| [1] |
Wei WL, Zeng R, Gu CM, Qu Y, Huang LF. 2016. Angelica sinensis in China − a review of botanical profile, ethnopharmacology, phytochemistry and chemical analysis. |
| [2] |
Ma JP, Guo ZB, Jin L, Li YD. 2015. Phytochemical progress made in investigations of Angelica sinensis (Oliv.) Diels. |
| [3] |
Su KH, Su SY, Ko CY, Cheng YC, Huang SS, et al. 2021. Ethnopharmacological survey of traditional Chinese medicine pharmacy prescriptions for dysmenorrhea. |
| [4] |
Zhang HY, Bi WG, Yu Y, Liao WB. 2012. Angelica sinensis (Oliv.) Diels in China: distribution, cultivation, utilization and variation. |
| [5] |
Han X, Li M, Yuan Q, Lee S, Li C, et al. 2023. Advances in molecular biological research of Angelica sinensis. |
| [6] |
Liu X, Luo M, Li M, Wei J. 2022. Depicting precise temperature and duration of vernalization and inhibiting early bolting and flowering of Angelica sinensis by freezing storage. |
| [7] |
Zhao Y, Liu G, Yang F, Liang Y, Gao Q, et al. 2023. Multilayered regulation of secondary metabolism in medicinal plants. |
| [8] |
Xiao J, Sui X, Xu Z, Liang L, Tang W, et al. 2025. CaNAC76 enhances lignin content and cold resistance in pepper by regulating CaCAD1. |
| [9] |
Yuan DP, Yang S, Feng L, Chu J, Dong H, et al. 2023. Red-light receptor phytochrome B inhibits BZR1-NAC028-CAD8B signaling to negatively regulate rice resistance to sheath blight. |
| [10] |
Bang SW, Choi S, Jin X, Jung SE, Choi JW, et al. 2022. Transcriptional activation of rice CINNAMOYL-CoA REDUCTASE 10 by OsNAC5, contributes to drought tolerance by modulating lignin accumulation in roots. |
| [11] |
Qu W, Huang W, Chen C, Chen J, Zhao L, et al. 2024. AdNAC20 regulates lignin and coumarin biosynthesis in the roots of Angelica Dahurica var. formosana. |
| [12] |
Han K, Zhao Y, Sun Y, Li Y. 2023. NACs, generalist in plant life. |
| [13] |
Gao Q, Zhang J, Cao J, Xiang C, Yuan C, et al. 2024. MetaDb: a database for metabolites and their regulation in plants with an emphasis on medicinal plants. |
| [14] |
Xu P, Ma W, Feng H, Cai W. 2024. The NAC056 transcription factor confers freezing tolerance by positively regulating expression of CBFs and NIA1 in Arabidopsis. |
| [15] |
Han K, Zhao Y, Liu J, Tian Y, El-Kassaby YA, et al. 2024. Genome-wide investigation and analysis of NAC transcription factor family in Populus tomentosa and expression analysis under salt stress. |
| [16] |
Qiu S, Shao C, Xu R, Luo Y, Hu Q, et al. 2025. Identification of the NAC gene family in Camellia sinensis and expression analysis of CsNAC65 under shading treatment. |
| [17] |
Mao H, Li S, Chen B, Jian C, Mei F, et al. 2022. Variation in cis-regulation of a NAC transcription factor contributes to drought tolerance in wheat. |
| [18] |
Kim Y, Kim B, Kang J, Bae SI, Yoon H, et al. 2025. ONAC005 enhances salt stress tolerance by promoting suberin deposition in root endodermis. |
| [19] |
Zhang X, Huang Y, Shi Y, Wang X, Chen W, et al. 2025. PnNAC03 from Panax notoginseng functions in positively regulating saponins and lignin biosynthesis during cell wall formation. |
| [20] |
Dong J, Zhao X, Song X, Wang S, Zhao X, et al. 2024. Identification of Eleutherococcus senticosus NAC transcription factors and their mechanisms in mediating DNA methylation of EsFPS, EsSS, and EsSE promoters to regulate saponin synthesis. |
| [21] |
Jiang T, Zhang Y, Zuo G, Luo T, Wang H, et al. 2024. Transcription factor PgNAC72 activates DAMMARENEDIOL SYNTHASE expression to promote ginseng saponin biosynthesis. |
| [22] |
Han X, Li C, Sun S, Ji J, Nie B, et al. 2022. The chromosome-level genome of female ginseng (Angelica sinensis) provides insights into molecular mechanisms and evolution of coumarin biosynthesis. |
| [23] |
Chen C, Wu Y, Li J, Wang X, Zeng Z, et al. 2023. TBtools-II: a 'one for all, all for one' bioinformatics platform for biological big-data mining. |
