PBZ/DPC处理对马尾松扦插生根及GAs代谢的影响

doi:10.11707/j.1001-7488.LYKX20230598

摘要/Abstract

摘要：

目的: 研究GAs生物合成抑制剂多效唑（PBZ）和缩节胺（DPC）处理下马尾松生根过程中内源性GAs代谢，为揭示生根活性GAs及其作用机理，提高马尾松无性育苗成效提供科学参考。方法: 以15年生以上桐棉松优良林分中优选的单株GLM-3为繁殖对象，利用微体连续嫁接技术获得复幼枝条为试验材料，分别进行200 mg·L^?1 NAA（对照）、200 mg·L^?1 NAA + 100 mg·L^?1 PBZ（PBZ）、200 mg·L^?1 NAA + 100 mg·L^?1 DPC（DPC）处理下的扦插繁殖，通过液相色谱串联质谱（LC-MS/MS）技术于扦插第0（生根初始期）、10（根发生期）、20（根发育期）、35天（根形成期）取样检测GAs变化特征；以200 mg·L^?1 NAA为对照，分析200 mg·L^?1 NAA + 100 mg·L^?1 GA₃（GA₃）、200 mg·L^?1 NAA + 100 mg·L^?1 GA₄（GA₄）处理下生根活性GAs对插穗生根能力及其内源性IAA水平、根茎解剖构造及木质素通路小分子的影响。结果: 1) PBZ、DPC均能改善马尾松生根能力，但两种GAs抑制剂处理下的生根时间、生根率不同，其中PBZ处理下的生根时间短，而DPC处理下的生根率较高，但根条数、成活率与对照均无显著差异（P>0.05），整体仍处于较低水平。扦插10天时，PBZ/DPC均降低了插穗中GA₃水平，而扦插20天时，PBZ处理下的GA₄水平明显升高。2) GA₃、GA₄对插穗生根具有抑制性，生根率、根条数、成活率均显著低于对照（P<0.05）。在GA₃处理下扦插10~35天时，内源性IAA含量低于对照，而在GA₄处理下扦插20~35天时，IAA水平与对照无显著差异（P>0.05）。GA₄处理导致扦插20~35天时，插穗根茎组织木栓化加剧、木栓质增多，木质素小分子咖啡醇水平下降，咖啡酸、阿魏酸水平上升。结论: 马尾松扦插过程中GAs抑制剂不同，促根效果及作用机制也不同。PBZ促根作用强于DPC，但生根稳定性较DPC差。PBZ/DPC均导致了不定根发生期对IAA水平具有抑制性的GA₃水平下降，但PBZ引起了不定根发育期能诱导细胞木栓化加剧的GA₄水平上升，揭示了GA₃、GA₄与马尾松不定根形成困难有关。

关键词: 马尾松, 不定根, 赤霉素, 木质化, 木栓化

Abstract:

