Your search keyword '"Thiya Mukherjee"' showing total 5 results

1. START domain mediates Arabidopsis GLABRA2 transcription factor dimerization and turnover independently of homeodomain DNA binding

Author

Thiya Mukherjee, Bibek Subedi, Aashima Khosla, Erika M. Begler, Preston M. Stephens, Adara L. Warner, Ruben Lerma-Reyes, Kyle A. Thompson, Sumedha Gunewardena, and Kathrin Schrick

Subjects

chemistry.chemical_compound, chemistry, biology, Arabidopsis, Mutant, Homeobox, Cycloheximide, biology.organism_classification, Phenotype, Transcription factor, DNA, Nuclear localization sequence, Cell biology

Abstract

Class IV homeodomain leucine-zipper transcription factors (HD-Zip IV TFs) are key regulators of epidermal differentiation that are characterized by a DNA-binding homeodomain (HD) in conjunction with a lipid-binding domain termed START (Steroidogenic Acute Regulatory (StAR)-related lipid Transfer). Previous work established that the START domain of GLABRA2 (GL2), a HD-Zip IV member from Arabidopsis, is required for transcription factor activity. Here, we address the functions and possible interactions of START and the HD in DNA binding, dimerization, and protein turnover. Deletion analysis of the HD and missense mutations of a conserved lysine (K146) result in phenotypic defects in leaf trichomes, root hairs and seed mucilage, similar to those observed for START domain mutants, despite nuclear localization of the respective proteins. In vitro and in vivo experiments demonstrate that while HD mutations impair binding to target DNA, the START domain is dispensable for DNA binding. Vice versa, protein interaction assays reveal impaired GL2 dimerization for multiple alleles of START mutants, but not HD mutants. Using in vivo cycloheximide chase experiments, we provide evidence for the role of START, but not HD, in maintaining protein stability. This work advances our mechanistic understanding of HD-Zip TFs as multidomain regulators of epidermal development in plants.

Published

2021

2. Arabidopsis PROTODERMAL FACTOR2 binds lysophosphatidylcholines and transcriptionally regulates phospholipid metabolism

Author

Kyle A. Thompson, Graham L. Mathews, Seth T. Peery, Anja Thalhammer, Aashima Khosla, Thiya Mukherjee, Xueyun Hu, Aleksandra Skirycz, Dirk K. Hincha, Jagoda Szlachetko, Kathrin Schrick, Patrick Knox-Brown, and Izabela Wojciechowska

Subjects

Tandem affinity purification, chemistry.chemical_compound, Protein destabilization, biology, Chemistry, Arabidopsis, Response element, Phospholipid homeostasis, Cycloheximide, biology.organism_classification, Ligand (biochemistry), Transcription factor, Cell biology

Abstract

Plant homeodomain leucine-zipper IV (HD-Zip IV) transcription factors (TFs) contain an evolutionarily conserved steroidogenic acute regulatory protein (StAR)-related lipid transfer (START) domain. The START domain is required for TF activity; however, its presumed role as a lipid sensor is not well understood. Here we used tandem affinity purification from Arabidopsis cell cultures to demonstrate that PROTODERMAL FACTOR2 (PDF2), a representative family member which controls epidermal differentiation, recruits lysophosphatidylcholines in a START-dependent manner. In vitro assays with recombinant protein verified that a missense mutation in a predicted ligand contact site reduces lysophospholipid binding. We additionally uncovered that PDF2 controls the expression of phospholipid-related target genes by binding to a palindromic octamer with consensus to a phosphate (Pi) response element. Phospholipid homeostasis and elongation growth were altered in pdf2 mutants according to Pi availability. Cycloheximide chase experiments further revealed a role for START in maintaining protein levels, and Pi limitation resulted in enhanced protein destabilization, suggesting a mechanism by which lipid binding controls TF activity. We propose that the START domain serves as a molecular sensor for membrane phospholipid status in the epidermis. Overall our data provide insights towards understanding how the lipid metabolome integrates Pi availability with gene expression.

Published

2021

3. A four-gene operon in Bacillus cereus produces two rare spore-decorating sugars

Author

Zachary Snow, Maor Bar-Peled, Sholeh Namdari, Sarah Prestridge, Thiya Mukherjee, Alexandra Carlton, Kyle Bowler, and Zi Li

Subjects

0301 basic medicine, Glycosylation, biology, Operon, Bacterial Glycan, fungi, 030106 microbiology, Bacillus cereus, Bacillus, Cell Biology, biology.organism_classification, Biochemistry, Spore, Microbiology, Bacillus anthracis, carbohydrates (lipids), 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Cereus, chemistry, Molecular Biology

Abstract

Bacterial glycan structures on cell surfaces are critical for cell-cell recognition and adhesion and in host-pathogen interactions. Accordingly, unraveling the sugar composition of bacterial cell surfaces can shed light on bacterial growth and pathogenesis. Here, we found that two rare sugars with a 3-C-methyl-6-deoxyhexose structure were linked to spore glycans in Bacillus cereus ATCC 14579 and ATCC 10876. Moreover, we identified a four-gene operon in B. cereus ATCC 14579 that encodes proteins with the following sequential enzyme activities as determined by mass spectrometry and one- and two-dimensional NMR methods: CTP:glucose-1-phosphate cytidylyltransferase, CDP-Glc 4,6-dehydratase, NADH-dependent SAM:C-methyltransferase, and NADPH-dependent CDP-3-C-methyl-6-deoxyhexose 4-reductase. The last enzyme predominantly yielded CDP-3-C-methyl-6-deoxygulose (CDP-cereose) and likely generated a 4-epimer CDP-3-C-methyl-6-deoxyallose (CDP-cillose). Some members of the B. cereus sensu lato group produce CDP-3-C-methyl-6-deoxy sugars for the formation of cereose-containing glycans on spores, whereas others such as Bacillus anthracis do not. Gene knockouts of the Bacillus C-methyltransferase and the 4-reductase confirmed their involvement in the formation of cereose-containing glycan on B. cereus spores. We also found that cereose represented 0.2-1% spore dry weight. Moreover, mutants lacking cereose germinated faster than the wild type, yet the mutants exhibited no changes in sporulation or spore resistance to heat. The findings reported here may provide new insights into the roles of the uncommon 3-C-methyl-6-deoxy sugars in cell-surface recognition and host-pathogen interactions of the genus Bacillus.

