独脚金内酯类似物及其荧光探针的研究进展

doi:10.3969/j.issn.1009-7791.2026.01.014

亚热带植物科学 ›› 2026, Vol. 55 ›› Issue (1): 120-130.DOI: 10.3969/j.issn.1009-7791.2026.01.014

独脚金内酯类似物及其荧光探针的研究进展

雷杰¹, 梁绮雯¹, 张雪芹³, 邓志伟², 周述波², 马立英^2*, 萧浪涛^1*

(1. 湖南农业大学植物激素与生长发育湖南省重点实验室，湖南长沙 410128；2. 海南热带海洋学院民族学院，海南三亚 572022；3. 福建省亚热带植物研究所 / 福建省亚热带植物生理生化重点公共实验室，福建厦门 361006)

收稿日期:2025-11-27 接受日期:2026-01-12 出版日期:2026-02-28 发布日期:2026-02-28
通讯作者: 马立英；萧浪涛
基金资助:
国家自然科学基金(32261143733、32560518)；海南热带海洋学院人才科研启动项目(RHDRCZK202527)

Research Progress on Strigolactone Analogues and Its Fluorescent Probes

LEI Jie¹, LIANG Qi-wen¹, ZHANG Xue-qing³, DENG Zhi-wei², ZHOU Shu-bo², MA Li-ying^2*, XIAO Lang-tao^1*

(1. Hunan Provincial Key Laboratory of Phytohormones and Growth Development, Hunan Agricultural University, Changsha 410128, Hunan China; 2. Minzu College, Hainan Tropical Ocean University, Sanya 572022, Hainan China; 3. Fujian Institute of Subtropical Botany / Fujian Key Laboratory of Physiology and Biochemistry for Subtropical Plant, Xiamen 361006, Fujian China)

Received:2025-11-27 Accepted:2026-01-12 Online:2026-02-28 Published:2026-02-28
Contact: MA Li-ying; XIAO Lang-tao

摘要/Abstract

摘要： 独脚金内酯（strigolactone，SLs）作为一类由类胡萝卜素衍生的植物激素，在调控植物生长发育、形态建成及逆境响应等生理过程中发挥重要作用。在塑造作物株型、杀灭寄生杂草和促进微生物有益共生等方面显示出巨大的应用潜力。开发结构稳定、价格低廉、活性增强的SLs类似物具有重要的理论和应用价值。本文系统综述了独脚金内酯的生物学功能及其分子机制，重点探讨了结构修饰对其生物活性的影响，并详尽介绍了荧光探针技术在独脚金内酯信号转导研究中的应用进展，但目前从基础结合研究迈向活体、多组分、实时动态成像，以及开发高通量筛选专用探针工具仍面临核心挑战。本文为深入解析独脚金内酯的作用机制及开发新型植物生长调节剂提供理论依据和研究思路。

关键词: 植物激素, 独脚金内酯, 结构类似物, 荧光探针, 植物生长调节剂

Abstract: Strigolactones (SLs), a novel class of carotenoid-derived phytohormones, play crucial roles in regulating various physiological processes including plant growth, development, morphogenesis, and stress responses. It demonstrates great application potential in shaping crop architecture, eliminating parasitic weeds, and promoting beneficial microbial symbiosis. Developing SLs analogs with stable structures, low costs, and enhanced activity holds significant theoretical and practical value. This review systematically summarizes the biological functions and molecular mechanisms of SLs, with particular emphasis on how structural modifications influence their bioactivity. Furthermore, it provides a comprehensive overview of recent advances in fluorescent probe technology for studying strigolactone signaling pathways. There are still core challenges in moving from basic combination studies to in vivo, multi-component, real-time dynamic imaging, and in developing dedicated probe tools for high-throughput screening. This paper provides a theoretical basis and research ideas for a deeper understanding of the mechanism of action of strigolactones and for the development of new plant growth regulators.

Key words: phytohormone, strigolactone, structural analog, fluorescent probe, plant growth regulators

中图分类号:

Q945

雷杰, 梁绮雯, 张雪芹, 邓志伟, 周述波, 马立英, 萧浪涛. 独脚金内酯类似物及其荧光探针的研究进展[J]. 亚热带植物科学, 2026, 55(1): 120-130.

