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115 results on '"Larkin, Robert M"'

104. Intracellular Signaling and Chlorophyll Synthesis.

Author

Govindjee, Eaton-Rye, Julian, Foyer, Christine H., Knaff, David B., Merchant, Sabeeha, Moore, Anthony L., Niyogi, Krishna, Parson, William, Raghavendra, Agepati, Renger, Gernot, Demmig-Adams, Barbara, Adams, William W., Mattoo, Autar, and Larkin, Robert M.

Abstract

The chloroplast proteome is encoded by genes that reside in both the chloroplast and the nucleus. This separation of genetic material necessitates a system for coordinating the expression of genes that reside in each compartment. Because the overwhelming majority of genes that encode chloroplast proteins reside in the nucleus, the regulation of nuclear genes by developmental and environmental cues plays a dominant role in chloroplast development and function. However, the chloroplast is not indifferent to its own protein composition. In fact, the chloroplast generates signals that have dramatic effects on the expression of nuclear genes that encode particular chloroplast proteins. Currently it is known that plastids produce at least a few distinct signals during chloroplast development that are required for proper expression of particular nuclear genes that encode components of the photosynthetic machinery. In response to certain environmental signals, mature chloroplasts send additional signals that regulate nuclear gene expression. The molecular nature of most of these plastid-to-nucleus signaling pathways is not well established. However, a number of studies have suggested that accumulation of certain chlorophyll precursors within plastids is a signal that regulates nuclear gene expression during chloroplast development and during the diurnal cycle. Future work in this area should provide detailed molecular information on the influence of chlorophyll synthesis and other plastid-localized metabolism on nuclear gene expression and howplants utilize this formof interorganellar communication during their lifecycles. [ABSTRACT FROM AUTHOR]

Published
2006
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105. A membrane-tethered transcription factor defines a branch of the heat stress response in Arabidopsis thaliana.

Author

Hongbo Gao, Brandizzi, Federica, Benning, Christoph, and Larkin, Robert M.

Subjects
PHYSIOLOGICAL effects of heat, ARABIDOPSIS thaliana, ARABIDOPSIS, ENDOPLASMIC reticulum, GENES
Abstract

In plants, heat stress responses are controlled by heat stress transcription factors that are conserved among all eukaryotes and can be constitutively expressed or induced by heat. Heat-inducible transcription factors that are distinct from the "classical" heat stress transcription factors have also been reported to contribute to heat tolerance. Here, we show that bZIP28, a gene encoding a putative membrane-tethered transcription factor, is up-regulated in response to heat and that a bZIP28 null mutant has a striking heat-sensitive phenotype. The heat-inducible expression of genes that encode BiP2, an endoplasmic reticulum (ER) chaperone, and HSP26.5-P, a small heat shock protein, is attenuated in the bZIP28 null mutant. An estradiol-inducible bZIP28 transgene induces a variety of heat and ER stress-inducible genes. Moreover, heat stress appears to induce the proteolytic release of the predicted transcription factor domain of bZIP28 from the ER membrane, thereby causing its redistribution to the nucleus. These findings indicate that bZIP28 is an essential component of a membrane-tethered transcription factor-based signaling pathway that contributes to heat tolerance. [ABSTRACT FROM AUTHOR]

Published
2008
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106. Cell wall remodeling confers plant architecture with distinct wall structure in Nelumbo nucifera.

Author

Hu, Huizhen, Zhang, Ran, Zhao, Yongjing, Yang, Jie, Zhao, Hanqian, Zhao, Lin, Wang, Li, Cheng, Zhipeng, Zhao, Wanyue, Wang, Bo, Larkin, Robert M., and Chen, Longqing

Abstract

SUMMARY Lotus (Nelumbo nucifera G.) is a perennial aquatic horticultural plant with diverse architectures. Distinct plant architecture (PA) has certain attractive and practical qualities, but its genetic morphogenesis in lotus remains elusive. In this study, we employ genome‐wide association analysis (GWAS) for the seven traits of petiole length (PLL), leaf length (LL), leaf width (LW), peduncle length (PLF), flower diameter (FD), petal length (PeL), and petal width (PeW) in 301 lotus accessions. A total of 90 loci are identified to associate with these traits across 4 years of trials. Meanwhile, we perform RNA sequencing (RNA‐seq) to analyze the differential expression of the gene (DEG) transcripts between large and small PA (LPA and SPA) of lotus stems (peduncles and petioles). As a result, eight key candidate genes are identified that are all primarily involved in plant cell wall remodeling significantly associated with PA traits by integrating the results of DEGs and GWAS. To verify this result, we compare the cell wall compositions and structures of LPA versus SPA in representative lotus germplasms. Intriguingly, compared with the SPA lotus, the LPA varieties have higher content of cellulose and hemicellulose, but less filling substrates of pectin and lignin. Additionally, we verified longer cellulose chains and higher cellulose crystallinity with less interference in LPA varieties. Taken together, our study illustrates how plant cell wall remodeling affects PA in lotus, shedding light on the genetic architecture of this significant ornamental trait and offering a priceless genetic resource for future genomic‐enabled breeding. [ABSTRACT FROM AUTHOR]

