficiency scenarios, and the expected impact of these improved efficiencies on the greenhouse gas emissions from enteric methane and manure storage was a decrease of 4.6 and 9.3%, respectively.

Published

2021

6. KRN4 Controls Quantitative Variation in Maize Kernel Row Number.

Author

Lei Liu, Yanfang Du, Xiaomeng Shen, Manfei Li, Wei Sun, Juan Huang, Zhijie Liu, Yongsheng Tao, Yonglian Zheng, Jianbing Yan, and Zuxin Zhang

Subjects

Genetics, QH426-470

Abstract

Kernel row number (KRN) is an important component of yield during the domestication and improvement of maize and controlled by quantitative trait loci (QTL). Here, we fine-mapped a major KRN QTL, KRN4, which can enhance grain productivity by increasing KRN per ear. We found that a ~3-Kb intergenic region about 60 Kb downstream from the SBP-box gene Unbranched3 (UB3) was responsible for quantitative variation in KRN by regulating the level of UB3 expression. Within the 3-Kb region, the 1.2-Kb Presence-Absence variant was found to be strongly associated with quantitative variation in KRN in diverse maize inbred lines, and our results suggest that this 1.2-Kb transposon-containing insertion is likely responsible for increased KRN. A previously identified A/G SNP (S35, also known as Ser220Asn) in UB3 was also found to be significantly associated with KRN in our association-mapping panel. Although no visible genetic effect of S35 alone could be detected in our linkage mapping population, it was found to genetically interact with the 1.2-Kb PAV to modulate KRN. The KRN4 was under strong selection during maize domestication and the favorable allele for the 1.2-Kb PAV and S35 has been significantly enriched in modern maize improvement process. The favorable haplotype (Hap1) of 1.2-Kb-PAV-S35 was selected during temperate maize improvement, but is still rare in tropical and subtropical maize germplasm. The dissection of the KRN4 locus improves our understanding of the genetic basis of quantitative variation in complex traits in maize.

Published

2015

7. ZmBET5L1 inhibits primary root growth and decreases osmotic stress tolerance by mediating vesicle aggregation and tethering in maize

Author

Ran, Zhao, Nan, Li, Qianrun, Lin, Manfei, Li, Xiaomeng, Shen, Yong, Peng, Yanfang, Du, Qiang, Ning, Yunfu, Li, Jimin, Zhan, Fang, Yang, Fang, Xu, Zuxin, Zhang, and Lei, Liu

Subjects

Physiology, Plant Science

Abstract

Improving osmotic stress tolerance is critical to help crops to thrive and maintain high yields in adverse environments. Here, we characterized a core subunit of the transport protein particle (TRAPP) complex, ZmBET5L1, in maize using knowledge-driven data mining and genome editing. We found that ZmBET5L1 can interact with TRAPP I complex subunits and act as a tethering factor to mediate vesicle aggregation and targeting from the endoplasmic reticulum to the Golgi apparatus. ZmBET5L1 knock-out increased the primary root elongation rate under 20% polyethylene glycol-simulated osmotic stress and the survival rate under drought stress compared to wild-type seedlings. In addition, we found that ZmBET5L1 moderates PIN1 polar localization and auxin flow to maintain normal root growth. ZmBET5L1 knock-out optimized auxin flow to the lateral side of the root and promoted its growth to generate a robust root, which may be related to improved osmotic stress tolerance. Together, these findings demonstrate that ZmBET5L1 inhibits primary root growth and decreases osmotic stress tolerance by regulating vesicle transport and auxin distribution. This study has improved our understanding of the role of tethering factors in response to abiotic stresses and identified desirable variants for breeding osmotic stress tolerance in maize.