LEI Jie, LIANG Qi-wen, ZHANG Xue-qing, DENG Zhi-wei, ZHOU Shu-bo, MA Li-ying, XIAO Lang-tao. Research Progress on Strigolactone Analogues and Its Fluorescent Probes[J]. Subtropical Plant Science, 2026, 55(1): 120-130.

参考文献

[1] Cook C E, Whichard L P, Turner B, Wall M E, Egley G H. Germination of witchweed (Striga lutea Lour.): Isolation and properties of a potent stimulant [J]. Science, 1966, 154(3753): 1189–1190.

[2] Kretzschmar T, Kohlen W, Sasse J, Borghi L, Schlegel M, Bachelier J B, Reinhardt D, Bours R, Bouwmeester H J, Martinoia E. A petunia ABC protein controls strigolactone- dependent symbiotic signalling and branching [J]. Nature, 2012, 483(7389): 341–344.

[3] Akiyama K, Matsuzaki K, Hayashi H. Plant sesquiterpenes induce hyphal branching in arbuscular mycorrhizal fungi [J]. Nature, 2005, 435(7043): 824–827.

[4] Arellano-Saab A, Skarina T, Xu Z, McErlean C S P, Savchenko A, Lumba S, Stogios P J, McCourt P. Structural analysis of a hormone-bound Striga strigolactone receptor [J]. Nature Plants, 2023, 9(6): 883–888.

[5] Gomez-Roldan V, Fermas S, Brewer P B, Puech-Pagès V, Dun E A, Pillot J P, Letisse F, Matusova R, Danoun S, Portais J C, Bouwmeester H, Bécard G, Beveridge C A, Rameau C, Rochange S F. Strigolactone inhibition of shoot branching [J]. Nature, 2008 ,455(7210): 189–194.

[6] Umehara M, Hanada A, Yoshida S, Akiyama K, Arite T, Takeda-Kamiya N, Magome H, Kamiya Y, Shirasu K, Yoneyama K, Kyozuka J, Yamaguchi S. Inhibition of shoot branching by new terpenoid plant hormones [J]. Nature, 2008, 455(7210): 195–200.

[7] Das D, Varshney K, Ogawa S, Torabi S, Hüttl R, Nelson D C, Gutjahr C. Ethylene promotes SMAX1 accumulation to inhibit arbuscular mycorrhiza symbiosis [J]. Nature Communications, 2025, 16(1): 2025.

[8] Ou H, Xie D, Yao R, Shan X. Strigolactones: Biosynthesis, transport, perception, and signal transduction [J]. Molecular Plant, 2026, 19(3): 515–537.

[9] Lyu J. Striga resistance: Cloak the strigolactone [J]. Nature Plants, 2017, 3(5): 17068.

[10] Vurro M, Yoneyama K. Strigolactones––intriguing biologically active compounds: Perspectives for deciphering their biological role and for proposing practical application [J]. Pest Management Science, 2012, 68(5): 664–668.

[11] Xie X N, Yoneyama K, Kisugi T, Uchida K, Ito S, Akiyama K, Hayashi H, Yokota T, Nomura T, Yoneyama K. Confirming stereochemical structures of strigolactones produced by rice and tobacco [J]. Molecular Plant, 2013, 6: 153–163.

[12] Chesterfield R J, Vickers C E, Beveridge C A. Translation of strigolactones from plant hormone to agriculture: Achievements, future perspectives, and challenges [J]. Trends in Plant Science, 2020, 25(11): 1087–1106.

[13] Yao R F, Ming Z H, Yan L M, Li S H, Wang F, Ma S, Yu C T, Yang M, Chen L, Chen L H, Li Y W, Yan C, Miao D, Sun Z Y, Yan J B, Sun Y N, Wang L, Chu J F, Fan S L, He W, Deng H T, Nan F J, Li J Y, Rao Z H, Lou Z Y, Xie D X. DWARF14 is a non-canonical hormone receptor for strigolactone [J]. Nature, 2016, 536: 469–473.

[14] Alashoor K F, Wang J Y, Al-Babili S. The role of hydrolysis in perceiving and degrading the plant hormone strigolactones [J]. Trends in Biochemical Sciences, 2024, 49(12): 1039–1041.

