Molecular mechanism analysis of LdHSFB2a in lily thermotolerance

Ting Li , Sujuan Xu , Yinyi Zhang , Liping Ding , Ze Wu , Nianjun Teng

Stress Biology ›› 2025, Vol. 5 ›› Issue (1) : 45

PDF
Stress Biology ›› 2025, Vol. 5 ›› Issue (1) : 45 DOI: 10.1007/s44154-025-00234-9
Original Paper

Molecular mechanism analysis of LdHSFB2a in lily thermotolerance

Author information +
History +
PDF

Abstract

Heat stress (HS) is a major environmental stress that inhibits plant growth and development. Plants have evolved various mechanisms to cope with heat stress, a key one being the HSF-HSP (Heat stress transcription factor-Heat shock protein) signaling pathway. HSFs can be divided into three classes: A, B, and C. In this study, we report the identification and functional characterization of a specific B2 member LdHSFB2a in Lilium davidii var. unicolor. RT-qPCR (Real-time Quantitative Polymerase Chain Reaction) analyses indicated that LdHSFB2a was highly expressed in HS-exposed leaves. LdHSFB2a was localized in the nucleus, consistent with the characterization of transcription factors. In contrast to other HSFBs, LdHSFB2a did not contain the typical B3 repression domain but exhibited transcriptional repression activity in yeast and plant cells. Transient overexpression and virus-induced gene silencing (VIGS) of LdHSFB2a in lily petals suggested that LdHSFB2a functions positively in lily thermotolerance. Consistent with the implication of LdHSFB2a function in thermotolerance, further analysis revealed that the expression levels of HSFA1, HSFA2, and MBF1c were increased as LdHSFB2a was overexpressed but reduced as LdHSFB2a was silenced. Furthermore, LdHSFB2a bound to the promoters of HSFA3 A, WRKY33, CAT2, and GLOS1. And LdHSFB2a overexpression and silencing enhanced and reduced their expressions, respectively. Therefore, we speculated that LdHSFB2a may be a coactivator that interacts with transcriptional activators to promote thermotolerance in lily by enhancing the expression of heat-responsive genes such as HSFA3 A, WRKY33, CAT2, and GLOS1.

Keywords

Lily / LdHSFB2a / Heat tolerance / HSF

Cite this article

Download citation ▾
Ting Li, Sujuan Xu, Yinyi Zhang, Liping Ding, Ze Wu, Nianjun Teng. Molecular mechanism analysis of LdHSFB2a in lily thermotolerance. Stress Biology, 2025, 5(1): 45 DOI:10.1007/s44154-025-00234-9

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Alavilli H, Lee H, Park M, Lee BJFips (2017) Antarctic Moss Multiprotein Bridging Factor 1c Overexpression in Arabidopsis Resulted in Enhanced Tolerance to Salt Stress. Front Plant Sci 8:1–15. https://doi.org/10.3389/fpls.2017.01206
[2]

Bachan S, Dinesh-Kumar SP (2012) Tobacco Rattle Virus (TRV)-Based Virus-Induced Gene Silencing. Methods Mol Biol 894:83-92. https://doi.org/10.1007/978-1-61779-882-5_6
[3]

Chan-SchaminetKY, BaniwalSK, BublakD, NoverL, ScharfK-D. Specific Interaction between Tomato HsfA1 and HsfA2 Creates Hetero-oligomeric Superactivator Complexes for Synergistic Activation of Heat Stress Gene Expression. J Biol Chem, 2009, 284(31): 20848-20857

[4]

ChenY, ZhangJ. Multiple functions and regulatory networks of WRKY33 and its orthologs. Gene, 2024, 931(148899): 1-14
[5]

DingY, ShiY, YangS. Molecular Regulation of Plant Responses to Environmental Temperatures. Mol Plant, 2020, 13(4): 544-564

[6]

DingL, WuZ, TengR, XuS, CaoX, YuanG, ZhangD, TengN. LlWRKY39 is involved in thermotolerance by activating LlMBF1c and interacting with LlCaM3 in lily ( Lilium longiflorum ). Horticulture Research, 2021, 8(36): 1-14
[7]

DingL, WuZ, XiangJ, CaoX, XuS, ZhangY, ZhangD, TengN. A LlWRKY33-LlHSFA4-LlCAT2 module confers resistance to Botrytis cinerea in lily. Horticulture Research, 2024, 11(1): 1-11

[8]

Diogo-JrR, de Resende Von Pinho EV, Pinto RT, Zhang L, Condori-Apfata JA, Pereira PA, Vilela DR,. Maize heat shock proteins-prospection, validation, categorization and in silico analysis of the different ZmHSP families. Stress Biology, 2023, 3(37): 1-21
[9]

