The optimization of crop response to climatic stress through modulation of plant stress response mechanisms. Opportunities for biostimulants and plant hormones to meet climate challenges.

Li, Jing; Forghieri, Giulia; Geelen, Danny; du Jardin, Patrick; Brown, Patrick H

doi:10.1111/nph.70701

Article (Scientific journals)

The optimization of crop response to climatic stress through modulation of plant stress response mechanisms. Opportunities for biostimulants and plant hormones to meet climate challenges.

Li, Jing; Forghieri, Giulia; Geelen, Danny et al.

2025 • In New Phytologist, 249 (1), p. 130 - 151

Peer Reviewed verified by ORBi

Permalink
https://hdl.handle.net/2268/343892

DOI
10.1111/nph.70701

PubMed
41215465

Files (1)Send to Details Statistics Bibliography Similar publications

Files

Full Text

New Phytologist - 2025 - Li - The optimization of crop response to climatic stress through modulation of plant stress-1.pdf

Author postprint (1.01 MB)

Download

All documents in ORBi are protected by a user license.

Send to

RIS BibTex APA Chicago Permalink X Linkedin

Details

Keywords :

abiotic stress; biostimulant; climate change; plant hormone; stress tolerance; Plant Growth Regulators; Crops, Agricultural/physiology; Crops, Agricultural/drug effects; Climate Change; Stress, Physiological/drug effects; Plant Growth Regulators/pharmacology; Crops, Agricultural; Stress, Physiological; Physiology; Plant Science

Abstract :

[en] This review discusses the use of agronomic management practices to enhance crop stress resilience to climate stress through the modulation of natural plant growth regulatory pathways. The use of biostimulants or plant hormones to improve crop resilience is subject to strict regulatory oversight if changes in the regulation of plant growth are implied. Climate change is a major threat to crop potential and is characterized by both long-term shifts in temperature and precipitation patterns as well as increased occurrence of extreme weather events, posing an immediate threat to agriculture. Breeding and exogenous inputs have been used to enhance cropping system resilience, although these management practices are either too slow or constrained by cost and availability, to address rapidly emerging climate challenges. Exogenous biostimulants, microbials and plant hormones have shown great promise as novel mechanisms to optimize natural plant resilience, resulting in immediate but non-permanent improvements in plant responses to climate-induced stresses, representing a powerful but underexplored approach to enhance crop productivity under climate stress. The use of these exogenous inputs is, however, constrained by outdated and scientifically unsound regulations that consider any such modification as pesticidal in nature. The failure to modernize regulatory frameworks for the use of biostimulants in agriculture will constrain the development of safe effective tools and deprive growers of means to respond to climate change. Here, we discuss the scientific rationale for eliminating the regulatory barriers governing biostimulants or products that modulate plant regulatory networks and propose a framework for enabling legislation to strengthen cropping system resilience.

Disciplines :

Biotechnology

Author, co-author :

Li, Jing ; HortiCell, Department Plants and Crops, Faculty of Bioscience Engineering, Ghent University, Coupure Links 653, Ghent, 9000, Belgium

Forghieri, Giulia ; CatMat Lab, Department of Molecular Sciences and Nanosystems, Ca' Foscari University of Venice and Consortium INSTM UdR VE, via Torino 155, Venice, 30172, Italy

Geelen, Danny ; HortiCell, Department Plants and Crops, Faculty of Bioscience Engineering, Ghent University, Coupure Links 653, Ghent, 9000, Belgium

du Jardin, Patrick ; Université de Liège - ULiège > Département GxABT > Plant Sciences

Brown, Patrick H ; Department of Plant Sciences, University of California Davis, One Shields Ave, Davis, 95616, CA, USA

Language :

English

Title :

The optimization of crop response to climatic stress through modulation of plant stress response mechanisms. Opportunities for biostimulants and plant hormones to meet climate challenges.

Publication date :

January 2025

Journal title :

New Phytologist

ISSN :

0028-646X

eISSN :

1469-8137

Publisher :

John Wiley and Sons Inc, England

Volume :

249

Issue :

Pages :

130 - 151

Peer reviewed :

Peer Reviewed verified by ORBi

Development Goals :

12. Responsible consumption and production

Additional URL :

https://nph.onlinelibrary.wiley.com/doi/pdf/10.1111/nph.70701

Available on ORBi :

since 11 April 2026

Statistics

Number of views

56 (4 by ULiège)