Published
2024
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107. Downregulated expression of S2-RNaseattenuates self-incompatibility in “Guiyou No. 1” pummelo

Author

Hu, Jianbing, Xu, Qiang, Liu, Chenchen, Liu, Binghao, Deng, Chongling, Chen, Chuanwu, Wei, Zhuangmin, Ahmad, Muhammad Husnain, Peng, Kang, Wen, Hao, Chen, Xiangling, Chen, Peng, Larkin, Robert M., Ye, Junli, Deng, Xiuxin, and Chai, Lijun

Abstract

Self-incompatibility (SI) substantially restricts the yield and quality of citrus. Therefore, breeding and analyzing self-compatible germplasm is of great theoretical and practical significance for citrus. Here, we focus on the mechanism of a self-compatibility mutation in ‘Guiyou No. 1’ pummelo (Citrus maxima), which is a spontaneous mutant of ‘Shatian’ pummelo (Citrus maxima, self-incompatibility). The rate of fruit set and the growth of pollen tubes in the pistil confirmed that a spontaneous mutation in the pistil is responsible for the self-compatibility of ‘Guiyou No. 1’. Segregation ratios of the Sgenotype in F1progeny, expression analysis, and western blotting validated that the reduced levels of S2-RNasemRNA contribute to the loss of SI in ‘Guiyou No. 1’. Furthermore, we report a phased assembly of the ‘Guiyou No. 1’ pummelo genome and obtained two complete and well-annotated Shaplotypes. Coupled with an analysis of SV variations, methylation levels, and gene expression, we identified a candidate gene (CgHB40), that may influence the regulation of the S2-RNasepromoter. Our data provide evidence that a mutation that affects the pistil led to the loss of SI in ‘Guiyou No. 1’ by influencing a poorly understood mechanism that affects transcriptional regulation. This work significantly advances our understanding of the genetic basis of the SI system in citrus and provides information on the regulation of S-RNasegenes.

Published
2021
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108. Characterization of four polymorphic genes controlling red leaf colour in lettuce that have undergone disruptive selection since domestication.

Author

Su, Wenqing, Tao, Rong, Liu, Wenye, Yu, Changchun, Yue, Zhen, He, Shuping, Lavelle, Dean, Zhang, Weiyi, Zhang, Lei, An, Guanghui, Zhang, Yu, Hu, Qun, Larkin, Robert M., Michelmore, Richard W., Kuang, Hanhui, and Chen, Jiongjiong

Subjects
*LETTUCE, *DOMESTICATION of animals, *COLOR of plants, *GENES, *TRANSCRIPTION factors, *BIOSYNTHESIS, *CELLULAR signal transduction
Abstract

Summary: Anthocyanins protect plants from biotic and abiotic stressors and provide great health benefits to consumers. In this study, we cloned four genes (Red Lettuce Leaves 1 to 4: RLL1 to RLL4) that contribute to colour variations in lettuce. The RLL1 gene encodes a bHLH transcription factor, and a 5‐bp deletion in some cultivars abolishes its function to activate the anthocyanin biosynthesis pathway. The RLL2 gene encodes an R2R3‐MYB transcription factor, which was derived from a duplication followed by mutations in its promoter region. The RLL3 gene encodes an R2‐MYB transcription factor, which down‐regulates anthocyanin biosynthesis through competing with RLL2 for interaction with RLL1; a mis‐sense mutation compromises the capacity of RLL3 to bind RLL1. The RLL4 gene encodes a WD‐40 transcription factor, homologous to the RUP genes suppressing the UV‐B signal transduction pathway in Arabidopsis; a mis‐sense mutation in rll4 attenuates its suppressing function, leading to a high concentration of anthocyanins. Sequence analysis of the RLL1‐RLL4 genes from wild and cultivated lettuce showed that their function‐changing mutations occurred after domestication. The mutations in rll1 disrupt anthocyanin biosynthesis, while the mutations in RLL2, rll3 and rll4 activate anthocyanin biosynthesis, showing disruptive selection for leaf colour during domestication of lettuce. The characterization of multiple polymorphic genes in this study provides the necessary molecular resources for the rational breeding of lettuce cultivars with distinct levels of red pigments and green cultivars with high levels of health‐promoting flavonoids. [ABSTRACT FROM AUTHOR]

Published
2020
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110. REDUCED CHLOROPLAST COVERAGE proteins are required for plastid proliferation and carotenoid accumulation in tomato.