Objective: Pinus massoniana is an important afforestation tree species in southern China. Asexual rapid propagation technology is one of the effective ways to solve the problem of high genetic differentiation and low stand productivity of forest trees. Adventitious root induction is the key technical bottleneck to cultivating asexual seedlings of P. massoniana. Endogenous gibberellins (GAs) have dual effects in the formation of adventitious roots of P. massoniana. High levels of GAs are not conducive to the rooting of P. massoniana. In this study, the metabolism of endogenous GAs in the rooting process of P. massoniana under the treatment of GAs biosynthesis inhibitors such as paclobutrazol (PBZ) and mepiquat chloride (DPC) was investigated, in order to reveal the rooting-active GAs and the mechanism, and to provide reference for improving the effectiveness of cultivating asexual seedlings of P. massoniana. Method: An elite tree, GLM-3, selected from over 15-year-old P. massoniana var. ‘Tongmiansong’ stand was used as the propagation object, and the rejuvenated branches obtained by micro-continuous grafting technology were used as the experimental materials. Cutting propagation under the conditions of 200 mg·L^?1 NAA (control), 200 mg·L^?1 NAA+100 mg·L^?1 PBZ (PBZ), and 200 mg·L^?1 NAA+100 mg·L^?1 DPC (DPC) treatment was carried out respectively. Liquid chromatography-tandem quadrupole mass spectrometry (LC-MS/MS) technology was used to detect the variation characteristics of GAs at 0 (rooting initial stage), 10 (root formation stage), 20 (root development stage) and 35 days (root formation stage). With 200 mg·L^?1 NAA as the control, the effects of rooting-active GAs in 200 mg·L^?1 NAA+100 mg·L^?1 GA₃ (GA₃) and 200 mg·L^?1 NAA+100 mg·L^?1 GA₄ (GA₄) on rooting ability, endogenous IAA level, rhizome anatomical structure and small molecules of lignin pathway were analyzed. Result: 1) Both PBZ and DPC were able to improve the rooting ability of P. massoniana, but the rooting time and rooting rate were different under the treatment of the two GAs inhibitors. Compared to the control, the rooting time under PBZ treatment was shorter, while the rooting rate under DPC treatment was higher, but there were not significant differences in root number and survival rate between the treatments and the control (P>0.05), with the overall at a low level. At 10 days of cutting, PBZ/DPC reduced the GA₃ level in the cuttings, while at 20 days of cutting, the GA₄ level under PBZ treatment was significantly increased. 2) GA₃ and GA₄ had inhibitory effect on rooting of cuttings, and the rooting rate, root number and survival rate were significantly lower than those of the control (P<0.05). The endogenous IAA content was lower than that of the control at 10–35 days under GA₃ treatment, but there was no significant difference in IAA content between the GA₄ treatment and the control at 20–35 days (P>0.05). Under GA₄ treatment, the suberization was aggravated, the suberin was increased, the level of small molecule caffeol in lignin was decreased, and the levels of caffeic acid and ferulic acid were both increased in the root and stem tissues of cuttings at 20–35 days of cutting. Conclusion: In the process of P. massoniana cutting, different inhibitors of GAs synthesis have different root-promoting effects and mechanisms. The root-inducing effect of PBZ is stronger than that of DPC, but the rooting stability is less than that of DPC. Both PBZ and DPC lead to a decrease in GA₃ level that inhibites IAA level during adventitious root formation. However PBZ causes an increase in GA₄ level that can induce increased cell suberization during adventitious root development. This study reveals that GA₃ and GA₄ are related to the difficulty of adventitious root formation in P. massoniana.

Key words: Pinus massoniana, adventitious root, gibberellin, lignification, suberization

中图分类号:

S718.43

王胤,姚瑞玲,肖玉菲. PBZ/DPC处理对马尾松扦插生根及GAs代谢的影响[J]. 林业科学, 2025, 61(3): 147-157.

Yin Wang,Ruiling Yao,Yufei Xiao. Effects of PBZ/DPC Treatment on Rooting and GAs Metabolism of Pinus massoniana Cuttings[J]. Scientia Silvae Sinicae, 2025, 61(3): 147-157.