Number of downloads

23 (1 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

OpenAlex citations

Bibliography

2019/1009 R (EU). 2019. Regulation (EU) 2019/1009.
Abouelsaad I, Renault S. 2018. Enhanced oxidative stress in the jasmonic acid-deficient tomato mutant def-1 exposed to NaCl stress. Journal of Plant Physiology 226: 136–144.
Ahmad RM, Cheng C, Sheng J, Wang W, Ren H, Aslam M, Yan Y. 2019. Interruption of jasmonic acid biosynthesis causes differential responses in the roots and shoots of maize seedlings against salt stress. International Journal of Molecular Sciences 20: 6202.
Ahmed M, Ullah H, Piromsri K, Tisarum R, Cha-um S, Datta A. 2022. Effects of an Ascophyllum nodosum seaweed extract application dose and method on growth, fruit yield, quality, and water productivity of tomato under water-deficit stress. South African Journal of Botany 151: 95–107.
Ali AH, Said EM, Abdelgawad ZA. 2022. The role of seaweed extract on improvement drought tolerance of wheat revealed by osmoprotectants and DNA (cpDNA) markers. Revista Brasileira de Botânica 45: 857–867.
Ali O, Ramsubhag A, Jr DB, Ramnarine S, Jayaraman J. 2022. Transcriptomic changes induced by applications of a commercial extract of Ascophyllum nodosum on tomato plants. Scientific Reports 12: 1–13.
Ali S, Moon YS, Hamayun M, Khan MA, Bibi K, Lee IJ. 2022. Pragmatic role of microbial plant biostimulants in abiotic stress relief in crop plants. Journal of Plant Interactions 17: 705–718.
Alvarez ME, Savouré A, Szabados L. 2022. Proline metabolism as regulatory hub. Trends in Plant Science 27: 39–55.
Alves LR, Monteiro CC, Carvalho RF, Ribeiro PC, Tezotto T, Azevedo RA, Gratão PL. 2017. Cadmium stress related to root-to-shoot communication depends on ethylene and auxin in tomato plants. Environmental and Experimental Botany 134: 102–115.
Ambreetha S, Chinnadurai C, Marimuthu P, Balachandar D. 2018. Plant-associated Bacillus modulates the expression of auxin-responsive genes of rice and modifies the root architecture. Rhizosphere 5: 57–66.
Arnold PA, Kruuk LEB, Nicotra AB. 2019. How to analyse plant phenotypic plasticity in response to a changing climate. New Phytologist 222: 1235–1241.
Bado S, Forster BP, Nielen S, Ali AM, Lagoda PJL, Till BJ, Laimer M. 2015. Plant mutation breeding: current progress and future assessment. Plant Breeding Reviews 39: 23–88.
Baena-González E, Hanson J. 2017. Shaping plant development through the SnRK1–TOR metabolic regulators. Current Opinion in Plant Biology 35: 152–157.
Barnawal D, Bharti N, Pandey SS, Pandey A, Chanotiya CS, Kalra A. 2017. Plant growth-promoting rhizobacteria enhance wheat salt and drought stress tolerance by altering endogenous phytohormone levels and TaCTR1/TaDREB2 expression. Physiologia Plantarum 161: 502–514.
Bi CL, Wen XJ, Zhang XY, Liu X. 2010. Cloning and characterization of a putative CTR1 gene from wheat. Agricultural Sciences in China 9: 1241–1250.
Bilal S, Shahzad R, Imran M, Jan R, Kim KM, Lee IJ. 2020. Synergistic association of endophytic fungi enhances Glycine max L. resilience to combined abiotic stresses: heavy metals, high temperature and drought stress. Industrial Crops and Products 143: 1–10.
Bouteraa MT, Mishra A, Ben RW, Ben HA, Siddique KHM, Ben SR. 2022. Bio-stimulating effect of natural polysaccharides from Lobularia maritima on durum wheat seedlings: improved plant growth, salt stress tolerance by modulating biochemical responses and ion homeostasis. Plants 11: 1–16.
Bouzroud S, Gasparini K, Hu G, Barbosa MAM, Rosa BL, Fahr M, Bendaou N, Bouzayen M, Zsögön A, Smouni A. 2020. Down regulation and loss of auxin response factor 4 function using CRISPR/Cas9 alters plant growth, stomatal function and improves tomato tolerance to salinity and osmotic stress. Genes 11: 272.
Brecht JK. 2019. Ethylene technology. In: Postharvest Technology of Perishable Horticultural Commodities. UK: Woodhead Publishing, 481–497.
Brooker R, Brown LK, George TS, Pakeman RJ, Palmer S, Ramsay L, Schöb C, Schurch N, Wilkinson MJ. 2022. Active and adaptive plasticity in a changing climate. Trends in Plant Science 27: 717–728.
Brown P, Saa S. 2015. Biostimulants in agriculture. Frontiers in Plant Sciences 6: 1–3.
Burney J, McIntosh C, Lopez-Videla B, Samphantharak K, Maia AG. 2024. Empirical modeling of agricultural climate risk. Proceedings of the National Academy of Sciences, USA 121: e2215677121.
Cagnola JI, Rotili DH, Otegui ME, Casal JJ. 2025. 50 years of breeding to improve yield: How maize stands up to climate change. Philosophical Transactions of the Royal Society, B: Biological Sciences 380: 20240250.
Calvo P, Nelson L, Kloepper JW. 2014. Agricultural uses of plant biostimulants. Plant and Soil 383: 3–41.
Canellas LP, da Silva RM, Busato JG, Olivares FL. 2024. Humic substances and plant abiotic stress adaptation. Chemical and Biological Technologies in Agriculture 11: 1–18.
Canellas LP, Olivares FL, Aguiar NO, Jones DL, Nebbioso A, Mazzei P, Piccolo A. 2015. Humic and fulvic acids as biostimulants in horticulture. Scientia Horticulturae 196: 15–27.
Carillo P, Ciarmiello LF, Woodrow P, Corrado G, Chiaiese P, Rouphael Y. 2020. Enhancing sustainability by improving plant salt tolerance through macro-and micro-algal biostimulants. Biology 9: 1–21.
Casadesús A, Pérez-Llorca M, Munné-Bosch S, Polo J. 2020. An enzymatically hydrolyzed animal protein-based biostimulant (pepton) increases salicylic acid and promotes growth of tomato roots under temperature and nutrient stress. Frontiers in Plant Science 11: 1–12.
Casadesús A, Polo J, Munné-Bosch S. 2019. Hormonal effects of an enzymatically hydrolyzed animal protein-based biostimulant (pepton) in water-stressed tomato plants. Frontiers in Plant Science 10: 1–11.
Ceccarelli AV, Miras-Moreno B, Buffagni V, Senizza B, Pii Y, Cardarelli M, Rouphael Y, Colla G, Lucini L. 2021. Foliar application of different vegetal-derived protein hydrolysates distinctively modulates tomato root development and metabolism. Plants 10: 1–15.
Chanda M, Merghoub N, Arroussi H. 2019. Microalgae polysaccharides: the new sustainable bioactive products for the development of plant bio-stimulants? World Journal of Microbiology and Biotechnology 35: 1–10.
Chang YN, Zhu C, Jiang J, Zhang H, Zhu JK, Duan CG. 2020. Epigenetic regulation in plant abiotic stress responses. Journal of Integrative Plant Biology 62: 563–580.
Chen M, Zhu X, Liu X, Wu C, Yu C, Hu G, Chen L, Chen R, Bouzayen M, Zouine M. 2021. Knockout of auxin response factor SlARF4 improves tomato resistance to water deficit. International Journal of Molecular Sciences 22: 3347.
Chen Q, Qu Z, Ma G, Wang W, Dai J, Zhang M, Wei Z, Liu Z. 2022b. Humic acid modulates growth, photosynthesis, hormone and osmolytes system of maize under drought conditions. Agricultural Water Management 263: 1–12.
Chen Y, Cothren JT, Chen D, Ibrahim AMH, Lombardini L. 2014. Effect of 1-MCP on cotton plants under abiotic stress caused by ethephon. American Journal of Plant Sciences 5: 3005.
Chen Z, Zhou W, Guo X, Ling S, Li W, Wang X, Yao J. 2024. Heat stress responsive Aux/IAA Protein, OsIAA29 regulates grain filling through OsARF17 mediated auxin signaling pathway. Rice 17: 1–14.
Colla G, Hoagland L, Ruzzi M, Cardarelli M, Bonini P, Canaguier R, Rouphael Y. 2017. Biostimulant action of protein hydrolysates: Unraveling their effects on plant physiology and microbiome. Frontiers in Plant Science 8: 1–14.