Published

2022

8. Divergent selection of KNR6 maximizes grain production by balancing the flowering‐time adaptation and ear size in maize

Author

Weiya Li, Haitao Jia, Manfei Li, Yiqin Huang, Wenkang Chen, Pengfei Yin, Zhixing Yang, Qiuyue Chen, Feng Tian, Zuxin Zhang, Xiaohong Yang, and Lei Liu

Subjects

Plant Science, Agronomy and Crop Science, Biotechnology

Published

2023

9. Kinetics of phosphorus sorption/desorption by soil aggregates in a long‐term revegetation desert ecosystem

Author

Chengyi Li, Mingzhu He, Jianxin Ren, Manfei Li, and Liang Tang

Subjects

Soil Science, Environmental Chemistry, Development, General Environmental Science

Published

2022

10. [Design and Implementation of ECG Electrode Tester]

Author

Yunlong, Zhao, Bo, Guo, Zhanshuo, Wang, Manfei, Li, and Shaobo, Xing

Abstract

As a technical method to detect cardiomotility of human body, ECG monitoring is widely used in various clinical departments of hospital, as an important guarantee for disease diagnosis, patients saving and treatment. Therefore, the testing and management of the performance of ECG monitoring equipment is of great importance. In view of researches from the perspective of disposable ECG electrode performance testing, the study puts forward a design scheme of disposable ECG electrode tester, and confirms the effectiveness of the design for ECG electrode performance testing through the test of disposable ECG electrode.

Published

2023

11. GIF1 controls ear inflorescence architecture and floral development by regulating key genes in hormone biosynthesis and meristem determinacy in maize

Author

Manfei Li, Yuanyuan Zheng, Di Cui, Yanfang Du, Dan Zhang, Wei Sun, Hewei Du, and Zuxin Zhang

Subjects

Meristem, Gene Expression, Plant Science, Zea mays, Phenotype, Plant Growth Regulators, Gene Expression Regulation, Plant, Genes, Reporter, Loss of Function Mutation, Chromatin Immunoprecipitation Sequencing, Gene Fusion, Inflorescence, Transcriptome, Plant Proteins

Abstract

Background Inflorescence architecture and floral development in flowering plants are determined by genetic control of meristem identity, determinacy, and maintenance. The ear inflorescence meristem in maize (Zea mays) initiates short branch meristems called spikelet pair meristems, thus unlike the tassel inflorescence, the ears lack long branches. Maize growth-regulating factor (GRF)-interacting factor1 (GIF1) regulates branching and size of meristems in the tassel inflorescence by binding to Unbranched3. However, the regulatory pathway of gif1 in ear meristems is relatively unknown. Result In this study, we found that loss-of-function gif1 mutants had highly branched ears, and these extra branches repeatedly produce more branches and florets with unfused carpels and an indeterminate floral apex. In addition, GIF1 interacted in vivo with nine GRFs, subunits of the SWI/SNF chromatin-remodeling complex, and hormone biosynthesis-related proteins. Furthermore, key meristem-determinacy gene RAMOSA2 (RA2) and CLAVATA signaling-related gene CLV3/ENDOSPERM SURROUNDING REGION (ESR) 4a (CLE4a) were directly bound and regulated by GIF1 in the ear inflorescence. Conclusions Our findings suggest that GIF1 working together with GRFs recruits SWI/SNF chromatin-remodeling ATPases to influence DNA accessibility in the regions that contain genes involved in hormone biosynthesis, meristem identity and determinacy, thus driving the fate of axillary meristems and floral organ primordia in the ear-inflorescence of maize.

Published

2021

12. The Coordinated KNR6–AGAP–ARF1 Complex Modulates Vegetative and Reproductive Traits by Participating in Vesicle Trafficking in Maize

Author

Yanfang Du, Zuxin Zhang, Ran Zhao, Dan Liu, Qing Xiong, Manfei Li, Xiaomeng Shen, Qiang Ning, and Yunfu Li

Subjects

Cell physiology, Arf GTPase-activating protein, QH301-705.5, media_common.quotation_subject, Mutant, Arabidopsis, Biology, Plant Roots, Zea mays, Article, vesicle transport, symbols.namesake, inflorescence, Biology (General), Internalization, media_common, ADP-Ribosylation Factors, Arabidopsis Proteins, GTPase-Activating Proteins, food and beverages, General Medicine, Golgi apparatus, Meristem, Plants, Genetically Modified, Cell biology, Vesicular transport protein, Phenotype, Inflorescence, ADP-ribosylation factor (Arf) GTPase, symbols, Phosphorylation, ADP-Ribosylation Factor 1, kernel number