Author

Hu Q, Zhang H, Song Y, Song L, Zhu L, Kuang H, and Larkin RM

Subjects
Plant Proteins metabolism, Plant Proteins genetics, Mutation genetics, Plant Leaves metabolism, Plant Leaves genetics, Chlorophyll metabolism, Abscisic Acid metabolism, Chloroplast Proteins metabolism, Chloroplast Proteins genetics, Ethylenes metabolism, Flowers genetics, Flowers metabolism, Flowers growth & development, Solanum lycopersicum genetics, Solanum lycopersicum metabolism, Solanum lycopersicum growth & development, Carotenoids metabolism, Plastids metabolism, Plastids genetics, Fruit metabolism, Fruit genetics, Fruit growth & development, Gene Expression Regulation, Plant, Chloroplasts metabolism
Abstract

Increasing the amount of cellular space allocated to plastids will lead to increases in the quality and yield of crop plants. However, mechanisms that allocate cellular space to plastids remain poorly understood. To test whether the tomato (Solanum lycopersicum L.) REDUCED CHLOROPLAST COVERAGE (SlREC) gene products serve as central components of the mechanism that allocates cellular space to plastids and contribute to the quality of tomato fruit, we knocked out the 4-member SlREC gene family. We found that slrec mutants accumulated lower levels of chlorophyll in leaves and fruits, accumulated lower levels of carotenoids in flowers and fruits, allocated less cellular space to plastids in leaf mesophyll and fruit pericarp cells, and developed abnormal plastids in flowers and fruits. Fruits produced by slrec mutants initiated ripening later than wild type and produced abnormal levels of ethylene and abscisic acid (ABA). Metabolome and transcriptome analyses of slrec mutant fruits indicated that the SlREC gene products markedly influence plastid-related gene expression, primary and specialized metabolism, and the response to biotic stress. Our findings and previous work with distinct species indicate that REC proteins help allocate cellular space to plastids in diverse species and cell types and, thus, play a central role in allocating cellular space to plastids. Moreover, the SlREC proteins are required for the high-level accumulation of chlorophyll and carotenoids in diverse organs, including fruits, promote the development of plastids and influence fruit ripening by acting both upstream and downstream of ABA biosynthesis in a complex network., Competing Interests: Conflict of interest statement. None declared., (© The Author(s) 2024. Published by Oxford University Press on behalf of American Society of Plant Biologists. All rights reserved. For commercial re-use, please contact reprints@oup.com for reprints and translation rights for reprints. All other permissions can be obtained through our RightsLink service via the Permissions link on the article page on our site—for further information please contact journals.permissions@oup.com.)

Published
2024
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111. Pangenome analysis provides insight into the evolution of the orange subfamily and a key gene for citric acid accumulation in citrus fruits.

Author

Huang Y, He J, Xu Y, Zheng W, Wang S, Chen P, Zeng B, Yang S, Jiang X, Liu Z, Wang L, Wang X, Liu S, Lu Z, Liu Z, Yu H, Yue J, Gao J, Zhou X, Long C, Zeng X, Guo YJ, Zhang WF, Xie Z, Li C, Ma Z, Jiao W, Zhang F, Larkin RM, Krueger RR, Smith MW, Ming R, Deng X, and Xu Q

Subjects
Citric Acid metabolism, Fruit genetics, China, Citrus genetics, Citrus metabolism, Citrus sinensis genetics, Citrus sinensis metabolism
Abstract

The orange subfamily (Aurantioideae) contains several Citrus species cultivated worldwide, such as sweet orange and lemon. The origin of Citrus species has long been debated and less is known about the Aurantioideae. Here, we compiled the genome sequences of 314 accessions, de novo assembled the genomes of 12 species and constructed a graph-based pangenome for Aurantioideae. Our analysis indicates that the ancient Indian Plate is the ancestral area for Citrus-related genera and that South Central China is the primary center of origin of the Citrus genus. We found substantial variations in the sequence and expression of the PH4 gene in Citrus relative to Citrus-related genera. Gene editing and biochemical experiments demonstrate a central role for PH4 in the accumulation of citric acid in citrus fruits. This study provides insights into the origin and evolution of the orange subfamily and a regulatory mechanism underpinning the evolution of fruit taste., (© 2023. The Author(s), under exclusive licence to Springer Nature America, Inc.)

Published
2023
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112. Variation in the fruit development gene POINTED TIP regulates protuberance of tomato fruit tip.