Colla G, Nardi S, Cardarelli M, Ertani A, Lucini L, Canaguier R, Rouphael Y. 2015a. Protein hydrolysates as biostimulants in horticulture. Scientia Horticulturae 196: 28–38.
Colla G, Rouphael Y, Canaguier R, Svecova E, Cardarelli M. 2014. Biostimulant action of a plant-derived protein hydrolysate produced through enzymatic hydrolysis. Frontiers in Plant Science 5: 448.
Colla G, Rouphael Y, Di Mattia E, El-Nakhel C, Cardarelli M. 2015b. Co-inoculation of Glomus intraradices and Trichoderma atroviride acts as a biostimulant to promote growth, yield and nutrient uptake of vegetable crops. Journal of the Science of Food and Agriculture 95: 1706–1715.
Deolu-Ajayi AO, van der Meer IM, van der Werf A, Karlova R. 2022. The power of seaweeds as plant biostimulants to boost crop production under abiotic stress. Plant, Cell & Environment 45: 2537–2553.
Dietz KJ, Vogelsang L. 2024. A general concept of quantitative abiotic stress sensing. Trends in Plant Science 29: 319–328.
Djanaguiraman M, Prasad PVV, Al-Khatib K. 2011. Ethylene perception inhibitor 1-MCP decreases oxidative damage of leaves through enhanced antioxidant defense mechanisms in soybean plants grown under high temperature stress. Environmental and Experimental Botany 71: 215–223.
Du H, Wu N, Cui F, You L, Li X, Xiong L. 2014. A homolog of ETHYLENE OVERPRODUCER, OsETOL1, differentially modulates drought and submergence tolerance in rice. The Plant Journal 78: 834–849.
Du H, Wu N, Fu J, Wang S, Li X, Xiao J, Xiong L. 2012. A GH3 family member, OsGH3-2, modulates auxin and abscisic acid levels and differentially affects drought and cold tolerance in rice. Journal of Experimental Botany 63: 6467–6480.
Elansary HO, Skalicka-Woźniak K, King IW. 2016. Enhancing stress growth traits as well as phytochemical and antioxidant contents of Spiraea and Pittosporum under seaweed extract treatments. Plant Physiology and Biochemistry 105: 310–320.
Enebe MC, Babalola OO. 2018. The influence of plant growth-promoting rhizobacteria in plant tolerance to abiotic stress: a survival strategy. Applied Microbiology and Biotechnology 102: 7821–7835.
EPA. 2024. Draft guidance for plant regulators and claims, including plant biostimulants. US EPA.
Eshed Y, Lippman ZB. 2019. Revolutions in agriculture chart a course for targeted breeding of old and new crops. Science 366: 1–7.
Etehadnia M, Waterer DR, Tanino KK. 2008. The method of ABA application affects salt stress responses in resistant and sensitive potato lines. Journal of Plant Growth Regulation 27: 331–341.
Fàbregas N, Fernie AR. 2021. The interface of central metabolism with hormone signaling in plants. Current Biology 31: R1535–R1548.
Fitzpatrick CR, Copeland J, Wang PW, Guttman DS, Kotanen PM, Johnson MTJ. 2017. Assembly and ecological function of the root microbiome across angiosperm plant species. Proceedings of the National Academy of Sciences, USA 115: E1157–E1165.
Francesca S, Cirillo V, Raimondi G, Maggio A, Barone A, Rigano MM. 2021. A novel protein hydrolysate-based biostimulant improves tomato performances under drought stress. Plants 10: 32–43.
Francesca S, Najai S, Zhou R, Decros G, Cassan C, Delmas F, Ottosen CO, Barone A, Rigano MM. 2022. Phenotyping to dissect the biostimulant action of a protein hydrolysate in tomato plants under combined abiotic stress. Plant Physiology and Biochemistry 179: 32–43.
Franzoni G, Cocetta G, Prinsi B, Ferrante A, Espen L. 2022. Biostimulants on crops: their impact under abiotic stress conditions. Horticulturae 8: 189.
Fumia N, Pironon S, Rubinoff D, Khoury CK, Gore MA, Kantar MB. 2022. Wild relatives of potato may bolster its adaptation to new niches under future climate scenarios. Food and Energy Security 11: e360.
Furio RN, Salazar SM, Mariotti-Martínez JA, Martínez-Zamora GM, Coll Y, Díaz-Ricci JC. 2022. Brassinosteroid applications enhance the tolerance to abiotic stresses. Production and Quality of Strawberry Fruits. 8: 572.
Gallusci P, Agius DR, Moschou PN, Dobránszki J, Kaiserli E, Martinelli F. 2023. Deep inside the epigenetic memories of stressed plants. Trends in Plant Science 28: 142–153.
Gao R, Yu Q, Shen Y, Chu Q, Chen G, Fen S, Yang M, Yuan L, McClements DJ, Sun Q. 2021. Production, bioactive properties, and potential applications of fish protein hydrolysates. Developments and Challenges. 110: 687–699.
Gashaw A, Theerawitaya C, Samphumphuang T, Cha-um S, Supaibulwatana K. 2014. CPPU elevates photosynthetic abilities, growth performances and yield traits in salt stressed rice (Oryza sativa L. spp. indica) via free proline and sugar accumulation. Pesticide Biochemistry and Physiology 108: 27–33.
Gemrotová M, Kulkarni MG, Stirk WA, Strnad M, Van Staden J, Spíchal L. 2013. Seedlings of medicinal plants treated with either a cytokinin antagonist (PI-55) or an inhibitor of cytokinin degradation (INCYDE) are protected against the negative effects of cadmium. Plant Growth Regulation 71: 137–145.
Glick BR. 2014. Bacteria with ACC deaminase can promote plant growth and help to feed the world. Microbiological Research 169: 30–39.
Grillo S, Leone A, Xu Y, Tucci M, Francione R, Hasegawa PM, Monti L, Bressan RA. 1995. Control of osmotin gene expression by ABA and osmotic stress in vegetative tissues of wild-type and ABA-deficient mutants of tomato. Physiologia Plantarum 93: 498–504.
Gujjar RS, Banyen P, Chuekong W, Worakan P, Roytrakul S, Supaibulwatana K. 2020. A synthetic cytokinin improves photosynthesis in rice under drought stress by modulating the abundance of proteins related to stomatal conductance, chlorophyll contents, and rubisco activity. Plants 9: 1–21.
Gurmani AR, Bano A, Khan SU, Din J, Zhang JL. 2011. Alleviation of salt stress by seed treatment with abscisic acid (ABA), 6-benzylaminopurine (BA) and chlormequat chloride (CCC) optimizes ion and organic matter accumulation and increases yield of rice (‘Oryza sativa’ L.). Australian Journal of Crop Science 5: 1278–1285.
Han YJ, Kim YS, Hwang OJ, Roh J, Ganguly K, Kim SK, Hwang I, Il KJ. 2017. Overexpression of Arabidopsis thaliana brassinosteroid-related acyltransferase 1 gene induces brassinosteroid-deficient phenotypes in creeping bentgrass. PLoS ONE 12: e0187378.
Harrison E, Burbidge A, Okyere JP, Thompson AJ, Taylor IB. 2011. Identification of the tomato ABA-deficient mutant sitiens as a member of the ABA-aldehyde oxidase gene family using genetic and genomic analysis. Plant Growth Regulation 64: 301–309.
Hasegawa T, Sakurai G, Fujimori S, Takahashi K, Hijioka Y, Masui T. 2021. Extreme climate events increase risk of global food insecurity and adaptation needs. Nature Food 2: 587–595.
He F, Sheng M, Tang M. 2017. Effects of Rhizophagus irregularis on photosynthesis and antioxidative enzymatic system in Robinia pseudoacacia L. under drought stress. Frontiers in Plant Science 8: 183.
He Z, Webster S, He SY. 2022. Growth–defense trade-offs in plants. Current Biology 32: R634–R639.
Hernández-Herrera RM, Sánchez-Hernández CV, Palmeros-Suárez PA, Ocampo-Alvarez H, Santacruz-Ruvalcaba F, Meza-Canales ID, Becerril-Espinosa A. 2022. Seaweed extract improves growth and productivity of tomato plants under salinity stress. Agronomy 12: 1–23.
Hirayama T, Mochida K. 2022. Plant hormonomics: a key tool for deep physiological phenotyping to improve crop productivity. Plant and Cell Physiology 00: 1–14.
Ho S-L, Chao Y-C, Tong W-F, Yu S-M. 2001. Sugar coordinately and differentially regulates growth-and stress-related gene expression via a complex signal transduction network and multiple control mechanisms. Plant and Cell Physiology 125: 877–890.
