| [1] |
Janusz G, Pawlik A, Świderska-Burek U, Polak J, Sulej J, et al. 2020. Laccase properties, physiological functions, and evolution. |
| [2] |
Dwivedi UN, Singh P, Pandey VP, Kumar A. 2011. Structure–function relationship among bacterial, fungal and plant laccases. |
| [3] |
Hoffmann N, Benske A, Betz H, Schuetz M, Samuels AL. 2020. Laccases and peroxidases co-localize in lignified secondary cell walls throughout stem development. |
| [4] |
Arregui L, Ayala M, Gómez-Gil X, Gutiérrez-Soto G, Hernández-Luna CE, et al. 2019. Laccases: structure, function, and potential application in water bioremediation. |
| [5] |
Upadhyay P, Shrivastava R, Agrawal PK. 2016. Bioprospecting and biotechnological applications of fungal laccase. |
| [6] |
Zhu C, Yin T, Chen Y, Wei S. 2025. Identifying and analyzing the laccase gene family in the genome of Populus davidiana × P. bolleana. Molecular Plant Breeding 1−14 (in Chinese) |
| [7] |
Barros J, Serk H, Granlund I, Pesquet E. 2015. The cell biology of lignification in higher plants. |
| [8] |
Niu Z, Li G, Hu H, Lv J, Zheng Q, et al. 2021. A gene that underwent adaptive evolution, LAC2 (LACCASE), in Populus euphratica improves drought tolerance by improving water transport capacity. |
| [9] |
Qin S, Fan C, Li X, Li Y, Hu J, et al. 2020. LACCASE14 is required for the deposition of guaiacyl lignin and affects cell wall digestibility in poplar. |
| [10] |
Berthet S, Demont-Caulet N, Pollet B, Bidzinski P, Cézard L, et al. 2011. Disruption of LACCASE4 and 17 results in tissue-specific alterations to lignification of Arabidopsis thaliana stems. |
| [11] |
Xu X, Zhou Y, Wang B, Ding L, Wang Y, et al. 2019. Genome-wide identification and characterization of laccase gene family in Citrus sinensis. |
| [12] |
Cheng X, Li G, Ma C, Abdullah M, Zhang J, et al. 2019. Comprehensive genome-wide analysis of the pear (Pyrus bretschneideri) laccase gene (PbLAC) family and functional identification of PbLAC1 involved in lignin biosynthesis. |
| [13] |
Balasubramanian VK, Rai KM, Thu SW, Hii MM, Mendu V. 2016. Genome-wide identification of multifunctional laccase gene family in cotton (Gossypium spp.); expression and biochemical analysis during fiber development. |
| [14] |
Ranocha P, Chabannes M, Chamayou S, Danoun S, Jauneau A, et al. 2002. Laccase down-regulation causes alterations in phenolic metabolism and cell wall structure in poplar. |
| [15] |
Liu Q, Luo L, Wang X, Shen Z, Zheng L. 2017. Comprehensive analysis of rice laccase gene (OsLAC) family and ectopic expression of OsLAC10 enhances tolerance to copper stress in Arabidopsis. |
| [16] |
Turlapati PV, Kim KW, Davin LB, Lewis NG. 2011. The laccase multigene family in Arabidopsis thaliana: towards addressing the mystery of their gene function(s). |
| [17] |
Zhao Q, Nakashima J, Chen F, Yin Y, Fu C, et al. 2013. LACCASE is necessary and nonredundant with PEROXIDASE for lignin polymerization during vascular development in Arabidopsis. |
| [18] |
Wang CY, Zhang S, Yu Y, Luo YC, Liu Q, et al. 2014. MiR397b regulates both lignin content and seed number in Arabidopsis via modulating a laccase involved in lignin biosynthesis. |
| [19] |
Le Bris P, Wang Y, Barbereau C, Antelme S, Cézard L, et al. 2019. Inactivation of LACCASE8 and LACCASE5 genes in Brachypodium distachyon leads to severe decrease in lignin content and high increase in saccharification yield without impacting plant integrity. |
| [20] |
Bryan AC, Jawdy S, Gunter L, Gjersing E, Sykes R, et al. 2016. Knockdown of a laccase in Populus deltoides confers altered cell wall chemistry and increased sugar release. |
| [21] |