[15] 田慧源, 唐博希, 王原秀, 刘帆, 郭凯阳, 刘国琴. 外源独脚金内酯对烟草腋芽伸长及独脚金内酯代谢途径相关基因表达的影响[J]. 亚热带植物科学, 2023, 52(5): 369–380.

[16] Wang L, Wang B, Yu H, Guo H, Lin T, Kou L, Wang A, Shao N, Ma H, Xiong G, Li X, Yang J, Chu J, Li J. Transcriptional regulation of strigolactone signalling in Arabidopsis [J]. Nature, 2020, 583(7815): 277–281.

[17] Hu J, Ji Y, Hu X, Sun S, Wang X. BES1 Functions as the co-regulator of D53-like SMXLs to inhibit BRC1 expression in strigolactone-regulated shoot branching in Arabidopsis [J]. Plant Communications, 2020, 1(3): 100014.

[18] Toh S, Holbrook-Smith D, Stogios P J, Onopriyenko O, Lumba S, Tsuchiya Y, Savchenko A, McCourt P. Structure-function analysis identifies highly sensitive strigolactone receptors in Striga [J]. Science, 2015, 350(6257): 203–207.

[19] Zwanenburg B, Pospisil T, Zeljkovic S C. Strigolactones: New plant hormones in action [J]. Planta, 2016, 243: 1311–1326.

[20] Zwanenburg B, Pospísil T. Structure and activity of strigolactones: New plant hormones with a rich future [J]. Molecular Plant, 2013, 6(1): 38–62.

[21] Yoneyama K, Xie X N, Sekimoto H, Takeuchi Y, Ogasawara S, Akiyama K, Hayashi H, Yoneyama K. Strigolactones, host recognition signals for root parasitic plants and arbuscular mycorrhizal fungi, from Fabaceae plants [J]. New Phytologist, 2008, 179: 484–494.

[22] Uraguchi D, Kuwata K, Hijikata Y, Yamaguchi R, Imaizumi H, AM S, Rakers C, Mori N, Akiyama K, Irle S, McCourt P, Kinoshita T, Ooi T, Tsuchiya Y. A femtomolar-range suicide germination stimulant for the parasitic plant Striga hermonthica [J]. Science, 2018, 362(6420): 1301–1305.

[23] Bebbington M W P. Natural product analogues: towards a blueprint for analogue-focused synthesis [J]. Chemical Society Reviews, 2017, 46(16): 5059–5109.

[24] Wang W, Shi J, Xie Q, Jiang Y, Yu N, Wang E. Nutrient exchange and regulation in arbuscular mycorrhizal symbiosis [J]. Molecular Plant, 2017, 10(9): 1147–1158.

[25] Akiyama K, Ogasawara S, Ito S, Hayashi H. Structural requirements of strigolactones for hyphal branching in AM fungi [J]. Plant Cell Physiol, 2010, 51(7):1104–1117.

[26] 纠松涛, 徐岩, 张才喜, 王磊, 马超, 许文平, 王世平. 独脚金内酯及其调控植物根系生长发育的研究进展[J]. 分子植物育种, 2021, 19(15): 5164–5171.

[27] Kapulnik Y, Koltai H. Strigolactone involvement in root development, response to abiotic stress, and interactions with the biotic soil environment [J]. Plant Physiology, 2014, 166(2): 560–569.

[28] Kodama K, Rich M K, Yoda A, Shimazaki S, Xie X, Akiyama K, Mizuno Y, Komatsu A, Luo Y, Suzuki H, Kameoka H, Libourel C, Keller J, Sakakibara K, Nishiyama T, Nakagawa T, Mashiguchi K, Uchida K, Yoneyama K, Tanaka Y, Yamaguchi S, Shimamura M, Delaux P M, Nomura T, Kyozuka J. An ancestral function of strigolactones as symbiotic rhizosphere signals [J]. Nature Communications, 2022, 13(1): 3974.

[29] Banasiak J, Borghi L, Stec N, Martinoia E, Jasiński M. The full size ABCG transporter of Medicago truncatula is involved instrigolactone secretion, affecting arbuscular mycorrhiza [J]. Frontiers in Plant Science, 2020, 11: 1–14.