Hosseini SA, Maillard A, Hajirezaei MR, Ali N, Schwarzenberg A, Jamois F, Yvin JC. 2017. Induction of barley silicon transporter HvLsi1 and HvLsi2, increased silicon concentration in the shoot and regulated starch and ABA homeostasis under osmotic stress and concomitant potassium deficiency. Frontiers in Plant Science 8: 1–15.
Huang Z, Zhang Z, Zhang X, Zhang H, Huang D, Huang R. 2004. Tomato TERF1 modulates ethylene response and enhances osmotic stress tolerance by activating expression of downstream genes. FEBS Letters 573: 110–116.
Hussain S, Bai Z, Huang J, Cao X, Zhu L, Zhu C, Khaskheli MA, Zhong C, Jin Q, Zhang J. 2019. 1-Methylcyclopropene modulates physiological, biochemical, and antioxidant responses of rice to different salt stress levels. Frontiers in Plant Science 10: 124.
Illescas M, Pedrero-Méndez A, Pitorini-Bovolini M, Hermosa R, Monte E. 2021. Phytohormone production profiles in Trichoderma species and their relationship to wheat plant responses to water stress. Pathogens 10: 991.
Iqbal M, Ashraf M. 2013. Gibberellic acid mediated induction of salt tolerance in wheat plants: Growth, ionic partitioning, photosynthesis, yield and hormonal homeostasis. Environmental and Experimental Botany 86: 76–85.
Iqbal N, Umar S, Per TS, Khan NA. 2017. Ethephon increases photosynthetic-nitrogen use efficiency, proline and antioxidant metabolism to alleviate decrease in photosynthesis under salinity stress in mustard. Plant Signaling & Behavior 12: e1297000.
ISO. ISO 8157. 2022. Fertilizers, soil conditioners and beneficial substances – Vocabulary. ISO.
Jägermeyr J, Müller C, Ruane AC, Elliott J, Balkovic J, Castillo O, Faye B, Foster I, Folberth C, Franke JA et al. 2021. Climate impacts on global agriculture emerge earlier in new generation of climate and crop models. Nature Food 2: 873–885.
Jan SS, Khan NA, Asaf S, Shahzad R, Lubna IM, Bilal S, Lee IJ, Al-Harrasi A. 2024. Consortium of endophytic Bacillus australimaris CK11 and Staphylococcus epidermidis CK9 from Commiphora gileadensis mediates tomato resilience to combined salinity, heat, and drought stresses. Journal of Plant Growth Regulation: 1–24.
du Jardin P, Brown PH, DeJong TM, Cassán F, Ferrante A, Fotopoulos V, Manganaris GA, Carillo P. 2025. Unlocking the black box of plant biostimulants. Scientia Horticulturae 350: 114281.
Jayakodi M, Shim H, Mascher M. 2025. What are we learning from plant pangenomes? Annual Review of Plant Biology 76: 663–686.
Jha CK, Sharma P, Shukla A, Parmar P, Patel R, Goswami D, Saraf M. 2021. Microbial enzyme, 1-aminocyclopropane-1-carboxylic acid (ACC) deaminase: an elixir for plant under stress. Physiological and Molecular Plant Pathology 115: 1–10.
Jia Z, Giehl RFH, von Wirén N. 2022. Nutrient–hormone relations: driving root plasticity in plants. Molecular Plant 15: 86–103.
Jiang M, Xu F, Peng M, Huang F, Meng F. 2016. Methyl jasmonate regulated diploid and tetraploid black locust (Robinia pseudoacacia L.) tolerance to salt stress. Acta Physiologiae Plantarum 38: 1–13.
Jiang W, Wang X, Wang Y, Du Y, Zhang S, Zhou H, Feng N, Zheng D, Ma G, Zhao L. 2024. S-ABA enhances rice salt tolerance by regulating Na+/K+ balance and hormone homeostasis. Metabolites 14: 181.
Jin P, Zhu H, Wang J, Chen J, Wang X, Zheng Y. 2013. Effect of methyl jasmonate on energy metabolism in peach fruit during chilling stress. Journal of the Science of Food and Agriculture 93: 1827–1832.
Jini D, Joseph B. 2017. Physiological mechanism of salicylic acid for alleviation of salt stress in rice. Rice Science 24: 97–108.
Jones AM. 2016. A new look at stress: abscisic acid patterns and dynamics at high-resolution. New Phytologist 210: 38–44.
Kamínek M. 2015. Tracking the story of cytokinin research. Journal of Plant Growth Regulation 34: 723–739.
Kang SM, Radhakrishnan R, Khan AL, Kim MJ, Park JM, Kim BR, Shin DH, Lee IJ. 2014. Gibberellin secreting rhizobacterium, Pseudomonas putida H-2-3 modulates the hormonal and stress physiology of soybean to improve the plant growth under saline and drought conditions. Plant Physiology and Biochemistry 84: 115–124.
Kang S-M, Shahzad R, Bilal S, Khan AL, Park Y-G, Lee K-E, Asaf S, Khan MA, Lee I-J. 2019. Indole-3-acetic-acid and ACC deaminase producing Leclercia adecarboxylata MO1 improves Solanum lycopersicum L. growth and salinity stress tolerance by endogenous secondary metabolites regulation. BMC Microbiology 19: 1–14.
Kasim W. 2017. Alleviation of drought stress in Vicia faba by seed priming with ascorbic acid or extracts of garlic and carrot. Egyptian Journal of Botany 0: 45–59.
Keswani C, Singh SP, Cueto L, García-Estrada C, Mezaache-Aichour S, Glare TR, Borriss R, Singh SP, Blázquez MA, Sansinenea E. 2020. Auxins of microbial origin and their use in agriculture. Applied Microbiology and Biotechnology 104: 8549–8565.
Khan I, Awan SA, Ikram R, Rizwan M, Akhtar N, Yasmin H, Sayyed RZ, Ali S, Ilyas N. 2021. Effects of 24-epibrassinolide on plant growth, antioxidants defense system, and endogenous hormones in two wheat varieties under drought stress. Physiologia Plantarum 172: 696–706.
Khan MA, Asaf S, Khan AL, Jan R, Kang S-M, Kim K-M, Lee I-J. 2020. Extending thermotolerance to tomato seedlings by inoculation with SA1 isolate of Bacillus cereus and comparison with exogenous humic acid application. PLoS ONE 15: e0232228.
Khan MA, Hamayun M, Asaf S, Khan M, Yun BW, Kang SM, Lee IJ. 2021. Rhizospheric Bacillus spp. rescues plant growth under salinity stress via regulating gene expression, endogenous hormones, and antioxidant system of Oryza sativa L. Frontiers in Plant Science 12: 665590.
Khan MA, Riaz H, Raheel M, Shakeel Q, Waheed U, Ahmed N, Bashair M, Ashraf W, Abbas HT, Siddique M et al. 2021. In-vitro and In-vivo management of Meloidogyne incognita (Kofoid and White) Chitwood and Rhizoctonia bataticola (Taub.) Butler in cotton using organic's. Saudi Journal of Biological Sciences 28: 1–9.
Khan MS, Akther T, Ali DM, Hemalatha S. 2019. An investigation on the role of salicylic acid alleviate the saline stress in rice crop (Oryza sativa (L)). Biocatalysis and Agricultural Biotechnology 18: 101027.
Khan Z, Gul H, Rauf M, Arif M, Hamayun M, Ud-Din A, Sajid ZA, Khilji SA, Rehman A, Tabassum A et al. 2022. Sargassum wightii aqueous extract improved salt stress tolerance in Abelmoschus esculentus by mediating metabolic and ionic rebalance. Frontiers in Marine Science 9: 1–13.
Khoury CK, Brush S, Costich DE, Curry HA, de Haan S, Engels JMM, Guarino L, Hoban S, Mercer KL, Miller AJ et al. 2022. Crop genetic erosion: understanding and responding to loss of crop diversity. New Phytologist 233: 84–118.
Kim EH, Kim YS, Park S-H, Koo YJ, Do CY, Chung Y-Y, Lee I-J, Kim J-K. 2009. Methyl jasmonate reduces grain yield by mediating stress signals to alter spikelet development in rice. Plant Physiology 149: 1751–1760.
Kowalczewski PŁ, Zembrzuska J. 2023. Advances in biological activities and application of plant extracts. Applied Sciences 13: 9324.
Krishnan S, Merewitz EB. 2015. Drought stress and trinexapac-ethyl modify phytohormone content within Kentucky bluegrass leaves. Journal of Plant Growth Regulation 34: 1–12.
Landis JB, Guercio AM, Brown KE, Fiscus CJ, Morrell PL, Koenig D. 2024. Natural selection drives emergent genetic homogeneity in a century-scale experiment with barley. Science 385: eadl0038.