Abstract

The KERNEL NUMBER PER ROW6 (KNR6)-mediated phosphorylation of an adenosine diphosphate ribosylation factor (Arf) GTPase-activating protein (AGAP) forms a key regulatory module for the numbers of spikelets and kernels in the ear inflorescences of maize (Zea mays L.). However, the action mechanism of the KNR6–AGAP module remains poorly understood. Here, we characterized the AGAP-recruited complex and its roles in maize cellular physiology and agronomically important traits. AGAP and its two interacting Arf GTPase1 (ARF1) members preferentially localized to the Golgi apparatus. The loss-of-function AGAP mutant produced by CRISPR/Cas9 resulted in defective Golgi apparatus with thin and compact cisternae, together with delayed internalization and repressed vesicle agglomeration, leading to defective inflorescences and roots, and dwarfed plants with small leaves. The weak agap mutant was phenotypically similar to knr6, showing short ears with fewer kernels. AGAP interacted with KNR6, and a double mutant produced shorter inflorescence meristems and mature ears than the single agap and knr6 mutants. We hypothesized that the coordinated KNR6–AGAP–ARF1 complex modulates vegetative and reproductive traits by participating in vesicle trafficking in maize. Our findings provide a novel mechanistic insight into the regulation of inflorescence development, and ear length and kernel number, in maize.

Published

2021

13. The Ruminant Farm Systems Animal Module: A Biophysical Description of Animal Management

Author

Jinghui Li, Militsa A. Sotirova, Ermias Kebreab, Tayler L. Hansen, Chris J. Vankerhove, Victor E. Cabrera, J.M. Tricarico, Manfei Li, and K. F. Reed

Subjects

Environmental Science and Management, Animal feed, Veterinary medicine, Agricultural engineering, RuFaS, Feed conversion ratio, Article, 03 medical and health sciences, Nutrient, Animal Production, Ruminant, SF600-1100, Production (economics), Baseline (configuration management), Monte Carlo simulation, 030304 developmental biology, 0303 health sciences, General Veterinary, biology, 0402 animal and dairy science, 04 agricultural and veterinary sciences, biology.organism_classification, 040201 dairy & animal science, Climate Action, dairy management, QL1-991, Greenhouse gas, Environmental science, Animal Science and Zoology, Residual feed intake, Zoology

Abstract

Simple Summary Consumers are increasingly concerned about the sustainable production of food, leading producers and scientists to evaluate farming practices that preserve environmental resources, provide adequate production, and are economically viable. However, there are challenges to synthesize these results and apply them on-farm in a holistic nature. Simulation modeling of farm systems, such as the dairy system, can allow producers, industry members, and policy makers to prioritize interventions that improve sustainable outcomes. We introduce the Animal Module of the Ruminant Farm Systems (RuFaS) model—a whole farm dairy system model—and describe its use to assess the environmental impact of improved feed efficiency in dairy cows. By decreasing the amount of feed intake required to produce the same amount of milk, the RuFaS model provides estimates of the reduction in feed use, enteric methane, and manure production. Abstract Dairy production is an important source of nutrients in the global food supply, but environmental impacts are increasingly a concern of consumers, scientists, and policy-makers. Many decisions must be integrated to support sustainable production—which can be achieved using a simulation model. We provide an example of the Ruminant Farm Systems (RuFaS) model to assess changes in the dairy system related to altered animal feed efficiency. RuFaS is a whole-system farm simulation model that simulates the individual animal life cycle, production, and environmental impacts. We added a stochastic animal-level parameter to represent individual animal feed efficiency as a result of reduced residual feed intake and compared High (intake = 94% of expected) and Very High (intake = 88% of expected) efficiency levels with a Baseline scenario (intake = 100% of expected). As expected, the simulated total feed intake was reduced by 6 and 12% for the High and Very High efficiency scenarios, and the expected impact of these improved efficiencies on the greenhouse gas emissions from enteric methane and manure storage was a decrease of 4.6 and 9.3%, respectively.