FragkostefanakisS, MesihovicA, SimmS, PaupièreM, HuY, PaulP, MishraS, TschierschB, TheresK, BovyA, SchleiffE, Scharf KJPp,. HsfA2 Controls the Activity of Developmentally and Stress-Regulated Heat Stress Protection Mechanisms in Tomato Male Reproductive Tissues. Plant Physiol, 2016, 170(4): 2461-2477

[10]

FragkostefanakisS, SimmS, El-ShershabyA, HuY, BublakD, MesihovicA, DarmK, MishraSK, TschierschB, TheresK, ScharfC, SchleiffE, ScharfKD. The repressor and co-activator HsfB1 regulates the major heat stress transcription factors in tomato. Plant, Cell Environ, 2019, 42(3): 874-890

[11]

FriedrichT, OberkoflerV, TrindadeI, AltmannS, BrzezinkaK, LämkeJ, GorkaM, KappelC, SokolowskaE, SkiryczA, GrafA, BäurleI. Heteromeric HSFA2/HSFA3 complexes drive transcriptional memory after heat stress inArabidopsis. Nat Commun, 2021, 12(3426): 1-15
[12]

GongB, YiJ, WuJ, SuiJ, KhanMA, WuZ, ZhongX, SengS, HeJ, YiM. LlHSFA1, a novel heat stress transcription factor in lily ( Lilium longiflorum), can interact with LlHSFA2 and enhance the thermotolerance of transgenicArabidopsis thaliana. Plant Cell Rep, 2014, 33(9): 1519-1533

[13]

GongZ, XiongL, ShiH, YangS, Herrera-EstrellaLR, XuG, ChaoD-Y, LiJ, WangP, QinF, LiJ, DingY, ShiY, WangY, YangY, GuoY, ZhuJ. Plant abiotic stress response and nutrient use efficiency. Science China Life Sciences, 2020, 63(5): 635-674

[14]

HanS, HanX, LiY, LiK, YinJ, GongS, FangZ. Wheat lesion mimic homology gene TaCAT2 enhances plant resistance to biotic and abiotic stresses. Int J Biol Macromol, 2024, 277(3): 1-14
[15]

HasanuzzamanM, NaharK, AlamM, RoychowdhuryR, FujitaM. Physiological, Biochemical, and Molecular Mechanisms of Heat Stress Tolerance in Plants. International Journal of Molecular Science, 2013, 14(5): 9643-9684

[16]

Iqbal M, Jia T, Tang T, Anwar M, Ali A, Hassan M, Zhang Y, Tang Q, Peng Y (2022) A heat shock transcription factor TrHSFB2a of white clover negatively regulates drought, heat and salt stress tolerance in transgenic Arabidopsis. Int J Mol Sci 23(21):1–19. https://doi.org/10.3390/ijms232112769
[17]

JungJ, SeoP, OhE, KimJ. Temperature perception by plants. Trends Plant Sci, 2023, 28(8): 924-940

[18]

LanL, WuZ, ZhangD, TengN. Study on heat resistance evaluation and summer cultivation techniques of cut flower lily. J Nanjing Agric Univ, 2021, 44: 1063-1073
[19]

LiT, WuZ, XiangJ, ZhangD, TengN. Overexpression of a novel heat-inducible ethylene-responsive factor gene LlERF110 from Lilium longiflorum decreases thermotolerance. Plant Sci, 2022, 319(111246): 1-14
[20]

LiM, ZhangR, ZhouJ, DuJ, LiX, ZhangY, ChenQ, WangY, LinY, ZhangY, HeW, WangX, XiongA, LuoY, TangH. Comprehensive analysis of HSF genes from celery ( Apium graveolens L.) and functional characterization of AgHSFa6-1 in response to heat stress. Front Plant Sci, 2023, 14: 1-14
[21]

LiT, WuZ, ZhangY, XuS, XiangJ, DingL, TengN. An AP2/ERF member LlERF012 confers thermotolerance via activation of HSF pathway in lily. Plant, Cell Environ, 2024, 47(12): 4702-4719

[22]

LiuY, ChenY. High-efficiency thermal asymmetric interlaced PCR for amplification of unknown flanking sequences. Biotechniques, 2007, 43(5): 649-654

[23]

LiuX, JinX, HouJ, MaoY, ZhangY, WangX, ChaiY. Effect of iron magnesium zinc combined application on root activity, yield and quality of Lanzhou Lily. J Gansu Agric Univ, 2023, 59(6): 108-116
[24]