Zhang Y, Wu L, Wang X, Chen B, Zhao J, et al. 2019. The cotton laccase gene GhLAC15 enhances Verticillium wilt resistance via an increase in defence-induced lignification and lignin components in the cell walls of plants. |
| [22] |
Xu X, Zhang Y, Liang M, Kong W, Liu J. 2022. The citrus laccase gene CsLAC18 contributes to cold tolerance. |
| [23] |
Liu M, Dong H, Wang M, Liu Q. 2020. Evolutionary divergence of function and expression of laccase genes in plants. |
| [24] |
Zhang H, He H, Song W, Zheng L. 2023. Pre-harvest UVB irradiation enhances the phenolic and flavonoid content, and antioxidant activity of green- and red-leaf lettuce cultivars. |
| [25] |
Gupta SK, Sharma M, Deeba F, Pandey V. 2017. Plant response: UV-B avoidance mechanisms. In UV‐B Radiation: from Environmental Stressor to Regulator of Plant Growth, eds. Singh VP, Singh S, Prasad SM, Parihar P. Chichester, UK: John Wiley & Sons Ltd. pp. 217−258 doi: 10.1002/9781119143611.ch12 |
| [26] |
Gao Y, Wei L, Jiang C, Shi S, Jiao J, et al. 2025. Physiological mechanisms of the enhanced UV-B radiation triggering plant-specific peroxidase-mediated antioxidant defences. |
| [27] |
Rozema J, van de Staaij J, Björn LO, Caldwell M. 1997. UV-B as an environmental factor in plant life: stress and regulation. |
| [28] |
Agati G, Azzarello E, Pollastri S, Tattini M. 2012. Flavonoids as antioxidants in plants: location and functional significance. |
| [29] |
Hideg É, Jansen MAK, Strid Å. 2013. UV-B exposure, ROS, and stress: inseparable companions or loosely linked associates? |
| [30] |
Sun Q, Zhou X, Yang L, Xu H, Zhou X. 2023. Integration of phosphoproteomics and transcriptome studies reveals ABA signaling pathways regulate UV-B tolerance in Rhododendron chrysanthum leaves. |
| [31] |
Müller R, Acosta-Motos JR, Großkinsky DK, Hernández JA, Lütken H, et al. 2019. UV-B exposure of black carrot (Daucus carota ssp. sativus var. atrorubens) plants promotes growth, accumulation of anthocyanin, and phenolic compounds. |
| [32] |
Chen T, Peng J, Qian, M, Shui X, Du J, et al. 2023. The effects of enhanced ultraviolet-B radiation on leaf photosynthesis and submicroscopic structures in Mangifera indica L. cv. 'Tainong No 1'. |
| [33] |
Wang Q, Li G, Zheng K, Zhu X, Ma J, et al. 2019. The soybean laccase gene family: evolution and possible roles in plant defense and stem strength selection. |
| [34] |
Tahir H, Sajjad M, Qian M, Ul Haq MZ, Tahir A, et al. 2024. Glutathione and ascorbic acid accumulation in mango pulp under enhanced UV-B based on transcriptome. |
| [35] |
Birchler JA, Yang H. 2022. The multiple fates of gene duplications: deletion, hypofunctionalization, subfunctionalization, neofunctionalization, dosage balance constraints, and neutral variation. |
| [36] |
Kong J, Xiong R, Qiu K, Lin X, Li D, et al. 2024. Genome-wide identification and characterization of the laccase gene family in Fragaria vesca and its potential roles in response to salt and drought stresses. |
| [37] |
Gong HL, Xing YJ, Ma JX, Cai X, Feng ZP. 2025. Identification of laccase (LAC) gene family in potato (Solanum tuberosum L.) and its expression analysis under salt stresses. |
| [38] |
Panchy N, Lehti-Shiu M, Shiu SH. 2016. Evolution of gene duplication in plants. |
| [39] |
Qiu KL, Wang YM, He JL, Yu H, Pan HF, et al. 2022. Identification of peach laccase family genes and functional analysis of PpLAC21. |
| [40] |
Yang Y, Liu YY. 2021. Identification and sequence analysis of the MdLAC gene family members in apple. |
| [41] |
Yao W, Liu MM, Cheng MC, Liu SC. 2024. Genome-wide identification and expression analysis of LAC gene family of Amaranthus tricolor L. |
| [42] |
Waadt R, Seller CA, Hsu PK, Takahashi Y, Munemasa S, et al. 2022. Plant hormone regulation of abiotic stress responses. |