Latif HH, Mohamed HI. 2016. Exogenous applications of moringa leaf extract effect on retrotransposon, ultrastructural and biochemical contents of common bean plants under environmental stresses. South African Journal of Botany 106: 221–231.
Latif Khan A, Hamayun M, Kang S-M, Kim Y-H, Jung H-Y, Lee J-H, Lee I-J. 2012. Endophytic fungal association via gibberellins and indole acetic acid can improve plant growth under abiotic stress: an example of Paecilomyces formosus LHL10. BMC Microbiology 12: 3.
Li J, Van Gerrewey T, Geelen D. 2022. A meta-analysis of biostimulant yield effectiveness in field trials. Frontiers in Plant Science 13: 1–13.
Li JH, Feng NJ, Zheng DF, Le DX, Wu JS, Wang X. 2024. Regulation of seed soaking with indole-3-butyric acid potassium salt (IBA-K) on rapeseed (Brassica napus L.) seedlings under NaCl stress. BMC Plant Biology 24: 904.
Li L, Chen X. 2023. Auxin regulation on crop: from mechanisms to opportunities in soybean breeding. Molecular Breeding 2023 43: 1–26.
Li L, Gu W, Li J, Li C, Xie T, Qu D, Meng Y, Li C, Wei S. 2018. Exogenously applied spermidine alleviates photosynthetic inhibition under drought stress in maize (Zea mays L.) seedlings associated with changes in endogenous polyamines and phytohormones. Plant Physiology and Biochemistry 129: 35–55.
Li Q, Wang G, Guan C, Yang D, Wang Y, Zhang Y, Ji J, Jin C, An T. 2019. Overexpression of LcSABP, an orthologous gene for salicylic acid binding protein 2, enhances drought stress tolerance in transgenic tobacco. Frontiers in Plant Science 10: 435271.
Lichtfouse E. 2021. Sustainable agriculture reviews. Switzerland: Springer Nature.
Liu C-H, Siew W, Hung Y-T, Jiang Y-T, Huang C-H. 2021. 1-Aminocyclopropane-1-carboxylate (ACC) deaminase gene in Pseudomonas azotoformans is associated with the amelioration of salinity stress in tomato. Journal of Agricultural and Food Chemistry 69: 913–921.
Liu L, Sun Y, Di P, Cui Y, Meng Q, Wu X, Chen Y, Yuan J. 2022. Overexpression of a Zea mays Brassinosteroid-signaling kinase gene ZmBSK1 confers salt stress tolerance in maize. Frontiers in Plant Science 13: 894710.
Liu R, Liang G, Gong J, Wang J, Zhang Y, Hao Z, Li G. 2023. A potential ABA analog to increase drought tolerance in Arabidopsis thaliana. International Journal of Molecular Sciences 24: 8783.
Liu YR, Wen S, Singh BK, Zhang W, Liu Z, Hao X, Hao YY, Delgado-Baquerizo M, Tan W, Huang Q et al. 2025. Vulnerability of soil food webs to chemical pollution and climate change. Nature Ecology & Evolution 9: 1–8.
Lubovská Z, Dobrá J, Štorchová H, Wilhelmová N, Vanková R. 2014. Cytokinin oxidase/dehydrogenase overexpression modifies antioxidant defense against heat, drought and their combination in Nicotiana tabacum plants. Journal of Plant Physiology 171: 1625–1633.
Luqman M, Shahbaz M, Maqsood MF, Farhat F, Zulfiqar U, Siddiqui MH, Masood A, Aqeel M, Haider FU. 2023. Effect of strigolactone on growth, photosynthetic efficiency, antioxidant activity, and osmolytes accumulation in different maize (Zea mays L.) hybrids grown under drought stress. Plant Signaling & Behavior 18: 2262795.
Ma C, Bian C, Liu W, Sun Z, Xi X, Guo D, Liu X, Tian Y, Wang C, Zheng X. 2022a. Strigolactone alleviates the salinity-alkalinity stress of Malus hupehensis seedlings. Frontiers in Plant Science 13: 901782.
Ma Q, Lin X, Zhan M, Chen Z, Wang H, Yao F, Chen J. 2022b. Effect of an exogenous strigolactone GR24 on the antioxidant capacity and quality deterioration in postharvest sweet orange fruit stored at ambient temperature. International Journal of Food Science & Technology 57: 619–630.
Mariotti L, Fambrini M, Pugliesi C, Scartazza A. 2022. The gibberellin-deficient dwarf2 mutant of sunflower shows a high constitutive level of jasmonic and salicylic acids and an elevated energy dissipation capacity in well-watered and drought conditions. Environmental and Experimental Botany 194: 104697.
Martínez-Andújar C, Martínez-Pérez A, Albacete A, Martínez-Melgarejo PA, Dodd IC, Thompson AJ, Mohareb F, Estelles-Lopez L, Kevei Z, Ferrández-Ayela A et al. 2021. Overproduction of ABA in rootstocks alleviates salinity stress in tomato shoots. Plant, Cell & Environment 44: 2966–2986.
Marzec M, Daszkowska-Golec A, Collin A, Melzer M, Eggert K, Szarejko I. 2020. Barley strigolactone signalling mutant hvd14.d reveals the role of strigolactones in abscisic acid-dependent response to drought. Plant, Cell & Environment 43: 2239–2253.
Mazorra LM, Holton N, Bishop GJ, Núñez M. 2011. Heat shock response in tomato brassinosteroid mutants indicates that thermotolerance is independent of brassinosteroid homeostasis. Plant Physiology and Biochemistry 49: 1420–1428.
Mekureyaw MF, Pandey C, Hennessy RC, Nicolaisen MH, Liu F, Nybroe O, Roitsch T. 2022. The cytokinin-producing plant beneficial bacterium Pseudomonas fluorescens G20-18 primes tomato (Solanum lycopersicum) for enhanced drought stress responses. Journal of Plant Physiology 270: 153629.
Mittler R, Zandalinas SI, Fichman Y, Van Breusegem F. 2022. Reactive oxygen species signalling in plant stress responses. Nature Reviews Molecular Cell Biology 23: 663–679.
Mizokami Y, Noguchi K, Kojima M, Sakakibara H, Terashima I. 2015. Mesophyll conductance decreases in the wild type but not in an ABA-deficient mutant (aba1) of Nicotiana plumbaginifolia under drought conditions. Plant, Cell & Environment 38: 388–398.
Mohammed AR, Cothren JT, Chen M, Tarpley L. 2015. 1-Methylcyclopropene (1-MCP)-induced alteration in leaf photosynthetic rate, chlorophyll fluorescence, respiration and membrane damage in rice (Oryza sativa L.) under high night temperature. Journal of Agronomy and Crop Science 201: 105–116.
Mohi-Ud-Din M, Talukder D, Rohman M, Ahmed JU, Jagadish SVK, Islam T, Hasanuzzaman M. 2021. Exogenous application of methyl jasmonate and salicylic acid mitigates drought-induced oxidative damages in French bean (Phaseolus vulgaris L.). Plants 10: 2066.
Mohsin SM, Hasanuzzaman M, Parvin K, Fujita M. 2020. Pretreatment of wheat (Triticum aestivum L.) seedlings with 2,4-D improves tolerance to salinity-induced oxidative stress and methylglyoxal toxicity by modulating ion homeostasis, antioxidant defenses, and glyoxalase systems. Plant Physiology and Biochemistry 152: 221–231.
Moradi S, Baninasab B, Gholami M, Ghobadi C. 2017. Paclobutrazol application enhances antioxidant enzyme activities in pomegranate plants affected by cold stress. The Journal of Horticultural Science and Biotechnology 92: 65–71.
Morales M, Munné-Bosch S. 2019. Malondialdehyde: facts and artifacts. Plant Physiology 180: 1246–1250.
Mushtaq N, Wang Y, Fan J, Li Y, Ding J. 2022. Down-regulation of cytokinin receptor gene SlHK2 improves plant tolerance to drought, heat, and combined stresses in tomato. Plants 11: 154.
Naboulsi I, Aboulmouhajir A, Kouisni L, Bekkaoui F, Yasri A. 2018. Plants extracts and secondary metabolites, their extraction methods and use in agriculture for controlling crop stresses and improving productivity: A review. Academia Journal of Medicinal Plants 6: 223–240.
Naeem M, Basit A, Ahmad I, Mohamed HI, Wasila H. 2020. Effect of salicylic acid and salinity stress on the performance of tomato plants. Gesunde Pflanzen 72: 393–402.
Nagar S, Singh VP, Arora A, Dhakar R, Singh N, Singh GP, Meena S, Kumar S, Shiv RR. 2021. Understanding the role of gibberellic acid and Paclobutrazol in terminal heat stress tolerance in wheat. Frontiers in Plant Science 12: 692252.
