Charng Yee-yung, Chen Chun-Jen (2023) Letter to the Editor: The Role of HSFA2 in Within-Generational Plasticity and Transgenerational Memory of the Heat-Induced Early Flowering Phenotype in Arabidopsis. Plant And Cell Physiology, 64 (11), 1383-1385
(Yee-yung Charng*), Chun-Jen Chen (2023) The role of HSFA2 in within-generational plasticity and transgenerational memory of heat-induced early flowering phenotype in Arabidopsis.. Plant and Cell Physiology, 64: 1383–1385
(Yee-yung Charng*), Suma Mitra, Shih-Jiun Yu (2023) Maintenance of abiotic stress memory in plants: Lessons learned from heat acclimation. PLANT CELL, 35, 187–200
Yao-Pin Lin*, Yu-Yen Shen, Yen-Bin Shiu, (Yee-yung Charng), Bernhard Grimm (2022) Chlorophyll dephytylase 1 and chlorophyll synthase: a chlorophyll salvage pathway for the turnover of photosystems I and II. Plant Journal, 111, 979-994
Chia-Ying Lin, Hsin-Hung Yeh, Kuo-Chen Yeh, Yee-yung Charng* (2022) Priming and Memory of Plant Stress Responses. 植物逆境反應的預啟(Priming) 與記憶 (In Chinese). Taiwan J. Agri. Chem. Food Sci. 台灣農業化學與食品科學, 60(2): 68-72
Lin YP*, Charng YY* (2021) Chlorophyll dephytylation in chlorophyll metabolism: a simple reaction catalyzed by various enzymes. Plant Science, 302, 110682
Szaker HM, Darkó É, Medzhiradszky AR, Janda T, Liu HC, Charng YY, Csorba T* (2019) miR824/AGAMOUS-LIKE16 module integrates recurring environmental heat stress changes to fine-tune post-stress development. Frontiers in Plant Science, 10, 1454
Rytz TC, Miller MJ, McLoughlin F, Augustine RC, Marshall RS, Juan YT, Charng YY, Scalf M, Smith LM, Vierstra RD* (2018) Sumoylome profiling in Arabidopsis reveals a diverse array of nuclear targets modified by the sumo ligase SIZ1 during heat stress. Plant Cell, 30(5), 1077-1099
Liu HC, Lämke J, Lin SY, Hung MJ, Liu KM, Charng YY*, Bäurle I* (2018) Distinct heat shock factors and chromatin modifications mediate the organ‐autonomous transcriptional memory of heat stress. Plant Journal, 95(3), 401-413
Vicente J, Mendiondo GM, Movahedi M, Peirats-Llobet M, Juan YT, Shen YY, Dambire C, Smart K, Rodriguez PL, Charng YY, Gray JE, Holdsworth MJ* (2017) The Cys-Arg/N-End Rule Pathway Is a General Sensor of Abiotic Stress in Flowering Plants. Current biology : CB, 27(20), 3183-3190.e4
Lin YP, Charng YY* (2017) Supraoptimal activity of CHLOROPHYLL DEPHYTYLASE1 results in an increase in tocopherol level in mature arabidopsis seeds. Plant Signaling & Behavior, e1382797
Merret R, Carpenier MC, Favory, JJ, Picart C, Descombin J, Bousquet-Antonelli C, Tillard P, Lejay L, Deragon JM, Charng YY* (2017) Heat-shock protein HSP101 affects the release of ribosomal protein mRNAs for recovery after heat shock. Plant Physiology, 174(2), 1216-1225
Lin YP, Wu MC, Charng YY* (2016) Identification of chlorophyll dephytylase involved in chlorophyll turnover in Arabidopsis. Plant Cell, 28, 2974-2990
Merret R, Nagarajan VK, Carpentier MC, Park S, Favory JJ, Descombin J, Picart C, Charng YY, Green P, Deragon JM, and Bousquet-Antonelli C* (2015) Heat-induced ribosome pausing triggers mRNA co-translational decay in Arabidopsis thaliana. NUCLEIC ACIDS RESEARCH, 43(8), 4121-4132
Kuo HF, Chang TY, Chiang SF, Wang WD, Charng YY, and Chiou TJ* (2014) Arabidopsis inositol pentakisphosphate 2-kinase, AtIPK1, modulates phosphate homeostasis via transcriptional regulation. Plant Journal, 80(3), 503-515