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参考文献 0

	韩雪源, 茅林春. 木栓质组成成分、组织化学特性及其生物合成研究进展. 植物学报, 2017, 52 (3): 358- 374. doi: 10.11983/CBB16068
	Han X Y, Mao L C. Research progress on constituents, histochemical characteristics and biosynthesis of suberin. Chinese Bulletin of Botany, 2017, 52 (3): 358- 374. doi: 10.11983/CBB16068
	何波祥, 曾令海, 连辉明, 等. 高产脂马尾松扦插繁殖技术研究. 广东林业科技, 2004, (1): 16- 19.
	He B X, Zeng L H, Lian H M, et al. A study on the cutting propagation of high gum Masson pine. Guangdong Forestry Science and Technology, 2004, (1): 16- 19.
	季孔庶, 王章荣, 陈天华, 等. 马尾松扦插繁殖年龄效应及继代扦插复壮效果. 浙江林学院学报, 1999, 16 (4): 341- 345.
	Ji K S, Wang Z R, Chen T H, et al. Cyclophysis and effect of rejuvenation with continued cuttage in Pinus massoniana cutting propagation. Journal of Zhejiang Forestry College, 1999, 16 (4): 341- 345.
	林士杰, 王梓默, 朱红波, 等. 吲哚丁酸对紫椴嫩枝扦插生根及相关生理特性的影响. 森林工程, 2023, 39 (4): 68- 77. doi: 10.3969/j.issn.1006-8023.2023.04.008
	Lin S J, Wang Z M, Zhu H B, et al. Effects of IBA on rooting and physiological characteristics in softwood cutting of Tilia amurensis. Forest Engineering, 2023, 39 (4): 68- 77. doi: 10.3969/j.issn.1006-8023.2023.04.008
	刘　彬, 刘青华, 周志春, 等. 马尾松β-蒎烯合酶基因克隆以及对松材线虫侵染的响应. 林业科学研究, 2020, 33 (6): 1- 12.
	Liu B, Liu Q H, Zhou Z C, et al. Cloning of β-pinene synthase gene in Pinus massoniana and its response to pine wood nematode infection. Forest Research, 2020, 33 (6): 1- 12.
	王　丽. 2014. 赤霉素合成抑制剂调控棉花营养生长的分子机制研究. 北京: 中国农业大学.
	Wang L. 2014. Molecular mechanism of vegetative growth control by a gibberellin biosynthesis inhibitor DPC in cotton (Gossypium hirsutum L.). Beijing: China Agricultural University. ［in Chinese］
	王　荣. 2016. 苹果砧木茎源根系发生中次生代谢、内源激素和转录组差异分析. 泰安: 山东农业大学.
	Wang R. 2016. Secondary metabolism, endogenous hormone and transcriptome analysis of apple stock cutting root system. Taian: Shandong Agricultural University. ［in Chinese］
	王　胤, 姚瑞玲, 李慧娟, 等. 基于外植体生理复幼的马尾松茎段芽无菌离体培养. 植物生理学报, 2019, 55 (9): 1375- 1384.
	Wang Y, Yao R L, Li H J, et al. In vitro sterilized culture of nodal segments based on explants physiological rejuvenation in Pinus massoniana. Plant Physiology Journal, 2019, 55 (9): 1375- 1384.
	王　胤, 姚瑞玲. 继代培养中马尾松生根能力及其与内源激素含量的相关分析. 林业科学, 2020, 56 (8): 38- 46. doi: 10.11707/j.1001-7488.20200805
	Wang Y, Yao R L. Analysis for rooting capacity and the correlations between rooting capacity and endohormones levels during subculturing in Pinus massoniana. Scientia Silvae Sinicae, 2020, 56 (8): 38- 46. doi: 10.11707/j.1001-7488.20200805
	颜培栋, 李　鹏, 杨章旗, 等. 不同造林密度马尾松人工林分化特征及其对生产力的影响. 林业科学, 2023, 59 (10): 66- 75.
	Yan P D, Li P, Yang Z Q, et al. Differentiation characteristics and their effects on productivity with different planting densities of Pinus massoniana plantations. Scientia Silvae Sinicae, 2023, 59 (10): 66- 75.
	杨模华. 2012. 马尾松种质资源分子评价与体胚发育技术研究. 长沙: 中南林业科技大学.
	Yang M H. 2012. Genetic structure and associations of Masson pine (Pinus massoniana Lamb. ) germplasm using molecular markers and somatic embryogenesis with immature zygotic embryos. Changsha: Central South University of Forestry and Technology. ［in Chinese］
	杨章旗, 冯源恒, 谭健晖, 等. 广西马尾松高世代育种策略研究. 广西林业科学, 2018, 47 (3): 251- 256. doi: 10.3969/j.issn.1006-1126.2018.03.001