Published

2021

14. Genetic and Molecular Mechanisms of Quantitative Trait Loci Controlling Maize Inflorescence Architecture

Author

Manfei Li, Wanshun Zhong, Fang Yang, and Zuxin Zhang

Subjects

0301 basic medicine, Physiology, animal diseases, Quantitative Trait Loci, genetic processes, Tassel, Plant Science, Biology, Quantitative trait locus, Zea mays, 03 medical and health sciences, Quantitative Trait, Heritable, Genetic Pleiotropy, Inflorescence, Gene, fungi, food and beverages, Cell Biology, General Medicine, Meristem, biology.organism_classification, MicroRNAs, 030104 developmental biology, Evolutionary biology, Grain yield, Flowering plant

Abstract

The establishment of inflorescence architecture is critical for the reproduction of flowering plant species. The maize plant generates two types of inflorescences, the tassel and the ear, and their architectures have a large effect on grain yield and yield-related traits that are genetically controlled by quantitative trait loci (QTLs). Since ear and tassel architecture are deeply affected by the activity of inflorescence meristems, key QTLs and genes regulating meristematic activity have important impacts on inflorescence development and show great potential for optimizing grain yield. Isolation of yield trait-related QTLs is challenging, but these QTLs have direct application in maize breeding. Additionally, characterization and functional dissection of QTLs can provide genetic and molecular knowledge of quantitative variation in inflorescence architecture. In this review, we summarize currently identified QTLs responsible for the establishment of ear and tassel architecture and discuss the potential genetic control of four ear-related and four tassel-related traits. In recent years, several inflorescence architecture-related QTLs have been characterized at the gene level. We review the mechanisms of these characterized QTLs.

Published

2018

15. Identification of a candidate gene underlying qKRN5b for kernel row number in Zea mays L

Author

Ran Zhao, Lei Liu, Zuxin Zhang, Hewei Du, Can Zhu, Xiaomeng Shen, and Manfei Li

Subjects

0106 biological sciences, Genetics, Candidate gene, Genetic Linkage, Quantitative Trait Loci, Nucleic acid sequence, food and beverages, Chromosome Mapping, General Medicine, Biology, Quantitative trait locus, 01 natural sciences, Zea mays, Phenotype, Inflorescence, Genetic linkage, Backcrossing, Seeds, Allele, Agronomy and Crop Science, Gene, Alleles, 010606 plant biology & botany, Biotechnology

Abstract

A quantitative trait locus for kernel row number, qKRN5, was dissected into two tightly linked loci, qKRN5a and qKRN5b. Fine mapping, comparative analysis of nucleotide sequences and gene expression established the endonuclease/exonuclease/phosphatase family protein-encoding gene Zm00001d013603 as a causal gene of qKRN5b. Maize grain yield is determined by agronomically important traits that are controlled by interactions among and between genes and environmental factors. Considerable efforts have been made to identify major quantitative trait loci (QTLs) for yield-related traits; however, few were previously isolated and characterized in maize. In this study, we divided a QTL for kernel row number (KRN), qKRN5, into two tightly linked loci, qKRN5a and qKRN5b, using advanced backcross populations derived from near-isogenic lines. KRN was greater in individuals that were homozygous for the NX531 allele, which showed coupling-phase linkage. The major QTL qKRN5b had an additive effect of approximately one kernel row. Furthermore, fine mapping narrowed qKRN5b within a 147.2-kb region. The upstream sequence Zm00001d013603 and its expression in the ear inflorescence showed obvious differences between qKRN5b near-isogenic lines. In situ hybridization located Zm00001d013603 on the primordia of the spikelet pair meristems and spikelet meristems, but not in the inflorescence meristem, which indicates a role in regulating the initiation of reproductive axillary meristems of ear inflorescences. Expression analysis and nucleotide sequence alignment revealed that Zm00001d013603, which encodes an endonuclease/exonuclease/phosphatase family protein that hydrolyzes phosphatidyl inositol diphosphates, is the causal gene of qKRN5b. These results provide insight into the genetic basis of KRN and have potential value for enhancing maize grain yield.

Published

2019

16. UNBRANCHED3 Expression and Inflorescence Development is Mediated by UNBRANCHED2 and the Distal Enhancer, KRN4, in Maize

Author

Yong Peng, Zuxin Zhang, Yanfang Du, Yunfu Li, Dan Liu, Lei Liu, Manfei Li, and Xingwang Li