Lin YP, Lee TY, Tanaka A, Charng YY* (2014) Analysis of an Arabidopsis Heat-sensitive Mutant Reveals that Chlorophyll Synthase is Involved in Reutilization of Chlorophyllide during Chlorophyll Turnover. Plant Journal, 80, 14-26
Lin MY, Chai KH, Ko SS, Kuang LY, Lur HS, Charng YY* (2014) A positive feedback loop between HSP101 and HSA32 modulates long-term acquired thermotolerance illustrating diverse heat stress responses in rice varieties. Plant Physiology, 164(4), 2045-2053
Wu TY, Juan YT, Hsu YH, Wu SH, Liao HT, Fung RWM, and Charng YY* (2013) Interplay between Heat Shock Proteins, HSP101 and HSA32, Prolongs Heat Acclimation Memory Posttranscriptionally in Arabidopsis. Plant Physiology, 161, 2075-2084
Liu HC and Charng YY* (2013) Common and Distinct Functions of Arabidopsis Class A1 and A2 Heat Shock Factors in Diverse Abiotic Stress Responses and Development. Plant Physiology, 163(1), 276-290
Merret R, Descombin J, Juan YT, Favory JJ, Marie-Christine Carpentier MC, Cristian Chaparro C, Charng YY, Deragon JM, and Bousquet-Antonelli C* (2013) XRN4 and LARP1 Are Required for a Heat-Triggered mRNA Decay Pathway Involved in Plant Acclimation and Survival during Thermal Stress. Cell Reports, 5(5), 1279-1293
Hu C, Lin SY, Chi WT, and Charng YY* (2012) Recent gene duplication and subfunctionalization produced a mitochondrial GrpE, the nucleotide exchange factor of Hsp70 complex, specialized in thermotolerance to chronic heat stress in Arabidopsis. Plant Physiology, 158(2), 747-758
Liu HC and Charng YY* (2012) Acquired thermotolerance independent of heat shock factor A1 (HsfA1), the master regulator of the heat stress response. Plant Singaling & Behavior, 7(5), 547-550
Yeh CH, Kaplinsky NJ, Hu C, and Charng YY* (2012) Some like It hot, some like It warm: phenotyping to explore thermotolerance diversity. Plant Science, 195, 10-23
Liu HC, Liao HT, and Charng YY* (2011) The role of class A1 heat shock factors (HSFA1s) in response to heat and other stresses in Arabidopsis. Plant Cell & Environment, 34(5), 738-751
Chi WT, Fung RWM, Liu HC, Hsu CC, and Charng YY* (2009) Temperature-Induced Lipocalin Is Required for Basal and Acquired Thermotolerance in Arabidopsis. Plant Cell & Environment, 32(7), 917-927
Chang SH, Lu LS, Wang NN, and Charng YY* (2008) Negative feedback regulation of system-1 ethylene production by the tomato 1-aminocyclopropane-1-carboxylate synthase 6 gene promoter. Plant Science, 175(1-2), 149-160
Charng YY*, Liu HC, Liu NY, Chi WT, Wang CN, Chang SH, and Wang TT (2007) A heat-inducible transcription factor, HsfA2, is required for extension of acquired thermotolerance in Arabidopsis. Plant Physiology, 143(1), 251-262
Charng YY*, Liu HC, Liu NY, Hsu FC, and Ko SS (2006) Arabidopsis Hsa32, a novel heat-shock protein, is essential for acquired thermotolerance during a long recovery period after acclimation treatment. Plant Physiology, 140, 1297-1305
Liu NY, Ko SS, Yeh KC, and Charng YY* (2006) Isolation and characterization of tomato Hsa32 encoding a novel heat-shock protein. Plant Science, 170, 976-985
Li HY, Chang CS, Lu LS, Liu CA, Chan MT, and Charng YY* (2003) Over-expression of Arabidopsis thaliana heat shock factor gene (AtHsfA1b) enhances chilling tolerance in transgenic tomato. BOTANICAL BULLETIN OF ACADEMIA SINICA, 44, 129-140