| [1] |
Wang W, Liu S, Zhang Q, Zhao Y, Dong Y, et al. 2025. Increasing aridity and interannual precipitation variability drives resilience declines in restored forests across China. |
| [2] |
Sun Z, Li S, Chen W, Zhang J, Zhang L, et al. 2021. Plant dehydrins: expression, regulatory networks, and protective roles in plants challenged by abiotic stress. |
| [3] |
McGregor IR, Helcoski R, Kunert N, Tepley AJ, Gonzalez-Akre EB, et al. 2021. Tree height and leaf drought tolerance traits shape growth responses across droughts in a temperate broadleaf forest. |
| [4] |
Anderegg WR, Berry JA, Smith DD, Sperry JS, Anderegg LD, et al. 2012. The roles of hydraulic and carbon stress in a widespread climate-induced forest die-off. |
| [5] |
Choi SJ, Lee Z, Kim S, Jeong E, Shim JS. 2023. Modulation of lignin biosynthesis for drought tolerance in plants. |
| [6] |
Riaz MW, Yousaf MI, Hussain Q, Yasir M, Sajjad M, et al. 2023. Role of lignin in wheat plant for the enhancement of resistance against lodging and biotic and abiotic stresses. |
| [7] |
Zhai X, Yan X, Zenda T, Wang N, Dong A, et al. 2024. Overexpression of the peroxidase gene ZmPRX1 increases maize seedling drought tolerance by promoting root development and lignification. |
| [8] |
Boulebd H. 2025. A comprehensive DFT-based study of the antioxidant properties of monolignols: mechanism, kinetics, and influence of physiological environments. |
| [9] |
Ménard D, Blaschek L, Kriechbaum K, Lee CC, Serk H, et al. 2022. Plant biomechanics and resilience to environmental changes are controlled by specific lignin chemistries in each vascular cell type and morphotype. |
| [10] |
Cantó-Pastor A, Kajala K, Shaar-Moshe L, Manzano C, Timilsena P, et al. 2024. A suberized exodermis is required for tomato drought tolerance. |
| [11] |
Atkinson NJ, Urwin PE. 2012. The interaction of plant biotic and abiotic stresses: from genes to the field. |
| [12] |
Shaik R, Ramakrishna W. 2014. Machine learning approaches distinguish multiple stress conditions using stress-responsive genes and identify candidate genes for broad resistance in rice. |
| [13] |
Wu T, Zhang M, Zhang H, Huang K, Chen M, et al. 2019. Identification and characterization of EDT1 conferring drought tolerance in rice. |
| [14] |
Gou J, Debnath S, Sun L, Flanagan A, Tang Y, et al. 2018. From model to crop: functional characterization of SPL8 in M. truncatula led to genetic improvement of biomass yield and abiotic stress tolerance in alfalfa. |
| [15] |
Yamasaki K, Kigawa T, Inoue M, Tateno M, Yamasaki T, et al. 2004. A novel zinc-binding motif revealed by solution structures of DNA-binding domains of Arabidopsis SBP-family transcription factors. |
| [16] |
Mermod M, Takusagawa M, Kurata T, Kamiya T, Fujiwara T, et al. 2019. SQUAMOSA promoter-binding protein-like 7 mediates copper deficiency response in the presence of high nitrogen in Arabidopsis thaliana. |
| [17] |
Wang L, Yu P, Lyu J, Hu Y, Han C, et al. 2021. BZR1 physically interacts with SPL9 to regulate the vegetative phase change and cell elongation in Arabidopsis. |
| [18] |
Zhang QQ, Wang JG, Wang LY, Wang JF, Wang Q, et al. 2020. Gibberellin repression of axillary bud formation in Arabidopsis by modulation of DELLA-SPL9 complex activity. |
| [19] |
Cao R, Guo L, Ma M, Zhang W, Liu X, et al. 2019. Identification and functional characterization of squamosa promoter binding protein-like gene TaSPL16 in wheat (Triticum aestivum L.). |
| [20] |
Xiong J, Bai Y, Ma C, Zhu H, Zheng D, et al. 2019. Molecular cloning and characterization of SQUAMOSA-promoter binding protein-like gene FvSPL10 from woodland strawberry (Fragaria vesca). |
| [21] |
Zhao M, Liu R, Chen Y, Cui J, Ge W, et al. 2022. Molecular identification and functional verification of SPL9 and SPL15 of Lilium. |
| [22] |
Cao Y, Chen R, Wang WT, Wang DH, Cao XY. 2021. SmSPL6 induces phenolic acid biosynthesis and affects root development in Salvia miltiorrhiza. |
| [23] |
Hu L, Chen W, Yang W, Li X, Zhang C, et al. 2021. OsSPL9 regulates grain number and grain yield in rice. |
| [24] |
Qin M, Zhang Y, Yang Y, Miao C, Liu S. 2020. Seed-specific overexpression of SPL12 and IPA1 improves seed dormancy and grain size in rice. |
| [25] |
Cui L, Zheng F, Wang J, Zhang C, Xiao F, et al. 2020. miR156a-targeted SBP-Box transcription factor SlSPL13 regulates inflorescence morphogenesis by directly activating SFT in tomato. |
| [26] |
Li J, Tang B, Li Y, Li C, Guo M, et al. 2021. Rice SPL10 positively regulates trichome development through expression of HL6 and auxin-related genes. |
| [27] |