[30] Gomez-Roldan V, Fermas S, Brewer P B, Puech-Pagès V, Dun E A, Pillot J P, Letisse F, Matusova R, Danoun S, Portais J C, Bouwmeester H, Bécard G, Beveridge C A, Rameau C, Rochange S F. Strigolactone inhibition of shoot branching [J]. Nature, 2008, 455(7210): 189–194.

[31] Prandi C, Ghigo G, Ernesto G O, Scarpi D, Begliomini S, Lace B, Alberto G, Artuso E, Blangetti M. Tailoring fluorescent strigolactones for in vivo investigations: a computational and experimental study [J]. Organic & Biomolecular Chemistry, 2014, 12: 2960–2968.

[32] Prandi C, Rosso H, Lace B, Occhiato E G, Oppedisano A, Tabasso S, Alberto G, Blangetti M. Strigolactone analogs as molecular probes in chasing the (SLs) receptor/s: Design and synthesis of fluorescent labeled molecules [J]. Molecular Plant, 2013, 6: 113–127.

[33] 王雪菱, 王如月, 李际红,王锦楠, 王冬月, 牛牧歌, 孙茂桐. 独脚金内酯抑制因子D53/SMXLs基因的研究进展[J]. 农学学报, 2023, 13(10): 37–43.

[34] 姚瑞枫, 谢道昕. 水稻独脚金内酯信号感知的激活和终止[J]. 植物学报, 2024, 59(6): 873–877.

[35] Marzec M, Brewer P B. Culture tames the unruly strigolactones [J]. Trends in Plant Science, 2025, 30(10): 1072–1074.

[36] Jiang L, Liu X, Xiong G, Liu H, Chen F, Wang L, Meng X, Liu G, Yu H, Yuan Y, Yi W, Zhao L, Ma H, He Y, Wu Z, Melcher K, Qian Q, Xu H E, Wang Y, Li J. DWARF 53 acts as a repressor of strigolactone signalling in rice [J]. Nature, 2013, 504(7480): 401–405.

[37] Shabek N, Ticchiarelli F, Mao H, Hinds T R, Leyser O, Zheng N. Structural plasticity of D3-D14 ubiquitin ligase in strigolactone signaling [J]. Nature, 2018, 563(7733): 652–656.

[38] Seale M, Bennett T, Leyser O. BRC1 expression regulates bud activation potential but is not necessary or sufficient for bud growth inhibition in Arabidopsis [J]. Development, 2017, 144: 1661–1673.

[39] Liang Y Y, Ward S, Li P, Bennett T, Leyser O. SMAX1-LIKE7 signals from the nucleus to regulate shoot development in Arabidopsis via partially EAR motif-independent mechanisms [J]. Plant Cell, 2016, 28(7): 1581–1601.

[40] van Rongen M, Bennett T, Ticchiarelli F, Leyser O. Connective auxin transport contributes to strigolactone-mediated shoot branching control independent of the transcription factor BRC1 [J]. PLoS Genetics, 2019, 15: e1008023.

[41] Zhang J, Mazur E, Balla J, Gallei M, Kalousek P, Medveďová Z, Li Y, Wang Y, Prát T, Vasileva M, Reinöhl V, Procházka S, Halouzka R, Tarkowski P, Luschnig C, Brewer P B, Friml J. Strigolactones inhibit auxin feedback on PIN-dependent auxin transport canalization [J]. Nature Communications, 2020, 11(1): 3508.

[42] Ning Y, Dijkstra F A, Liang X S, Zhang X J, Yang G J, Jiang L C, Han X G, Lü X T. Stronger response of plant N: P to nitrogen enrichment when considering roots [J]. Global Change Biology, 2025, 31(2): e70091.

[43] 洪林, 杨蕾, 杨海健, 王武, 谭平. 独脚金内酯调控植物非生物胁迫响应的研究进展[J]. 植物生理学报, 2020, 56(6): 1097–1108.

[44] Zhang Y, Feng H, Druzhinina I S, Xie X, Wang E, Martin F, Yuan Z. Phosphorus/nitrogen sensing and signaling in diverse root-fungus symbioses [J]. Trends in Microbiology, 2024, 32(2): 200–215.