	Yang Z Q, Feng Y H, Tan J H, et al. Advanced generation breeding strategy of Pinus massoniana in Guangxi. Guangxi Forestry Science, 2018, 47 (3): 251- 256. doi: 10.3969/j.issn.1006-1126.2018.03.001
	姚瑞玲, 王　胤, 吴幼媚. 马尾松组培生根关键因子分析. 广西植物, 2016, 36 (11): 1288- 1294.
	Yao R L, Wang Y, Wu Y M. Key factors affecting rooting of Pinus massoniana by tissue culture. Guihaia, 2016, 36 (11): 1288- 1294.
	姚瑞玲, 王　胤. 2022. 一种提升高产脂马尾松优树继代芽生根稳定性的方法. 国家发明专利, ZL202010426414.6. 2022−11−15.
	Yao R L, Wang Y. 2022. A method to improve the rooting stability of subculture buds of high-yield resin Masson pine plus trees. National Patent, ZL202010426414.6. 2022−11−15. ［in Chinese］
	张　旭, 王小佳, 黎思辰, 等. 柑橘果实粒化过程中木质素生物合成与调控研究进展. 浙江农业学报, 2019, 31 (12): 2131- 2140. doi: 10.3969/j.issn.1004-1524.2019.12.22
	Zhang X, Wang X J, Li S C, et al. Research progress of lignin biosynthesis and regulation during granulation of citrus. Acta Agriculturae Zhejiangensis, 2019, 31 (12): 2131- 2140. doi: 10.3969/j.issn.1004-1524.2019.12.22
	郑　璐. 2019. 多效唑和烯效唑与植物赤霉素合成酶的分子反应机制. 杭州: 浙江工业大学.
	Zheng L. 2019. Molecular reaction mechanism of paclobutrazol and uniconazole with gibberellin synthetase in plant. Hangzhou: Zhejiang University of Technology. ［in Chinese］
	郑武林. 2014. 马尾松与落叶松高效离体再生体系建立. 南昌: 江西农业大学.
	Zheng W L. 2014. Establishment of highly efficient in vitro regeneration system of masson pine and larch. Nancang: Jiangxi Agricultural University. ［in Chinese］
	Abdel-Mohsen M A-A, Rashedy A A. Stock plant etiolation reduces rooting of sub-terminal olive cuttings by reducing total sugars, IAA, indole/phenol ratio, and IAA/GA ratio. Acta Physiologiae Plantarum, 2023, 45 (9): 104. doi: 10.1007/s11738-023-03582-z
	Alok K S, Manoj K S, Kureel R S, et al. Effects of IAA and GA₃ on in vitro root regeneration in potato variety Kufri chipsona-1 and Kufri mohan. Biotech Today: an International Journal of Biological Sciences, 2017, 7 (2): 49- 51. doi: 10.5958/2322-0996.2017.00021.7
	Arpin R, LoBuono C, Rego M, et al. Thionin stain replacement of toluidine blue stain for cytological specimen triage improves safety during the COVID-19 pandemic. Journal of the American Society of Cytopathology, 2021, 10 (5): S73.
	Camara M C, Vandenberghe L P S, Rodrigues C, et al. Current advances in gibberellic acid (GA₃) production, patented technologies and potential applications. Planta, 2018, 248 (5): 1049- 1062. doi: 10.1007/s00425-018-2959-x
	Cesarino I. With a little help from MYB friends: transcriptional network controlling root suberization and lignification. Plant Physiology, 2022, 190 (2): 1077- 1079. doi: 10.1093/plphys/kiac318
	Gargul J M, Mibus H, Serek M. Characterization of transgenic Kalanchoë and Petunia with organ-specific expression of GUS or GA₂ox genes led by the deletion BOX-I version (dBI) of the PAL1 promoter. Journal of Plant Growth Regulation, 2017, 36 (2): 424- 435. doi: 10.1007/s00344-016-9650-x
	Han H, Dye L, Mackie A. The impact of processing on the release and antioxidant capacity of ferulic acid from wheat: a systematic review. Food Research International, 2023, 164, 112371. doi: 10.1016/j.foodres.2022.112371