Published

2017

4. Bioorthogonal click chemistry for fluorescence imaging of choline phospholipids in plants

Author

Kathrin Schrick, Janet M. Paper, and Thiya Mukherjee

Subjects

0106 biological sciences, 0301 basic medicine, Cell signaling, Arabidopsis thaliana, Membrane lipids, Phospholipid, Fluorescence labeling, Plant Science, lcsh:Plant culture, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Phosphatidylcholine, Genetics, Propargylcholine, Choline, lcsh:SB1-1110, lcsh:QH301-705.5, Phospholipids, Alexa Fluor, Click chemistry, fungi, Methodology, food and beverages, Plant cell, ESI-MS/MS, 030104 developmental biology, Membrane, lcsh:Biology (General), chemistry, Biochemistry, lipids (amino acids, peptides, and proteins), 010606 plant biology & botany, Biotechnology

Abstract

Background Phospholipids are important structural and signaling molecules in plant membranes. Some fluorescent dyes can stain general lipids of membranes, but labeling and visualization of specific lipid classes have yet to be developed for most components of the membrane. New techniques for visualizing membrane lipids are needed to further delineate their dynamic structural and signaling roles in plant cells. In this study we examined whether propargylcholine, a bioortholog of choline, can be used to label the major membrane lipid, phosphatidylcholine, and other choline phospholipids in plants. We established that propargylcholine is readily taken up by roots, and that its incorporation is not detrimental to plant growth. After plant tissue is harvested and fixed, a click-chemistry reaction covalently links the alkyne group of propargylcholine to a fluorescently-tagged azide, resulting in specific labeling of choline phospholipids. Results Uptake of propargylcholine, followed by click chemistry with fluorescein or Alexa Fluor 594 azide was used to visualize choline phospholipids in cells of root, leaf, stem, silique and seed tissues from Arabidopsis thaliana. Co-localization with various subcellular markers indicated coinciding fluorescent signals in cell membranes, such as the tonoplast and the ER. Among different cell types in the leaf epidermis, guard cells displayed strong labeling. Mass spectrometry-based lipidomic analysis of the various plant tissues revealed that incorporation of propargylcholine was strongest in roots with approximately 50% of total choline phospholipids being labeled, but it was also incorporated in the other tissues including seeds. Phospholipid profiling confirmed that, in each tissue analyzed, incorporation of the bioortholog had little impact on the pool of choline plus choline-like phospholipids or other lipid species. Conclusion We developed and validated a click-chemistry based method for fluorescence imaging of choline phospholipids using a bioortholog of choline, propargylcholine, in various cell-types and tissues from Arabidopsis. This click-chemistry method provides a direct way to metabolically tag and visualize specific lipid molecules in plant cells. This work paves the way for future studies addressing in situ localization of specific lipids in plants. Electronic supplementary material The online version of this article (10.1186/s13007-018-0299-2) contains supplementary material, which is available to authorized users.

Published

2018

5. Constitutively overexpressing a tomato fructokinase gene (LeFRK1) in cotton (Gossypium hirsutum L. cv. Coker 312) positively affects plant vegetative growth, boll number and seed cotton yield

Author

David Granot, Yoshinori Kanayama, Thiya Mukherjee, Marisela Dagda, A. Scott Holaday, and Mariana Ivanova

Subjects

Ecophysiology, Sucrose, biology, Vegetative reproduction, fungi, food and beverages, Fructose, Plant Science, biology.organism_classification, Photosynthesis, Fructokinase, chemistry.chemical_compound, chemistry, Agronomy, biology.protein, Sucrose synthase, Solanum, Agronomy and Crop Science

Abstract

Increasing fructokinase (FRK) activity in cotton (Gossypium hirsutum L.) plants may reduce fructose inhibition of sucrose synthase (Sus) and lead to improved fibre yield and quality. Cotton was transformed with a tomato (Solanum lycopersicum L.) fructokinase gene (LeFRK1) under the control of the CMV 35S promoter. In a greenhouse, the LeFRK1 plants had increased fibre and leaf FRK activity over nonexpressing nulls, but not improved fibre length and strength. Compared with the nulls, LeFRK1 plants yielded 13–100% more seed-cotton mass per boll and more bolls per plant, and therefore more seed cotton and fibre yield per plant. The enhanced yield was related to a greater seed number per boll for LeFRK1 plants. Photosynthetic rates were not appreciably different among genotypes. However, more area per leaf and leaf number (in some instances) for LeFRK1 plants than for nulls enhanced the capacity for C gain. Larger leaf areas for LeFRK1 plants were associated with larger stem diameters. Lower sucrose levels in developing leaves of LeFRK1 plants suggest that LeFRK1 overexpression leads to improved in vivo Sus activity in developing leaves and possibly in developing seeds. The improvement in yield for LeFRK1 plants may also be the result of improvements in photosynthate supply as a consequence of greater leaf area.

Published

2015