Najeeb U, Atwell BJ, Bange MP, Tan DKY. 2015. Aminoethoxyvinylglycine (AVG) ameliorates waterlogging-induced damage in cotton by inhibiting ethylene synthesis and sustaining photosynthetic capacity. Plant Growth Regulation 76: 83–98.
Nanda S, Kumar G, Hussain S. 2021. Utilization of seaweed-based biostimulants in improving plant and soil health: current updates and future prospective. International journal of Environmental Science and Technology 2021: 1–14.
Nazara R, Umara S, Khanb NA. 2015. Exogenous salicylic acid improves photosynthesis and growth through increase in ascorbate-glutathione metabolism and S assimilation in mustard under salt stress. Plant Signaling & Behavior 10: 1–10.
Nitsch L, Kohlen W, Oplaat C, Charnikhova T, Cristescu S, Michieli P, Wolters-Arts M, Bouwmeester H, Mariani C, Vriezen WH. 2012. ABA-deficiency results in reduced plant and fruit size in tomato. Journal of Plant Physiology 169: 878–883.
Nivetha N, Asha AD, Krishna GK, Chinnusamy V, Paul S. 2024. Rhizobacteria Bacillus spp. mitigate osmotic stress and improve seed germination in mustard by regulating osmolyte and plant hormone signaling. Physiologia Plantarum 176: 1–15.
Noreen S, Siddiq A, Hussain K, Ahmad S, Hasanuzzama M. 2017. Foliar application of salicylic acid with salinity stress on physiological and biochemical attributes of sunflower (Helianthus annuus L.) crop. Acta Scientiarum Polonorum. Hortorum Cultus 16: 57–74.
Núñez Vázquez M, Reyes Guerrero Y, Rosabal Ayan L, Martínez L, González Cepero MC. 2013. Brassinosteroids and its analogs enhance the seedling growth of two rice (Oryza sativa L.) genotypes under saline conditions. Cultivos Tropicales 34: 74–80.
Oguz MC. 2024. Stimulating endogenous hormone content by plant extracts: increased in vitro regeneration of flax (Linum usitatissimum) cultivars. Journal of Crop Science and Biotechnology 28: 1–13.
Okamoto M, Peterson FC, Defries A, Park SY, Endo A, Nambara E, Volkman BF, Cutler SR. 2013. Activation of dimeric ABA receptors elicits guard cell closure, ABA-regulated gene expression, and drought tolerance. Proceedings of the National Academy of Sciences, USA 110: 12132–12137.
Oklestkova J, Rárová L, Kvasnica M, Strnad M. 2015. Brassinosteroids: synthesis and biological activities. Phytochemistry Reviews 14: 1053–1072.
Olaetxea M, De Hita D, Garcia CA, Fuentes M, Baigorri R, Mora V, Garnica M, Urrutia O, Erro J, Zamarreño AM et al. 2018. Hypothetical framework integrating the main mechanisms involved in the promoting action of rhizospheric humic substances on plant root- and shoot- growth. Applied Soil Ecology 123: 521–537.
Omena-Garcia RP, Oliveira Martins A, Medeiros DB, Vallarino JG, Mendes Ribeiro D, Fernie AR, Araújo WL, Nunes-Nesi A. 2019. Growth and metabolic adjustments in response to gibberellin deficiency in drought stressed tomato plants. Environmental and Experimental Botany 159: 95–107.
Othibeng K, Nephali L, Ramabulana AT, Steenkamp P, Petras D, Bin KK, Opperman H, Huyser J, Tugizimana F. 2021. A metabolic choreography of maize plants treated with a humic substance-based biostimulant under normal and starved conditions. Metabolites 11: 1–17.
Patel K, Agarwal P, Agarwal PK. 2018. Kappaphycus alvarezii sap mitigates abiotic-induced stress in Triticum durum by modulating metabolic coordination and improves growth and yield. Journal of Applied Phycology 30: 2659–2673.
Pehlivan N, Yesilyurt AM, Durmus N, Karaoglu SA. 2017. Trichoderma lixii ID11D seed biopriming mitigates dose dependent salt toxicity in maize. Acta Physiologiae Plantarum 39: 1–12.
Pospíšilová H, Jiskrova E, Vojta P, Mrizova K, Kokáš F, Čudejková MM, Bergougnoux V, Plíhal O, Klimešová J, Novák O. 2016. Transgenic barley overexpressing a cytokinin dehydrogenase gene shows greater tolerance to drought stress. New Biotechnology 33: 692–705.
Pradhan M, Sahoo RK, Swain DM, Dangar TK, Mohanty S. 2018. Inoculation of Azotobacter vinellandii (SRI Az3) to rice plant increases stress tolerance in rice plant during drought stress. ORYZA – An International Journal on Rice 55: 406–412.
Qiao Z, Yao C, Sun S, Zhang F, Yao X, Li X, Zhang J, Jiang X. 2023. Spraying S-ABA can alleviate the growth inhibition of corn (Zea mays L.) under water-deficit stress. Journal of Soil Science and Plant Nutrition 23: 1222–1234.
Qin XQ, Zeevaart JAD. 2002. Overexpression of a 9-cis-epoxycarotenoid dioxygenase gene in Nicotiana plumbaginifolia increases abscisic acid and phaseic acid levels and enhances drought tolerance. Plant Physiology 128: 544–551.
Qiu C-W, Zhang C, Wang N-H, Mao W, Wu F. 2021. Strigolactone GR24 improves cadmium tolerance by regulating cadmium uptake, nitric oxide signaling and antioxidant metabolism in barley (Hordeum vulgare L.). Environmental Pollution 273: 116486.
Quezada-Martinez D, Addo Nyarko CP, Schiessl SV, Mason AS. 2021. Using wild relatives and related species to build climate resilience in Brassica crops. Theoretical and Applied Genetics 134: 1711–1728.
Rademacher W. 2015. Plant growth regulators: backgrounds and uses in plant production. Journal of Plant Growth Regulation 34: 845–872.
Rakkammal K, Pandian S, Maharajan T, Antony Ceasar S, Sohn SI, Ramesh M. 2024. Humic acid regulates gene expression and activity of antioxidant enzymes to inhibit the salt-induced oxidative stress in finger millet. Cereal Research Communications 52: 397–411.
Raspor M, Mrvaljević M, Savić J, Ćosić T, Kaleri AR, Pokimica N, Cingel A, Ghalawnji N, Motyka V, Ninković S. 2024. Cytokinin deficiency confers enhanced tolerance to mild, but decreased tolerance to severe salinity stress in in vitro grown potato. Frontiers in Plant Science 14: 1296520.
Rathor P, Upadhyay P, Ullah A, Gorim LY, Thilakarathna MS. 2024. Humic acid improves wheat growth by modulating auxin and cytokinin biosynthesis pathways. AoB Plants 16: 1–15.
Rathore RS, Mishra M, Pareek A, Singla-Pareek SL. 2024. Concurrent improvement of rice grain yield and abiotic stress tolerance by overexpression of cytokinin activating enzyme LONELY GUY (OsLOG). Plant Physiology and Biochemistry 211: 108635.
Réthoré E, Ali N, Yvin JC, Hosseini SA. 2020. Silicon regulates source to sink metabolic homeostasis and promotes growth of rice plants under sulfur deficiency. International Journal of Molecular Sciences 21: 1–21.
Reyes Guerrero Y, Martínez González L, Núñez VM. 2017. Biobras-16 foliar spraying enhances rice (Oryza sativa L.) young plant growth under NaCl treatment. Cultivos Tropicales 38: 155–156.
Rezazadeh A, Harkess RL, Bi G. 2016. Effects of paclobutrazol and flurprimidol on water stress amelioration in potted red firespike. HortTechnology 26: 26–29.
Romano I, Ventorino V, Pepe O. 2020. Effectiveness of plant beneficial microbes: overview of the methodological approaches for the assessment of root colonization and persistence. Frontiers in Plant Science 11: 487940.
Rosheen SS, Utreja D. 2023. Salicylic acid: synthetic strategies and their biological activities. ChemistrySelect 8: e202204614.
Rouphael Y, Colla G. 2020. Biostimulants in agriculture. Frontiers in Plant Science 11: 40.
Rouphael Y, du Jardin P, Brown P, De Pascale S, Colla G. 2020. Biostimulants for sustainable crop production. Cambridge, UK: Burleigh Dodds Science Publishing.
Rubio V, Bustos R, Irigoyen ML, Cardona-López X, Rojas-Triana M, Paz-Ares J. 2009. Plant hormones and nutrient signaling. Plant Molecular Biology 69: 361–373.