Li Y, Han S, Sun X, Khan NU, Zhong Q, et al. 2023. Variations in OsSPL10 confer drought tolerance by directly regulating OsNAC2 expression and ROS production in rice. |
| [28] |
Wu Z, Cao Y, Yang R, Qi T, Hang Y, et al. 2016. Switchgrass SBP-box transcription factors PvSPL1 and 2 function redundantly to initiate side tillers and affect biomass yield of energy crop. |
| [29] |
Lian L, He W, Cai Q, Zhang H, Ren C, et al. 2018. Physiological and transcriptome analysis of indica rice 'MH86' overexpressing OsSPL14. |
| [30] |
Tang M, Bai X, Xia Y, Huang P, Xu ZF. 2026. SBP-box transcription factor JcSPL9 regulates both seed yield and oil content in the biofuel plant Jatropha curcas. |
| [31] |
Li Y, Ma J, Pan R, Wang T. 2024. Hydrogen production from Fraxinus mandshurica solid wood waste using FeCl3 as a non-precious metal Lewis acid catalyst: a comprehensive utilization approach. |
| [32] |
Wang J, Wu L, Zhao X, Fan J, Zhang C, et al. 2013. Influence of ground flora on Fraxinus mandshurica seedling growth on abandoned land and beneath forest canopy. |
| [33] |
He B, Gao S, Lu H, Yan J, Li C, et al. 2022. Genome-wide analysis and molecular dissection of the SPL gene family in Fraxinus mandshurica. |
| [34] |
Mendes GGM, Mota TR, Bossoni GEB, Marchiosi R, de Oliveira DM, et al. 2022. Inhibiting tricin biosynthesis improves maize lignocellulose saccharification. |
| [35] |
Yu M, Wang M, Gyalpo T, Basang Y. 2021. Stem lodging resistance in hulless barley: transcriptome and metabolome analysis of lignin biosynthesis pathways in contrasting genotypes. |
| [36] |
Zhang L, Jia X, Zhao Y, Shan L, Zhang Y, et al. 2025. Lagged and cumulative effects of drought on global vegetation greenness, coverage, and productivity. |
| [37] |
Gupta A, Rico-Medina A, Caño-Delgado AI. 2020. The physiology of plant responses to drought. |
| [38] |
Dong NQ, Lin HX. 2021. Contribution of phenylpropanoid metabolism to plant development and plant–environment interactions. |
| [39] |
Hu Y, Wu Q, Peng Z, Sprague SA, Wang W, et al. 2017. Silencing of OsGRXS17 in rice improves drought stress tolerance by modulating ROS accumulation and stomatal closure. |
| [40] |
Zhu Y, Huang P, Guo P, Chong L, Yu G, et al. 2020. CDK8 is associated with RAP2.6 and SnRK2.6 and positively modulates abscisic acid signaling and drought response in Arabidopsis. |
| [41] |
Li S, Lin YJ, Wang P, Zhang B, Li M, et al. 2019. The AREB1 transcription factor influences histone acetylation to regulate drought responses and tolerance in Populus trichocarpa. |
| [42] |
Szőllősi R. 2014. Chapter 3 - Superoxide dismutase (SOD) and abiotic stress tolerance in plants: an overview. In Oxidative Damage to Plants, ed. Ahmad P. San Diego: Academic Press. pp. 89−129 doi: 10.1016/B978-0-12-799963-0.00003-4 |
| [43] |
Wang X, Liu H, Yu F, Hu B, Jia Y, et al. 2019. Differential activity of the antioxidant defence system and alterations in the accumulation of osmolyte and reactive oxygen species under drought stress and recovery in rice (Oryza sativa L.) tillering. |
| [44] |
Hanly A, Karagiannis J, Lu QSM, Tian L, Hannoufa A. 2020. Characterization of the role of SPL9 in drought stress tolerance in Medicago sativa. |
| [45] |
Li S, Cheng Z, Li Z, Dong S, Yu X, et al. 2022. MeSPL9 attenuates drought resistance by regulating JA signaling and protectant metabolite contents in cassava. |
| [46] |
Shi H, Chen L, Ye T, Liu X, Ding K, et al. 2014. Modulation of auxin content in Arabidopsis confers improved drought stress resistance. |
| [47] |
Chaves MM, Flexas J, Pinheiro C. 2009. Photosynthesis under drought and salt stress: regulation mechanisms from whole plant to cell. |
| [48] |
Sato H, Mizoi J, Shinozaki K, Yamaguchi-Shinozaki K. 2024. Complex plant responses to drought and heat stress under climate change. |
| [49] |
Hamanishi ET, Thomas BR, Campbell MM. 2012. Drought induces alterations in the stomatal development program in Populus. |
| [50] |
Fraser LH, Greenall A, Carlyle C, Turkington R, Friedman CR. 2009. Adaptive phenotypic plasticity of Pseudoroegneria spicata: response of stomatal density, leaf area and biomass to changes in water supply and increased temperature. |
| [51] |
Eckardt NA. 2022. From the archives: Photosynthesis matters; PSII antenna size, photorespiration, and the evolution of C4 photosynthesis. |
| [52] |
Baker NR. 2008. Chlorophyll fluorescence: a probe of photosynthesis in vivo. |
| [53] |
Zait Y, Shemer OE, Cochavi A. 2024. Dynamic responses of chlorophyll fluorescence parameters to drought across diverse plant families. |
| [54] |
Zhao Y, Lin S, Qiu Z, Cao D, Wen J, et al. 2015. MicroRNA857 is involved in the regulation of secondary growth of vascular tissues in Arabidopsis. |