LiuW, YanC, LiR, ChenG, WangX, WenY, ZhangC, WangX, XuY, WangY. VqMAPK3/VqMAPK6, VqWRKY33, and VqNSTS3 constitute a regulatory node in enhancing resistance to powdery mildew in grapevine. Horticulture Research, 2023, 10(7): 1-16

[25]

LiuX, ZhuJ, ZhaoC. Liquid-liquid phase separation as a major mechanism of plant abiotic stress sensing and responses. Stress Biology, 2023, 3(56): 1-11
[26]

LuoJ, JiangJ, SunS, WangX. Brassinosteroids promote thermotolerance through releasing BIN2-mediated phosphorylation and suppression of HsfA1 transcription factors in Arabidopsis. Plant Communication, 2022, 3(100419): 1-17
[27]

MaH, WangC, YangB, ChengH, WangZ, MijitiA, RenC, QuG, ZhangH, MaL. CarHSFB2, a class b heat shock transcription factor, is involved in different developmental processes and various stress responses in chickpea (Cicer Arietinum L.). Plant Mol Biol Rep, 2015, 34(1): 1-14

[28]

NingK, HanY, ChenZ, LuoC, WangS, ZhangW, LiL, ZhangX, FanS, WangQ. Genome-wide analysis of MADS-box family genes during flower development in lettuce. Plant Cell Environ, 2019, 42(6): 1868-1881

[29]

OhamaN, KusakabeK, MizoiJ, ZhaoH, KidokoroS, KoizumiS, TakahashiF, IshidaT, YanagisawaS, ShinozakiK, Yamaguchi-Shinozaki KJTPc,. The Transcriptional Cascade in the Heat Stress Response of Arabidopsis Is Strictly Regulated at the Level of Transcription Factor Expression. Plant Cell, 2016, 28(1): 181-201

[30]

PerrellaG, BaurleI, van ZantenM. Epigenetic regulation of thermomorphogenesis and heat stress tolerance. New Phytol, 2022, 234(4): 1144-1160

[31]

RössnerC, LotzD, Becker AJAropb,. VIGS Goes Viral: How VIGS Transforms Our Understanding of Plant Science. Annual Reviews Plant Biology, 2022, 73: 703-728

[32]

ScharfK, BerberichT, EbersbergerI. The plant heat stress transcription factor (Hsf) family: Structure, function and evolution. Biochimica et Biophysica Acta (BBA)-Gene Regulatory Mechanisms, 1819, 2: 104-119
[33]

SchrammF, LarkindaleJ, KiehlmannE, GanguliA, EnglichG, VierlingE, von Koskull-DoringP. A cascade of transcription factor DREB2A and heat stress transcription factor HsfA3 regulates the heat stress response of Arabidopsis. Plant J, 2008, 53(2): 264-274

[34]

SuzukiN, KoussevitzkyS, MittlerR, MillerG. ROS and redox signalling in the response of plants to abiotic stress. Plant Cell Environ, 2012, 35(2): 259-270

[35]

TorresM-Á, BerlangaDJ. OsDMI3, a Ca 2+/calmodulin kinase, integrates and amplifies H2O2and Ca2+signaling in ABA-mediated responses. Mol Plant, 2023, 16(6): 968-970

[36]

WuZ, LiangJ, WangC, DingL, ZhaoX, CaoX, XuS, TengN, YiM. Alternative splicing provides a mechanism to regulate LlHSFA3 function in response to heat stress in Lily. Plant Physiol, 2019, 181(4): 1651-1667

[37]

WuT, HohK, BoonyavesK, KrishnamoorthiS, UranoD. Diversification of heat shock transcription factors expanded thermal stress responses during early plant evolution. Plant Cell, 2022, 34(10): 3557-3576

[38]

WuZ, LiT, ZhangD, TengN. Lily HD-Zip I Transcription Factor LlHB16 Promotes Thermotolerance by Activating LlHSFA2 andLlMBF1c. Plant Cell and Physiology, 2022, 63(11): 1529-1539

[39]

WuZ, LiangJ, LiT, ZhangD, TengN. A LlMYB305-LlC3H18-LlWRKY33 module regulates thermotolerance in lily. Molecular Horticulture, 2023, 3(1): 15-32

[40]

WuZ, GongX, ZhangY, LiT, XiangJ, FangQ, YuJ, DingL, LiangJ, TengN. LlbHLH87 interacts with LlSPT to modulate thermotolerance via activation of LlHSFA2 and LlEIN3 in lily. Plant J, 2024, 120(4): 1457-1473

[41]

WuZ, LiT, DingL, WangC, TengR, XuS, CaoX, TengN. Lily LlHSFC2 coordinates with HSFAs to balance heat stress response and improve thermotolerance. New Phytol, 2024, 241: 2124-2142