Subjects

Cancer Research, Gene Expression, Plant Science, QH426-470, Plant Genetics, Biochemistry, 0302 clinical medicine, Gene Expression Regulation, Plant, Transcription (biology), Gene expression, Medicine and Health Sciences, Plant Genomics, Promoter Regions, Genetic, Genetics (clinical), Plant Proteins, Regulation of gene expression, 0303 health sciences, Chromosome Biology, Plant Anatomy, Eukaryota, Gene Expression Regulation, Developmental, Genomics, Plants, Chromatin, Enzymes, Cell biology, Enhancer Elements, Genetic, Experimental Organism Systems, Engineering and Technology, Epigenetics, Anatomy, Oxidoreductases, Luciferase, Research Article, Biotechnology, Transcriptional Activation, Inflorescences, Bioengineering, Biology, Research and Analysis Methods, Zea mays, 03 medical and health sciences, Model Organisms, Plant and Algal Models, Genetics, Gene Regulation, Grasses, Enhancer, Molecular Biology, Transcription factor, Gene, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Organisms, Biology and Life Sciences, Proteins, Promoter, Cell Biology, Chromatin Assembly and Disassembly, Maize, Ears, Animal Studies, Enzymology, Plant Biotechnology, Head, 030217 neurology & neurosurgery, Transcription Factors

Abstract

Enhancers are cis-acting DNA segments with the ability to increase target gene expression. They show high sensitivity to DNase and contain specific DNA elements in an open chromatin state that allows the binding of transcription factors (TFs). While numerous enhancers are annotated in the maize genome, few have been characterized genetically. KERNEL ROW NUMBER4 (KRN4), an intergenic quantitative trait locus for kernel row number, is assumed to be a cis-regulatory element of UNBRANCHED3 (UB3), a key inflorescence gene. However, the mechanism by which KRN4 controls UB3 expression remains unclear. Here, we found that KRN4 exhibits an open chromatin state, harboring sequences that showed high enhancer activity toward the 35S and UB3 promoters. KRN4 is bound by UB2-centered transcription complexes and interacts with the UB3 promoter by three duplex interactions to affect UB3 expression. Sequence variation at KRN4 enhances ub2 and ub3 mutant ear fasciation. Therefore, we suggest that KRN4 functions as a distal enhancer of the UB3 promoter via chromatin interactions and recruitment of UB2-centered transcription complexes for the fine-tuning of UB3 expression in meristems of ear inflorescences. These results provide evidence that an intergenic region helps to finely tune gene expression, providing a new perspective on the genetic control of quantitative traits., Author summary With the completion of increasing numbers of plant genome sequences and continuous accumulation of multiomics data, numerous regulatory elements are annotated in those intergenic regions containing open chromatin. Enhancers are cis-acting DNA elements with the ability to increase target gene expression. They show high sensitivity to DNase and contain specific DNA elements in an open chromatin state that allows the binding of transcription factors. KERNEL ROW NUMBER4 (KRN4) is an intergenic region located downstream of a key inflorescence gene UNBRANCHED3 (UB3). However, the mechanism by which KRN4 regulates UB3 expression remains unknown. Here, we showed the genetic interactions between KRN4 and UB3 as well as UNBRANCHED2 (UB2) in controlling inflorescence architecture, enhancer activity of KRN4 toward UB3 promoters, and KRN4- recruited UB2-centered transcription complex for UB3 transcription. These results provide evidence that an intergenic region helps to finely tune gene expression and quantitative traits.

Published

2020

17. GRF-interacting factor1 Regulates Shoot Architecture and Meristem Determinacy in Maize[OPEN]

Author

Dan Zhang, Zuxin Zhang, China Lunde, Yuanyuan Zheng, Zheng Cao, Sarah Hake, Wei Sun, Renee Singh, and Manfei Li

Subjects

0301 basic medicine, Meristem determinacy, Positional cloning, fungi, Mutant, food and beverages, Cell Biology, Plant Science, macromolecular substances, Meristem, Biology, Phenotype, Cell biology, Chromatin, 03 medical and health sciences, 030104 developmental biology, Inflorescence, Chromatin immunoprecipitation, Research Articles