| [24] |
Arshad KT, Li C, Li L, Wang J, Chen J, et al. 2025. Genome-wide identification and expression profiling of bHLH transcription factors associated with ferulic acid biosynthesis in Angelica sinensis. |
| [25] |
Zhang G, Jiao Y, Zhao Z, Chen Q, Wang Z, et al. 2024. Genome-wide and expression pattern analysis of the HIT4 gene family uncovers the involvement of GHHIT4_4 in response to Verticillium Wilt in Gossypium hirsutum. |
| [26] |
Zhao Y, Zhang G, Tang Q, Song W, Gao Q, et al. 2022. EbMYBP1, a R2R3-MYB transcription factor, promotes flavonoid biosynthesis in Erigeron breviscapus. |
| [27] |
Arshad KT, Xiang C, Yuan C, Li L, Wang J, et al. 2024. Elucidation of AsANS controlling pigment biosynthesis in Angelica sinensis through hormonal and transcriptomic analysis. |
| [28] |
Wang J, Zhou PH, Li CH, Liang YL, Liu GZ, et al. 2024. Progress on medicinal plant regeneration and the road ahead. |
| [29] |
Peng DQ, Luo MM, Guo XW, Li MF, Wei JH. 2024. Selection of reference genes for quantitative real-time PCR analysis in Angelica sinensis. Chinese Traditional and Herbal Drugs 55:269−278 |
| [30] |
Luan Y, Chen Z, Meng J, Tao J, Zhao D. 2023. PoWRKY17 promotes drought tolerance in Paeonia ostii by modulating lignin accumulation. |
| [31] |
Yuan C, Li L, Zhou P, Xiang C, Huang C, et al. 2025. Decoding the root lignification mechanism of Angelica sinensis through genome-wide DNA methylation analysis. |
| [32] |
Chen S, Zhou Y, Chen Y, Gu J. 2018. Fastp: an ultra-fast all-in-one FASTQ preprocessor. |
| [33] |
Kim D, Langmead B, Salzberg SL. 2015. HISAT: a fast spliced aligner with low memory requirements. |
| [34] |
Wang J, Li CH, Xiang CF, Zhou PH, Li LS, et al. 2024. Establishment and application of highly efficient regeneration, genetic transformation and genome editing system for cucurbitacins biosynthesis in Hemsleya chinensis. |
| [35] |
Zhang Q, Wang L, Wang Z, Zhang R, Liu P, et al. 2021. The regulation of cell wall lignification and lignin biosynthesis during pigmentation of winter jujube. |
| [36] |
Li M, Cheng C, Zhang X, Zhou S, Wang C, et al. 2019. PpNAC187 enhances lignin synthesis in 'Whangkeumbae' pear (Pyrus pyrifolia) 'Hard-End' fruit. |
| [37] |
Jung SE, Kim TH, Shim JS, Bang SW, Bin Yoon H, et al. 2022. Rice NAC17 transcription factor enhances drought tolerance by modulating lignin accumulation. |
| [38] |
Sun Y, Jiang C, Jiang R, Wang F, Zhang Z, et al. 2021. A novel NAC transcription factor from Eucalyptus, EgNAC141, positively regulates lignin biosynthesis and increases lignin deposition. |
| [39] |
Duan AQ, Tao JP, Jia LL, Tan GF, Liu JX, et al. 2020. AgNAC1, a celery transcription factor, related to regulation on lignin biosynthesis and salt tolerance. |
| [40] |
Nie G, Yang Z, He J, Liu A, Chen J, et al. 2021. Genome-wide investigation of the NAC transcription factor family in Miscanthus sinensis and expression analysis under various abiotic stresses. |
| [41] |
Ma M, Hao T, Ren X, Liu C, Gela A, et al. 2025. NAC family gene CmNAC34 positively regulates fruit ripening through interaction with CmNAC-NOR in Cucumis melo. |
| [42] |
Xu Y, Zou S, Zeng H, Wang W, Wang B, et al. 2022. A NAC transcription factor TuNAC69 contributes to ANK-NLR-WRKY NLR-mediated stripe rust resistance in the diploid wheat Triticum urartu. |
| [43] |
Li X, Wang N, She W, Guo Z, Pan H, et al. 2022. Identification and functional analysis of the CgNAC043 gene involved in lignin synthesis from Citrusgrandis 'San Hong'. |
| [44] |
Cheng C, Zhang C, Jin X, Wang T, Zhang Y, et al. 2025. Calcium disrupts CML38/WRKY46-NAC187-CCR cascade to inhibit the formation of lignin-related physiological disorders in pear fruit. |
| [45] |
Gong X, Qi K, Zhao L, Xie Z, Pan J, et al. 2024. PbAGL7–PbNAC47–PbMYB73 complex coordinately regulates PbC3H1 and PbHCT17 to promote the lignin biosynthesis in stone cells of pear fruit. |