Author

Song J, Shang L, Li C, Wang W, Wang X, Zhang C, Ai G, Ye J, Yang C, Li H, Hong Z, Larkin RM, Ye Z, and Zhang J

Subjects
Arginine genetics, Fruit metabolism, Gene Expression Regulation, Plant, Genome-Wide Association Study, Histidine genetics, Indoleacetic Acids, Plant Proteins genetics, Plant Proteins metabolism, Transcription Factors genetics, Solanum lycopersicum
Abstract

The domestication of tomato has led to striking variations in fruit morphology. Here, we show a genome-wide association study (GWAS) to understand the development of the fruit tip and describe a POINTED TIP (PT) gene that encodes a C2H2-type zinc finger transcription factor. A single nucleotide polymorphism is found to change a histidine (H) to an arginine (R) in the C2H2 domain of PT and the two alleles are referred to as PT H and PT R . Knocking out PT H leads to development of pointed tip fruit. PT H functions to suppress pointed tip formation by downregulating the transcription of FRUTFULL 2 (FUL2), which alters the auxin transport. Our evolutionary analysis and previous studies by others suggest that the PT R allele likely hitch-hiked along with other selected loci during the domestication process. This study uncovers variation in PT and molecular mechanism underlying fruit tip development in tomato., (© 2022. The Author(s).)

Published
2022
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113. Upregulation of a KN1 homolog by transposon insertion promotes leafy head development in lettuce.

Author

Yu C, Yan C, Liu Y, Liu Y, Jia Y, Lavelle D, An G, Zhang W, Zhang L, Han R, Larkin RM, Chen J, Michelmore RW, and Kuang H

Subjects
Base Sequence, Gene Duplication, Genes, Plant, Lactuca anatomy & histology, Phylogeny, Plant Leaves anatomy & histology, Plant Proteins chemistry, Promoter Regions, Genetic genetics, Protein Binding, Quantitative Trait Loci genetics, Sequence Homology, Nucleic Acid, Transcription, Genetic, DNA Transposable Elements genetics, Gene Expression Regulation, Plant, Lactuca genetics, Mutagenesis, Insertional genetics, Plant Leaves genetics, Plant Leaves growth & development, Plant Proteins genetics, Up-Regulation genetics
Abstract

Leafy head is a unique type of plant architecture found in some vegetable crops, with leaves bending inward to form a compact head. The genetic and molecular mechanisms underlying leafy head in vegetables remain poorly understood. We genetically fine-mapped and cloned a major quantitative trait locus controlling heading in lettuce. The candidate gene ( LsKN1 ) is a homolog of knotted 1 ( KN1 ) from Zea mays Complementation and CRISPR/Cas9 knockout experiments confirmed the role of LsKN1 in heading. In heading lettuce, there is a CACTA-like transposon inserted into the first exon of LsKN1 ( LsKN1 ▽). The transposon sequences act as a promoter rather than an enhancer and drive high expression of LsKN1 ▽. The enhanced expression of LsKN1 ▽ is necessary but not sufficient for heading in lettuce. Data from ChIP-sequencing, electrophoretic mobility shift assays, and dual luciferase assays indicate that the LsKN1▽ protein binds the promoter of LsAS1 and down-regulates its expression to alter leaf dorsoventrality. This study provides insight into plant leaf development and will be useful for studies on heading in other vegetable crops., Competing Interests: The authors declare no competing interest.

Published
2020
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114. Influence of plastids on light signalling and development.

Author

Larkin RM

Subjects
Arabidopsis genetics, Arabidopsis Proteins genetics, DNA-Binding Proteins genetics, Genetic Testing, Mutation genetics, Arabidopsis growth & development, Arabidopsis Proteins metabolism, Cell Nucleus physiology, Chloroplasts metabolism, DNA-Binding Proteins metabolism, Light Signal Transduction physiology, Plastids physiology
Abstract

In addition to their contribution to metabolism, chloroplasts emit signals that influence the expression of nuclear genes that contribute to numerous plastidic and extraplastidic processes. Plastid-to-nucleus signalling optimizes chloroplast function, regulates growth and development, and affects responses to environmental cues. An incomplete list of plastid signals is available and particular plastid-to-nucleus signalling mechanisms are partially understood. The plastid-to-nucleus signalling that depends on the GENOMES UNCOUPLED (GUN) genes couples the expression of nuclear genes to the functional state of the chloroplast. Analyses of gun mutants provided insight into the mechanisms and biological functions of plastid-to-nucleus signalling. GUN genes contribute to chloroplast biogenesis, the circadian rhythm, stress tolerance, light signalling and development. Some have criticized the gun mutant screen for employing inhibitors of chloroplast biogenesis and suggested that gun alleles do not disrupt significant plastid-to-nucleus signalling mechanisms. Here, I briefly review GUN-dependent plastid-to-nucleus signalling, explain the flaws in the major criticisms of the gun mutant screen and review the influence of plastids on light signalling and development.

Published
2014
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