Abstract

Plant architecture results from a balance of indeterminate and determinate cell fates. Cells with indeterminate fates are located in meristems, comprising groups of pluripotent cells that produce lateral organs. Meristematic cells are also found in intercalary stem tissue, which provides cells for internodes, and at leaf margins to contribute to leaf width. We identified a maize (Zea mays) mutant that has a defect in balancing determinacy and indeterminacy. The mutant has narrow leaves and short internodes, suggesting a reduction in indeterminate cells in the leaf and stem. In contrast, the mutants fail to control indeterminacy in shoot meristems. Inflorescence meristems are fasciated, and determinate axillary meristems become indeterminate. Positional cloning identified growth regulating factor-interacting factor1 (gif1) as the responsible gene. gif1 mRNA accumulates in distinct domains of shoot meristems, consistent with tissues affected by the mutation. We determined which GROWTH REGULATING FACTORs interact with GIF1 and performed RNA-seq analysis. Many genes known to play roles in inflorescence architecture were differentially expressed in gif1 Chromatin immunoprecipitation identified some differentially expressed genes as direct targets of GIF1. The interactions with these diverse direct and indirect targets help explain the paradoxical phenotypes of maize GIF1. These results provide insights into the biological functions of gif1.

Published

2018

18. Integrated Analysis of Protein Abundance, Transcript Level, and Tissue Diversity To Reveal Developmental Regulation of Maize

Author

Wei Sun, Haitao Jia, Manfei Li, and Zuxin Zhang

Subjects

0106 biological sciences, 0301 basic medicine, Proteomics, Key genes, Proteome, Flowers, Transcript level, Biology, 01 natural sciences, Biochemistry, Plant Roots, Zea mays, Transcriptome, 03 medical and health sciences, Transcription (biology), Gene Expression Regulation, Plant, Gene expression, Gene Regulatory Networks, RNA, Messenger, Chromatography, High Pressure Liquid, Plant Proteins, Gene Expression Profiling, Gene Expression Regulation, Developmental, General Chemistry, Cell biology, 030104 developmental biology, Mrna level, Organ Specificity, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Seeds, Protein abundance, Metabolic Networks and Pathways, 010606 plant biology & botany

Abstract

The differentiation and subsequent development of plant tissues or organs are tightly regulated at multiple levels, including the transcriptional, posttranscriptional, translational, and posttranslational levels. Transcriptomes define many of the tissue-specific gene expression patterns in maize, and some key genes and their regulatory networks have been established at the transcriptional level. In this study, the sequential window acquisition of all theoretical spectra-mass spectrometry technique was employed as a quantitative proteome assay of four representative maize tissues, and a set of high-confidence proteins was identified. Integrated analysis of the proteome and transcriptome revealed that protein abundance was positively correlated with mRNA level with weak to moderate correlation coefficients, but the abundance of key proteins for function or architecture in a given tissue was closely tempospatially regulated at the transcription level. A subset of differentially expressed proteins, specifically tissue-specific highly expressed proteins, was identified, for example, reproductive structure and flower development-related proteins in tassel and ear, lipid and fatty acid biosynthetic process-related proteins in immature embryo, and inorganic substance and oxidation reduction responsive proteins in root, potentially revealing the physiology, morphology, and function of each tissue. Furthermore, we found many new proteins in specific tissues that were highly correlated with their mRNA levels, in addition to known key factors. These proteome data provide new perspective for understanding many aspects of maize developmental biology. Raw proteomics data are available via ProteomeXchange with identifier PXD008464.

Published

2017

19. UNBRANCHED3 regulates branching by modulating cytokinin biosynthesis and signaling in maize and rice

Author

Yanfang Du, Lei Liu, Jinfang Chu, Manfei Li, Xiaomeng Shen, Zuxin Zhang, and Shuang Fang

Subjects

0301 basic medicine, Cytokinins, Physiology, Mutant, Plant Science, Biology, Zea mays, 03 medical and health sciences, chemistry.chemical_compound, Gene Expression Regulation, Plant, Botany, Gene family, Regeneration, Inflorescence, Gene, Panicle, Plant Proteins, Oryza sativa, food and beverages, Oryza, Meristem, Plants, Genetically Modified, Cell biology, Biosynthetic Pathways, 030104 developmental biology, chemistry, Cytokinin, Mutation, Regulatory Pathway, Transcriptome, Signal Transduction