	Mauriat M, Petterle A, Bellini C, et al. Gibberellins inhibit adventitious rooting in hybrid aspen and Arabidopsis by affecting auxin transport. Plant Journal, 2014, 78 (3): 372- 384. doi: 10.1111/tpj.12478
	Mignolli F, Vidoz M L, Picciarelli P, et al. Gibberellins modulate auxin responses during tomato (Solanum lycopersicum L.) fruit development. Physiologia Plantarum, 2018, 165 (4): 768- 779.
	Pan T, Chen X L, Hao Y P, et al. Optimization of factors affecting the rooting of pine wilt disease resistant Masson pine (Pinus massoniana) stem cuttings. PLoS One, 2021, 16 (9): e0251937. doi: 10.1371/journal.pone.0251937
	Saini S, Sharma I, Kaur N, et al. Auxin: a master regulator in plant root development. Plant Cell Reports, 2013, 32 (6): 741- 757. doi: 10.1007/s00299-013-1430-5
	Su Y C, Li Y P, Tan C S, et al. Rapid identification of flaxseed oil based on portable fiber optic Raman spectroscopy combined with an oil microscopy method. Journal of Food Science, 2022, 87 (8): 3407- 3418. doi: 10.1111/1750-3841.16234
	Wang Y, Yao R L. Plantlet regeneration of adult Pinus massoniana Lamb. trees using explants collected in March and thidiazuron in culture medium. Journal of Forestry Research, 2017, 28 (6): 1169- 1175. doi: 10.1007/s11676-017-0412-9
	Wang Y, Yao R L. Indole-3-acetic acid accelerates root system development in tissue culture of mature Pinus massoniana Lamb. trees. Propagation of Ornamental Plants, 2019, 19 (3): 85- 92.
	Wang Y, Yao R L. Increased endogenous gibberellin level inhibits root growth of Pinus massoniana Lamb. plantlets during long-term subculture. In Vitro Cellular & Developmental Biology-Plant, 2020, 56 (4): 470- 479.
	Yang F, Fan Y F, Wu X L, et al. Auxin-to-gibberellin ratio as a signal for light intensity and quality in regulating soybean growth and matter partitioning. Frontiers in Plant Science, 2018, 9, 56. doi: 10.3389/fpls.2018.00056
	Yao R L, Fang S Z, Shang X L, et al. Cytochemical localization of ATPase and sub-cellular variation in mesophyll cell of Cyclocarya paliurus seedlings under iso-osmotic stress and calcium regulation. Journal of Forestry Research, 2009, 20 (4): 343- 348. doi: 10.1007/s11676-009-0058-3
	Zheng L L, She M H, Ai B L, et al. Construction and properties of an amyloid fiber ferulic acid chitosan double network hydrogel and its inhibition of AGEs activity. Food Hydrocolloids, 2023, 139, 8536.
	Zhu W H, Qi J G, Chen J D, et al. Identification of GA₂ox family genes and expression analysis under gibberellin treatment in pineapple (Ananas comosus (L.) Merr.). Plants, 2023, 12 (14): 2673. doi: 10.3390/plants12142673

生根剂 Rooting agent	生根时间 Rooting time/d	生根率 Rooting rate (%)	根条数 Root number per plant	成活率 Survival percentage (%)
NAA	45.2±1.5a	58.6±3.3c	1.9±0.4a	52.3±3.6a
NAA+PBZ	30.5±2.3c	79.5±2.8b	2.0±0.5a	56.3±4.1a
NAA+DPC	37.2±3.5b	85.4±2.7a	2.2±0.7a	54.8±2.8a

生根剂 Rooting agent	生根时间 Rooting time/d	生根率 Rooting rate (%)	根条数 Root number per plant	成活率 Survival percentage (%)
C	45.9±2.7a	53.2±3.4a	2.2±0.4a	56.4±3.8a
G3	45.7±3.1a	11.3±3.0c	1.4±0.4b	38.8±2.8b
G4	47.2±1.7a	16.4±2.4b	1.1±0.2b	22.3±2.1c

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