[42]

XiangJ, RanJ, ZouJ, ZhouX, LiuA, ZhangX, PengY, TangN, LuoG, ChenX. Heat shock factor OsHsfB2b negatively regulates drought and salt tolerance in rice. Plant Cell Rep, 2013, 32(11): 1795-1806

[43]

XiangJ, WuZ, DingL, ZhangY, TengN. A lily heat-inducible multi-protein bridging factor, LlMBF1c , plays a crucial role in plant thermotolerance. Horticulture Advances, 2024, 2(24): 1-12
[44]

XuX, XieQ. LNKs-RVEs complex ticks in the circadian gating of plant temperature stress responses. Stress Biology, 2023, 3(32): 1-4
[45]

XuS, HouH, WuZ, ZhaoJ, ZhangF, TengR, ChenF, TengN. Chrysanthemum embryo development is negatively affected by a novel ERF transcription factor,CmERF12. J Exp Bot, 2021, 73(1): 197-212

[46]

XuS, ChenR, ZhangX, WuY, YangL, SunZ, ZhuZ, SongA, WuZ, LiT, JinB, NiuS, HuangX, LiuS, YangC, JiaG, HeY, DuF, ChenM, ChenF, WangW, SunH, FuY, LiaoW, PeiH, WuX, ZhengS, XueJ, NingG, MingR, TengN. The evolutionary tale of lilies: Giant genomes derived from transposon insertions and polyploidization. The Innovation, 2024, 5(6): 100726-100728

[47]

YanZ, XiangL, YijiS, LinaL, ShunxianT, QiZ, MengfanQ, KaiW, YuX, LinZ, HanmingC, HanW, YunlinZ, JiaS, KeqiL, AixiaX, ZhenH. The B-box transcription factor BnBBX22.A07 enhances salt stress tolerance by indirectly activating BnWRKY.33C03. Plant Cell Environ, 2024, 47(12): 5424-5442

[48]

YiJ, LuoX, CaoX, ChenL, XinH, LiX, ChenJ, YiM. Cloning and Expression Analysis of LlHSF1 fromLilium longiforum. Acta Horticulturae Sinica, 2012, 39(11): 2199-2205
[49]

YoshidaT, OhamaN, NakajimaJ, KidokoroS, MizoiJ, NakashimaK, MaruyamaK, KimJ, SekiM, TodakaD, OsakabeY, SakumaY, SchöfflF, ShinozakiK, Yamaguchi-Shinozaki KJMg, MGG g,. Arabidopsis HsfA1 transcription factors function as the main positive regulators in heat shock-responsive gene expression. Mol Genet Genomics, 2011, 286: 321-332

[50]

Yu J, Wu Z, Liu X, Fang Q, Pan X, Xu S, He M, Lin J, Teng N (2024) LoBLH6 interacts with LoMYB65 to regulate anther development through feedback regulation of gibberellin synthesis in lily. Hortic Res 12(3):uhae339. https://doi.org/10.1093/hr/uhae339
[51]

ZhangH, ZhuJ, GongZ, ZhuJ. Abiotic stress responses in plants. Nat Rev Genet, 2022, 23(2): 104-119

[52]

ZhangC, TongC, CaoL, ZhengP, TangX, WangL, MiaoM, LiuY, CaoS. Regulatory module WRKY33-ATL31-IRT1 mediates cadmium tolerance in Arabidopsis. Plant, Cell Environ, 2023, 46(5): 1651-1670

[53]

ZhangX, XuS, PanX, WuZ, DingL, TengN. Low LdMYB12 expression contributes to petal spot deficiency in Lilium davidii var. unicolor. Mol Genet Genomics, 2023, 298(6): 1545-1557

[54]

ZhangL, ZhuQ, SunJ, YaoZ, QingT, MaH, LiuJ. XBAT31 regulates reproductive thermotolerance through controlling the accumulation of HSFB2a/B2b under heat stress conditions. Cell Rep, 2024, 43(6): 114349

[55]

ZhouY, WangY, XuF, SongC, YangX, ZhangZ, YiM, MaN, ZhouX, HeJ. Small HSPs play an important role in crosstalk between HSF-HSP and ROS pathways in heat stress response through transcriptomic analysis in lilies ( Lilium longiflorum ). BMC Plant Biol, 2022, 22(202): 1-16

Funding

the National Natural Science Foundation of China(32472784)

the Project for Crop Germplasm Resources Conservation of Jiangsu(2021-SJ-011)

Postgraduate Research & Practice Innovation Program of Jiangsu Province(KYCX24-0962)

RIGHTS & PERMISSIONS

The Author(s)

AI Summary AI Mindmap
PDF

193

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/