[45] 刘斌, 倪中福. 低磷信号调控独脚金内酯合成与水稻株型的核心机制[J]. 科学通报, 2024, 69(2): 143–145.

[46] Yoneyama K. How do strigolactones ameliorate nutrient deficiencies in plants? [J]. Cold Spring Harbor Perspectives in Biology, 2019, 11(8): a034686.

[47] Oldroyd G E D, Leyser O. A plant’s diet, surviving in a variable nutrient environment [J]. Science, 2020. DOI: 10.1126/science.aba0196.

[48] Li L, Ge S, He L, Liu R, Mei Y, Xia X, Yu J, Zhou Y. SlDELLA interacts with SlPIF4 to regulate arbuscular mycorrhizal symbiosis and phosphate uptake in tomato [J]. Horticulture Research, 2024, 11(9):195.

[49] Han Y, Feng J, Han M, Zhu B. Responses of arbuscular mycorrhizal fungi to nitrogen addition: A meta-analysis [J]. Global Change Biology, 2020, 26(12): 7229–7241.

[50] Hines P J. A step toward control of a noxious weed [J]. Science, 2018, 362(6420): 1259–1260.

[51] Rasmussen A, Heugebaert T, Matthys C, Deun R V, Boyer F D, Goormachtig S, Stevens C, Geelen D. A fluorescent alternative to the synthetic strigolactone GR24 [J]. Molecular Plant, 2013, 6(1): 100–112.

[52] Boyer F D, Germain A de S, Pouvreau J B, Clavé G, Pillot J P, Roux A, Rasmussen A, Depuydt S, Lauressergues D, Frey N F dit, Heugebaert T S A, Stevens C V, Geelen D, Goormachtig S, Rameau C. New strigolactone analogs as plant hormones with low activities in the rhizosphere [J]. Molecular Plant, 2014, 7(4): 675–690.

[53] Waters M T, Gutjahr C, Bennett T, Nelson D C. Strigolactone signaling and evolution [J]. Annual Review of Plant Biology, 2017, 68: 291–322.

[54] 李敏, 周思梅, 冯艳, 李梓璇, 王大伟. 独脚金内酯激动剂和拮抗剂的研究进展[J]. 现代农药, 2025, 24(2): 18–27+33.

[55] Samejima H, Babiker A G, Takikawa H, Sasaki M, Sugimoto Y. Practicality of the suicidal germination approach for controlling Striga hermonthica [J]. Pest Management Science, 2016, 72(11): 2035–2042.

[56] Bao X, Rodriguez J, Bonne D. Enantioselective synthesis of atropisomers with multiple stereogenic axes [J]. Angewandte Chemie International Edition, 2020, 59(31): 12623–12634.

[57] Zwanenburg B, Ćavar Zeljković S, Pospíšil T. Synthesis of strigolactones, a strategic account [J]. Pest Management Science, 2016, 72(1): 15–29.

[58] Scaffidi A, Waters M T, Sun Y K, Skelton B W, Dixon K W, Ghisalberti E L, Flematti G R, Smith S M. Strigolactone hormones and their stereoisomers signal through two related receptor proteins to induce different physiological responses in Arabidopsis [J]. Plant Physiology, 2014, 165(3): 1221–1232.

[59] 康兆勇, 董小绮, 刘胜男, 高清志. 独脚金内酯及其新型衍生物[J]. 化学进展, 2023, 35(9): 1341–1356.

[60] Boyer F D, de Saint Germain A, Pillot J P, Pouvreau J B, Chen V X, Ramos S, Stévenin A, Simier P, Delavault P, Beau J M, Rameau C. Structure-activity relationship studies of strigolactone- related molecules for branching inhibition in garden pea: molecule design for shoot branching [J]. Plant Physiology. 2012, 159(4): 1524–1544.

[61] Johnson A W, Gowda G, Hassanali A, Knox J, Monaco S, Razavi Z, Rosebery G. The preparation of synthetic analogues of strigolactone [J]. Journal of the Chemical Society, Perkin Transactions 1, 1981, 10: 1734–1743.

[62] Nakamura H, Hirabayashi K, Miyakawa T, Kikuzato K, Hu W, Xu Y, Jiang K, Takahashi I, Niiyama R, Dohmae N, Tanokura M, Asami T. Triazole ureas covalently bind to strigolactone receptor and antagonize strigolactone responses [J]. Molecular Plant, 2019, 12(1): 44–58.