Rugiu L, Panova M, Pereyra RT, Jormalainen V. 2020. Gene regulatory response to hyposalinity in the brown seaweed Fucus vesiculosus. BMC Genomics 21: 1–17.
Sahni S, Prasad BD, Liu Q, Grbic V, Sharpe A, Singh SP, Krishna P. 2016. Overexpression of the brassinosteroid biosynthetic gene DWF4 in Brassica napus simultaneously increases seed yield and stress tolerance. Scientific Reports 6: 1–14.
Saleem K, Asghar MA, Raza A, Pan K, Ullah A, Javed HH, Seleiman MF, Imran S, Nadeem SM, Khan KS. 2024. Alleviating drought stress in strawberry plants: unraveling the role of paclobutrazol as a growth regulator and reducer of oxidative stress induced by reactive oxygen and carbonyl species. Journal of Plant Growth Regulation 43: 3238–3253.
Sangha JS, Kelloway S, Critchley AT, Prithiviraj B. 2014. Seaweeds (Macroalgae) and their extracts as contributors of plant productivity and quality. the current status of our understanding. In: Advances in botanical research. USA: Academic Press Inc., 189–219.
Saravanakumar D, Samiyappan R. 2007. ACC deaminase from Pseudomonas fluorescens mediated saline resistance in groundnut (Arachis hypogea) plants. Journal of Applied Microbiology 102: 1283–1292.
Sariñana-Aldaco O, Benavides-Mendoza A, Robledo-Olivo A, González-Morales S. 2022. The biostimulant effect of hydroalcoholic extracts of Sargassum spp. in tomato seedlings under salt stress. Plants 11: 1–24.
Saruhan N, Saglam A, Kadioglu A. 2012. Salicylic acid pretreatment induces drought tolerance and delays leaf rolling by inducing antioxidant systems in maize genotypes. Acta Physiologiae Plantarum 34: 97–106.
Serna M, Coll Y, Zapata PJ, Botella MÁ, Pretel MT, Amorós A. 2015. A brassinosteroid analogue prevented the effect of salt stress on ethylene synthesis and polyamines in lettuce plants. Scientia Horticulturae 185: 105–112.
Shahzad R, Khan AL, Bilal S, Waqas M, Kang S-M, Lee I-J. 2017. Inoculation of abscisic acid-producing endophytic bacteria enhances salinity stress tolerance in Oryza sativa. Environmental and Experimental Botany 136: 68–77.
Sharma L, Dalal M, Verma RK, Kumar SVV, Yadav SK, Pushkar S, Kushwaha SR, Bhowmik A, Chinnusamy V. 2018. Auxin protects spikelet fertility and grain yield under drought and heat stresses in rice. Environmental and Experimental Botany 150: 9–24.
Sheikh Mohammadi MH, Etemadi N, Arab MM, Aalifar M, Arab M, Pessarakli M. 2017. Molecular and physiological responses of Iranian Perennial ryegrass as affected by Trinexapac ethyl, Paclobutrazol and Abscisic acid under drought stress. Plant Physiology and Biochemistry 111: 129–143.
Shukry WM, Abu-Ria ME, Abo-Hamed SA, Anis GB, Ibraheem F. 2023. The efficiency of humic acid for improving salinity tolerance in salt sensitive rice (Oryza sativa): growth responses and physiological mechanisms. Gesunde Pflanzen 75: 2639–2653.
Siddiqui MH, Khan MN, Mohammad F, Khan MMA. 2008. Role of nitrogen and gibberellin (GA3) in the regulation of enzyme activities and in osmoprotectant accumulation in Brassica juncea L. under salt stress. Journal of Agronomy and Crop Science 194: 214–224.
Singh RP, Pandey DM, Jha PN, Ma Y. 2022. ACC deaminase producing rhizobacterium Enterobacter cloacae ZNP-4 enhance abiotic stress tolerance in wheat plant. PLoS ONE 17: 1–23.
Singh S, Tripathi A, Chanotiya CS, Barnawal D, Singh P, Patel VK, Vajpayee P, Kalra A. 2020. Cold stress alleviation using individual and combined inoculation of ACC deaminase producing microbes in Ocimum sanctum. Environmental Sustainability 3: 289–301.
Sitohy MZ, Desoky ESM, Osman A, Rady MM. 2020. Pumpkin seed protein hydrolysate treatment alleviates salt stress effects on Phaseolus vulgaris by elevating antioxidant capacity and recovering ion homeostasis. Scientia Horticulturae 271: 1–11.
Song Y, Lv D, Jiang M, Han Y, Sun Y, Zhu S, Chen J, Zhao T. 2023. Exogenous strigolactones enhance salinity tolerance in cotton (Gossypium hirsutum L.) seedlings. Plant Stress 10: 100235.
Sorrentino M, De Diego N, Ugena L, Spíchal L, Lucini L, Miras-Moreno B, Zhang L, Rouphael Y, Colla G, Panzarová K. 2021. Seed priming with protein hydrolysates improves Arabidopsis growth and stress tolerance to abiotic stresses. Frontiers in Plant Science 12: 1–17.
Soskine M, Tawfik DS. 2010. Mutational effects and the evolution of new protein functions. Nature Reviews Genetics 11: 572–582.
Sulpice R, McKeown PC. 2015. Moving toward a comprehensive map of central plant metabolism. Annual Review of Plant Biology 66: 187–210.
Sun L, Zhang Q, Wu J, Zhang L, Jiao X, Zhang S, Zhang Z, Sun D, Lu T, Sun Y. 2014. Two rice authentic histidine phosphotransfer proteins, OsAHP1 and OsAHP2, mediate cytokinin signaling and stress responses in rice. Plant Physiology 165: 335–345.
Tanaka N, Matsuoka M, Kitano H, Asano T, Kaku H, Komatsu S. 2006. gid1, a gibberellin-insensitive dwarf mutant, shows altered regulation of probenazole-inducible protein (PBZ1) in response to cold stress and pathogen attack. Plant, Cell & Environment 29: 619–631.
Thakur R, Yadav S. 2024. Biofilm forming, exopolysaccharide producing and halotolerant, bacterial consortium mitigates salinity stress in Triticum aestivum. International Journal of Biological Macromolecules 262: 1–15.
Tian Y, Zhang H, Pan X, Chen X, Zhang Z, Lu X, Huang R. 2011. Overexpression of ethylene response factor TERF2 confers cold tolerance in rice seedlings. Transgenic Research 20: 857–866.
Timm CM, Carter KR, Carrell AA, Jun S-R, Jawdy SS, Vélez JM, Gunter LE, Yang Z, Nookaew I, Engle NL et al. 2018. Abiotic stresses shift belowground populus -associated bacteria toward a core stress microbiome. mSystems 3: 1–17.
Toulotte JM, Pantazopoulou CK, Sanclemente MA, Voesenek LACJ, Sasidharan R. 2022. Water stress resilient cereal crops: lessons from wild relatives. Journal of Integrative Plant Biology 64: 412–430.
Tounekti T, Hernández I, Müller M, Khemira H, Munné-Bosch S. 2011. Kinetin applications alleviate salt stress and improve the antioxidant composition of leaf extracts in Salvia officinalis. Plant Physiology and Biochemistry 49: 1165–1176.
Trevisan S, Manoli A, Quaggiotti S. 2019. A novel biostimulant, belonging to protein hydrolysates, mitigates abiotic stress effects on maize seedlings grown in hydroponics. Agronomy 9: 1–16.
Tworkoski T, Wisniewski M, Artlip T. 2011. Application of BABA and s-ABA for drought resistance in apple. Journal of Applied Horticulture 13: 85–90.
Ullah A, Zeng F, Tariq A, Asghar MA, Saleem K, Raza A, Naseer MA, Zhang Z, Noor J. 2022. Exogenous naphthaleneacetic acid alleviated alkalinity-induced morpho-physio-biochemical damages in Cyperus esculentus L. var. sativus Boeck. Frontiers in Plant Science 13: 1018787.
Vaidya AS, Helander JDM, Peterson FC, Elzinga D, Dejonghe W, Kaundal A, Park S-Y, Xing Z, Mega R, Takeuchi J et al. 2019. Dynamic control of plant water use using designed ABA receptor agonists. Science 366: eaaw8848.
Visentin I, Vitali M, Ferrero M, Zhang Y, Ruyter-Spira C, Novák O, Strnad M, Lovisolo C, Schubert A, Cardinale F. 2016. Low levels of strigolactones in roots as a component of the systemic signal of drought stress in tomato. New Phytologist 212: 954–963.
Walia US. 2023. Modern techniques for crop management.
Walker-Simmons M, Kudrna DA, Warner RL. 1989. Reduced accumulation of ABA during water stress in a molybdenum cofactor mutant of barley. Plant Physiology 90: 728–733.
Wang D, Yang Z, Wu M, Wang W, Wang Y, Nie S. 2022. Enhanced brassinosteroid signaling via the overexpression of SlBRI1 positively regulates the chilling stress tolerance of tomato. Plant Science 320: 111281.