Abstract

Summary UNBRANCHED3 (UB3), a member of the SQUAMOSA promoter binding protein-like (SPL) gene family, regulates kernel row number by negatively modulating the size of the inflorescence meristem in maize. However, the regulatory pathway by which UB3 mediates branching remains unknown. We introduced the UB3 into rice and maize to reveal its effects in the two crop plants, respectively. Furthermore, we performed transcriptome sequencing and protein-DNA binding assay to elucidate the regulatory pathway of UB3. We found that UB3 could bind and regulate the promoters of LONELY GUY1 (LOG1) and Type-A response regulators (ARRs), which participate in cytokinin biosynthesis and signaling. Overexpression of exogenous UB3 in rice (Oryza sativa) dramatically suppressed tillering and panicle branching as a result of a greater decrease in the amount of active cytokinin. By contrast, moderate expression of UB3 suppressed tillering slightly, but promoted panicle branching by cooperating with SPL genes, resulting in a higher grain number per panicle in rice. In maize (Zea mays) ub3 mutant with an increased kernel row number, UB3 showed a low expression but cytokinin biosynthesis-related genes were up-regulated and degradation-related genes were down-regulated. These results suggest that UB3 regulates vegetative and reproductive branching by modulating cytokinin biosynthesis and signaling in maize and rice.

Published

2016

20. KRN4 Controls Quantitative Variation in Maize Kernel Row Number

Author

Wei Sun, Juan Huang, Yonglian Zheng, Yongsheng Tao, Jianbing Yan, Lei Liu, Zuxin Zhang, Zhijie Liu, Yanfang Du, Manfei Li, and Xiaomeng Shen

Subjects

Germplasm, Genetics, Cancer Research, education.field_of_study, lcsh:QH426-470, Gene Expression Profiling, Population, Haplotype, Locus (genetics), Quantitative trait locus, Biology, Genes, Plant, Zea mays, lcsh:Genetics, Inbred strain, Genetic linkage, Allele, Cloning, Molecular, education, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Research Article, Plant Proteins

Abstract

Kernel row number (KRN) is an important component of yield during the domestication and improvement of maize and controlled by quantitative trait loci (QTL). Here, we fine-mapped a major KRN QTL, KRN4, which can enhance grain productivity by increasing KRN per ear. We found that a ~3-Kb intergenic region about 60 Kb downstream from the SBP-box gene Unbranched3 (UB3) was responsible for quantitative variation in KRN by regulating the level of UB3 expression. Within the 3-Kb region, the 1.2-Kb Presence-Absence variant was found to be strongly associated with quantitative variation in KRN in diverse maize inbred lines, and our results suggest that this 1.2-Kb transposon-containing insertion is likely responsible for increased KRN. A previously identified A/G SNP (S35, also known as Ser220Asn) in UB3 was also found to be significantly associated with KRN in our association-mapping panel. Although no visible genetic effect of S35 alone could be detected in our linkage mapping population, it was found to genetically interact with the 1.2-Kb PAV to modulate KRN. The KRN4 was under strong selection during maize domestication and the favorable allele for the 1.2-Kb PAV and S35 has been significantly enriched in modern maize improvement process. The favorable haplotype (Hap1) of 1.2-Kb-PAV-S35 was selected during temperate maize improvement, but is still rare in tropical and subtropical maize germplasm. The dissection of the KRN4 locus improves our understanding of the genetic basis of quantitative variation in complex traits in maize., Author Summary Maize (Zea mays L.) is one of the world's most important sources of calories for humans. With an expanding global population, the demands for maize-derived food, feed, and fuel are rapidly increasing. To meet these needs, geneticists and breeders are facing the challenge of enhancing grain yield through genetic improvement of maize germplasm. Understanding the genetic basis of grain yield is necessary to guide breeding efforts towards the development of high-yielding hybrids. Kernel row number (KRN) in maize is one of the most important yield components and a significant breeding target. Over the last few decades, many genes that determine inflorescence development and architecture have been identified and characterized. The formation of kernel rows is an integral part of the development of the female inflorescence in maize. Nevertheless, the genetic basis and molecular regulation of quantitative variation in KRN is poorly understood. This study provides experimental evidence for the hypothesis that variation in intergenic regions can regulate quantitative variation of important grain yield-related traits, and also provides tools for improving KRN in maize.

Published

2015

21. Integrated Analysis of Protein Abundance, Transcript Level, and Tissue Diversity To Reveal Developmental Regulation of Maize.

Author

Haitao Jia, Wei Sun, Manfei Li, and Zuxin Zhang

Published

2018