[63] Kushihara R, Nakamura A, Takegami K, Seto Y, Kato Y, Dohra H, Ohnishi T, Todoroki Y, Takeuchi J. Structural requirements of KAI2 ligands for activation of signal transduction [J]. Proceedings of the National Academy of Sciences of the United States of America, 2025, 122(8): e2414779122.

[64] Wang J, Takahashi I, Kikuzato K, Sakai T, Zhu Z, Jiang K, Nakamura H, Nakano T, Tanokura M, Miyakawa T, Asami T. Identification and structure-guided development of triazole urea-based selective antagonists of Arabidopsis karrikin signaling [J]. Nature Communications, 2025, 16(1): 104.

[65] Jamil M, Mutinda S, Wang J Y, Barminga D, Mwihaki A, Navangi L, Okiyo T O, Patil R H, Ngatia T, Mudavadi P, Runo S, Al-Babili S. Evaluation of formulated strigolactone analogs for Striga management in Kenyan agriculture [J]. Journal of Agriculture and Food Research, 2025, 21: 101921.

[66] Zwanenburg B, Mwakaboko A S, Reizelman A, Anilkumar G, Sethumadhavan D. Structure and function of natural and synthetic signalling molecules in parasitic weed germination [J]. Pest Management Science, 2009, 65: 478–491.

[67] Mishiro K, Sesumi A, Fujii T, Furuyama T, Kunishima M. Phototriggered butenolide formation from a cyclobutenedione and an acidic nucleophile [J]. Organic Letters, 2023, 26(1): 380–384.

[68] Zwanenburg B, Ćavar Zeljković S, Pospíšil T. Synthesis of strigolactones, a strategic account [J]. Pest Managment Science. 2016, 72(1): 15–29.

[69] Kawada K, Takahashi I, Takei S, Nomura A, Seto Y, Fukui K, Asami T. The evaluation of debranone series strigolactone agonists for germination stimulants in Orobanche species [J]. Journal of Agricultural and Food Chemistry, 2024, 72(35): 19517–19525.

[70] Fukui K, Ito S, Asami T. Selective mimics of strigolactone actions and their potential use for controlling damage caused by root parasitic weeds [J]. Molecular Plant, 2013, 6(1): 88–99.

[71] Fukui K, Ito S, Ueno K, Yamaguchi S, Kyozuka J, Asami T. New branching inhibitors and their potential as strigolactone mimics in rice [J]. Bioorganic & Medicinal Chemistry Letters, 2011, 15: 21(16): 4905–4908.

[72] Roy R N. Bioactive natural derivatives of phthalate ester [J]. Critical Reviews in Biotechnology, 2020, 40(7): 913–929.

[73] Hamiaux C, Drummond R S M, Luo Z, Lee H W, Sharma P, Janssen B J, Perry N B, Denny W A, Snowden K C. Inhibition of strigolactone receptors by N-phenylanthranilic acid derivatives: Structural and functional insights [J]. Journal of Biological Chemistry, 2018, 293(17): 6530–6543.

[74] Takeuchi J, Jiang K, Hirabayashi K, Imamura Y, Wu Y, Xu Y, Miyakawa T, Nakamura H, Tanokura M, Asami T. Rationally designed strigolactone analogs as antagonists of the D14 receptor [J]. Plant and Cell Physiology, 2018, 59(8): 1545–1554.

[75] Du L, Li X, Ding Y, Ma D, Yu C, Duan L. Design, synthesis, and bioactivities of N-heterocyclic ureas as strigolactone response antagonists against parasitic-weed seed germination [J]. Journal of Agricultural and Food Chemistry, 2024. DOI: 10.1021/acs.jafc.3c08174.

[76] Germain A de S, Clavé G, Schouveiler P, Pillot J P, Singh A V, Chevalier A, Fornier S D, Guillory A, Bonhomme S, Rameau C, Boyer F D. Expansion of the strigolactone profluorescent probes repertory: The right probe for the right application [J]. Frontiers in Plant Science, 2022, 13: 887347.