Wang F, Wan C, Wu W, Pan Y, Cheng X, Li C, Pi J, Chen X. 2023a. Exogenous methyl jasmonate (MeJA) enhances the tolerance to cadmium (Cd) stress of okra (Abelmoschus esculentus L.) plants. Plant Cell, Tissue and Organ Culture (PCTOC) 155: 907–922.
Wang F, Wan C, Wu W, Zhang Y, Pan Y, Chen X, Li C, Pi J, Wang Z, Ye Y. 2023b. Methyl jasmonate (MeJA) enhances salt tolerance of okra (Abelmoschus esculentus L.) plants by regulating ABA signaling, osmotic adjustment substances, photosynthesis and ROS metabolism. Scientia Horticulturae 319: 112145.
Wang J, Wang D, Zhu M, Li F. 2021. Exogenous 6-benzyladenine improves waterlogging tolerance in maize seedlings by mitigating oxidative stress and upregulating the ascorbate-glutathione cycle. Frontiers in Plant Science 12: 680376.
Wang M, Qiao J, Yu C, Chen H, Sun C, Huang L, Li C, Geisler M, Qian Q, Jiang DA. 2019. The auxin influx carrier, OsAUX3, regulates rice root development and responses to aluminium stress. Plant, Cell & Environment 42: 1125–1138.
Wang N, Wang X, Shi J, Liu X, Xu Q, Zhou H, Song M, Yan G. 2019. Mepiquat chloride-priming induced salt tolerance during seed germination of cotton (Gossypium hirsutum L.) through regulating water transport and K+/Na+ homeostasis. Environmental and Experimental Botany 159: 168–178.
Wang W, Zhang C, Zheng W, Lv H, Li J, Liang B, Zhou W. 2022. Seed priming with protein hydrolysate promotes seed germination via reserve mobilization, osmolyte accumulation and antioxidant systems under PEG-induced drought stress. Plant Cell Reports 41: 2173–2186.
Wang Y, Hu J, Qin G, Cui H, Wang Q. 2012. Salicylic acid analogues with biological activity may induce chilling tolerance of maize (Zea mays) seeds. Botany 90: 845–855.
Weijers D, Nemhauser J, Yang Z. 2018. Auxin: small molecule, big impact. Journal of Experimental Botany 69: 133–136.
Wi SJ, Jang SJ, Park KY. 2010. Inhibition of biphasic ethylene production enhances tolerance to abiotic stress by reducing the accumulation of reactive oxygen species in Nicotiana tabacum. Molecules and Cells 30: 37–49.
Win NM, Yoo J, Lwin HP, Lee EJ, Kang IK, Lee J. 2021. Effects of 1-methylcyclopropene and aminoethoxyvinylglycine treatments on fruit quality and antioxidant metabolites in cold-stored ‘Sangjudungsi’ persimmons. Horticulture, Environment and Biotechnology 62: 891–905.
Wittenmayer L, Merbach W. 2005. Plant responses to drought and phosphorus deficiency: contribution of phytohormones in root-related processes. Journal of Plant Nutrition and Soil Science 168: 531–540.
WMO. 2024. Climate change indicators reached record levels in 2023: WMO.
Wu H, Bai B, Lu X, Li H. 2023. A gibberellin-deficient maize mutant exhibits altered plant height, stem strength and drought tolerance. Plant Cell Reports 42: 1687–1699.
Wu H, Wu X, Li Z, Duan L, Zhang M. 2012. Physiological evaluation of drought stress tolerance and recovery in cauliflower (Brassica oleracea L.) seedlings treated with methyl jasmonate and coronatine. Journal of Plant Growth Regulation 31: 113–123.
Wu W, Zhang Q, Ervin EH, Yang Z, Zhang X. 2017. Physiological mechanism of enhancing salt stress tolerance of perennial ryegrass by 24-epibrassinolide. Frontiers in Plant Science 8: 1017.
Xing X, Jiang H, Zhou Q, Xing H, Jiang H, Wang S. 2016a. Improved drought tolerance by early IAA-and ABA-dependent H2O2 accumulation induced by α-naphthaleneacetic acid in soybean plants. Plant Growth Regulation 80: 303–314.
Xing X, Jiang H, Zhou Q, Xing H, Jiang H, Wang S. 2016b. Improved drought tolerance by early IAA- and ABA-dependent H2O2 accumulation induced by α-naphthaleneacetic acid in soybean plants. Plant Growth Regulation 80: 303–314.
Xu Y, Burgess P, Zhang X, Huang B. 2016. Enhancing cytokinin synthesis by overexpressing ipt alleviated drought inhibition of root growth through activating ROS-scavenging systems in Agrostis stolonifera. Journal of Experimental Botany 67: 1979–1992.
Xu Y, Tian J, Gianfagna T, Huang B. 2009. Effects of SAG12-ipt expression on cytokinin production, growth and senescence of creeping bentgrass (Agrostis stolonifera L.) under heat stress. Plant Growth Regulation 57: 281–291.
Yadav G, Sharma N, Goel A, Varma A, Mishra A, Kothari SL, Choudhary DK. 2024. Trichoderma mediated metal chelator and its role in Solanum melongena growth under heavy metals. Journal of Plant Growth Regulation 43: 178–200.
Yaghoubi Khanghahi M, AbdElgawad H, Verbruggen E, Korany SM, Alsherif EA, Beemster GTS, Crecchio C. 2022. Biofertilisation with a consortium of growth-promoting bacterial strains improves the nutritional status of wheat grain under control, drought, and salinity stress conditions. Physiologia Plantarum 174: 1–15.
Yan J, Li S, Gu M, Yao R, Li Y, Chen J, Yang M, Tong J, Xiao L, Nan F et al. 2016. Endogenous bioactive jasmonate is composed of a set of (+)-7-iso-JA-amino acid conjugates. Plant Physiology 172: 2154–2164.
Yang C, Wang H, Ouyang Q, Chen G, Fu X, Hou D, Xu H. 2023. Deficiency of auxin efflux carrier OsPIN1b impairs chilling and drought tolerance in rice. Plants 12: 4058.
Yang D, Li Y, Shi Y, Cui Z, Luo Y, Zheng M, Chen J, Li Y, Yin Y, Wang Z. 2016. Exogenous cytokinins increase grain yield of winter wheat cultivars by improving stay-green characteristics under heat stress. PLoS ONE 11: e0155437.
Yao C, Zhang F, Sun X, Shang D, He F, Li X, Zhang J, Jiang X. 2019. Effects of S-abscisic acid (S-ABA) on seed germination, seedling growth, and asr1 gene expression under drought stress in maize. Journal of Plant Growth Regulation 38: 1300–1313.
Ye L, Zhao X, Bao E, Cao K, Zou Z. 2019. Effects of arbuscular mycorrhizal fungi on watermelon growth, elemental uptake, antioxidant, and photosystem ii activities and stress-response gene expressions under salinity-alkalinity stresses. Frontiers in Plant Science 10: 1–12.
Yu C, Sun C, Shen C, Wang S, Liu F, Liu Y, Chen Y, Li C, Qian Q, Aryal B. 2015. The auxin transporter, Os AUX 1, is involved in primary root and root hair elongation and in Cd stress responses in rice (Oryza sativa L.). The Plant Journal 83: 818–830.
Zhang H, Zhu J, Gong Z, Zhu JK. 2021. Abiotic stress responses in plants. Nature Reviews Genetics 2021 23: 104–119.
Zhang X-H, Ma C, Zhang L, Su M, Wang J, Zheng S, Zhang T-G. 2022. GR24-mediated enhancement of salt tolerance and roles of H2O2 and Ca2+ in regulating this enhancement in cucumber. Journal of Plant Physiology 270: 153640.
Zhang Z, Li F, Li D, Zhang H, Huang R. 2010. Expression of ethylene response factor JERF1 in rice improves tolerance to drought. Planta 232: 765–774.
Zhao S, Ma Q, Xu X, Li G, Hao L. 2016. Tomato jasmonic acid-deficient mutant spr2 seedling response to cadmium stress. Journal of Plant Growth Regulation 35: 603–610.
Zou P, Lu X, Zhao H, Yuan Y, Meng L, Zhang C, Li Y. 2019. Polysaccharides derived from the brown algae Lessonia nigrescens enhance salt stress tolerance to wheat seedlings by enhancing the antioxidant system and modulating intracellular ion concentration. Frontiers in Plant Science 10: 1–15.
Zuluaga MYA, Monterisi S, Rouphael Y, Colla G, Lucini L, Cesco S, Pii Y. 2023. Different vegetal protein hydrolysates distinctively alleviate salinity stress in vegetable crops: a case study on tomato and lettuce. Frontiers in Plant Science 14: 1–11.
Zwanenburg B, Blanco-Ania D. 2018. Strigolactones: new plant hormones in the spotlight. Journal of Experimental Botany 69: 2205–2218.