[77] Tsuchiya Y, Yoshimura M, Sato Y, Kuwata K, Toh S, Holbrook–Smith D, Zhang H, McCourt P, Itami K, Kinoshita T, Hagihara S. Probing strigolactone receptors in Striga hermonthica with fluorescence [J]. Science, 2015, 349(6250): 864–868.

[78] Heugebaert T S A, Stevens C V. Gold (III) chloride catalyzed synthesis of 1-cyanoisoindoles [J]. Organic Letters, 2009, 11(21): 5018–5021.

[79] Zhao J, Li Y, Ma J, Liu J, Xiao R, Wang L, Li P, He Y, Qian F, Zhang A, Sun Z L, Ding C. Synthesis and pharmacological validation of fluorescent diarylsulfonylurea analogues as NLRP3 inhibitors and imaging probes [J]. European Journal of Medicinal Chemistry, 2022, 237: 114338.

[80] Prandi C, Occhiato E G, Tabasso S, Bonfante P, Novero M, Scarpi D, Bova M E, Miletto I. New potent fluorescent analogues of strigolactones: Synthesis and biological activity in parasitic weed germination and fungal branching [J]. European Journal of Organic Chemistry, 2011(20-21): 3781–3793.

[81] Prandi C, Rosso H, Lace B, Occhiato E G, Oppedisano A, Tabasso S, Alberto G, Blangetti M. Strigolactone analogs as molecular probes in chasing the (SLs) receptor/s: design and synthesis of fluorescent labeled molecules [J]. Molecular Plant, 2013, 6(1): 113–127.

[82] Lace B, Prandi C. Shaping small bioactive molecules to untangle their biological function: A focus on fluorescent plant hormones [J]. Molecular Plant, 2016, 9(8): 1099–1118.

[83] Fridlender M, Lace B, Wininger S, Dam A, Kumari P, Belausov E, Tsemach H, Kapulnik Y, Prandi C, Koltai H. Influx and efflux of strigolactones are actively regulated and involve the cell-trafficking system [J]. Molecular Plant, 2015, 8(12): 1809–1812.

[84] Chesterfield R J, Whitfield J H, Pouvreau B, Cao D, Alexandrov K, Beveridge C A, Vickers C E. Rational design of novel fluorescent enzyme biosensors for direct detection of strigolactones [J]. ACS Synthetic Biology, 2020, 9(8): 2107–2118.

[85] Chen C, Yang L L, Tang A L, Wang P Y, Dong R, Wu Z B, Li Z, Yang S. Curcumin-Cu(II) ensemble-based fluorescence "turn-on" mode sensing the plant defensive hormone salicylic acid in situ and in vivo [J]. Agricultural and Food Chemistry, 2020, 68(17): 4844–4850.

[86] 曹艺颖, 陈虞超, 郭生虎,甘晓燕, 田莉, 黄璐琦, 袁媛. 独脚金内酯研究进展及其在药用植物的应用展望[J]. 中国中药杂志, 2023, 48(12): 3132–3139.

[87] Bouwmeester H, Li C, Thiombiano B, Rahimi M, Dong L. Adaptation of the parasitic plant lifecycle: Germination is controlled by essential host signaling molecules [J]. Plant Physiology, 2020, 185(4): 1292–1308.

[88] Chen Y, Kuang Y, Shi L, Wang X, Fu H, Yang S, Sampietro D A, Huang L, Yuan Y. Synthesis and evaluation of new halogenated GR24 analogs as germination promotors for Orobanche cumana [J]. Frontiers in Plant Science, 2021, 12: 725949.

[89] 方园, 姚瑞枫. 生物传感检测独脚金内酯的研究与展望[J]. 生命科学研究, 2021, 25(5): 455–462.

[90] Kawada K, Uchida Y, Takahashi I, Nomura T, Sasaki Y, Asami T, Yajima S, Ito S. Triflumizole as a novel lead compound for strigolactone biosynthesis inhibitor [J]. Molecules, 2020, 25(23): 5525.

[91] Rigal A, Ma Q, Robert S. Unraveling plant hormone signaling through the use of small molecules [J]. Frontiers in Plant Science, 2014, 5: 373.

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独脚金内酯类似物及其荧光探针的研究进展

Research Progress on Strigolactone Analogues and Its Fluorescent Probes

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