Journal of Tropical Oceanography >
Research progress on the secondary metabolites and activities of endophytic fungi of genus Aspergillus and Trichoderma from mangroves
Copy editor: YAO Yantao
Received date: 2022-09-14
Revised date: 2022-11-15
Online published: 2022-12-08
Supported by
Research and Development Foundation of Beijing City University(KYF202003)
2022 Graduate Research Innovation Project of Beijing City University(Yjscx202243)
Mangrove endophytic fungi has evolved a unique metabolic pathway due to its high salt, high temperature, strong light and anoxic living environment, and then produced a large number of secondary metabolites with rich species, novel structure and significant activity, making the secondary metabolites of mangrove endophytic fungi a research hotspot in recent years. In the field of mangrove endophytic fungi, Aspergillus and Trichoderma are two genera that have been studied frequently. This paper reviews the recent advance on the chemical structure and biological activity of new secondary metabolites of the endophytic fungi of genus Aspergillus from mangrove from January 2018 to October 2022 and the endophytic fungi of genus Trichoderma from mangrove from January 2015 to October 2022, summarizes them by polyketones, alkaloids, terpenoids and other compounds, and highlights the challenges in the current research. It can provide reference and guidance for the future study of mangrove endophytic fungi.
Key words: mangroves; endophytes; genus Aspergillus; genus Trichoderma; secondary metabolites
LIANG Hanqiao , CHEN Wenfeng , FAN Yikai , ZHU Zidong , MA Guoxu , CHEN Deli , TIAN Jing . Research progress on the secondary metabolites and activities of endophytic fungi of genus Aspergillus and Trichoderma from mangroves[J]. Journal of Tropical Oceanography, 2023 , 42(4) : 12 -24 . DOI: 10.11978/2022190
图2 红树林曲霉属真菌中分离得到的聚酮类化合物(16—26)[改自Elsbaey等(2022)、郝丽丽等(2020)、Zhang等(2023)、Guo等(2020)、Wang等(2021)、Xiao等(2021)]Fig. 2 Polyketides isolated from genus Aspergillus mangrove (16—26) [after Elsbaey et al (2022), Hao et al (2020), Zhang et al (2023), Guo et al (2020), Wang et al (2021), and Xiao et al (2021)] |
[1] |
陈长锟, 吴婷, 何若男, 等, 2020. 海洋木霉属真菌次生代谢产物活性研究进展[J]. 海峡药学, 32(9): 1-5.
|
[2] |
邓祖军, 曹理想,
|
[3] |
高剑, 2013. 红树林内生真菌多样性及其生态分布[D]. 湛江: 广东海洋大学.
|
[4] |
郝丽丽, 2020. 北部湾红树林老鼠簕内生真菌次级代谢产物和百香果皮化学成分及其生物活性研究[D]. 桂林: 广西师范大学.
|
[5] |
洪璇, 吴婷, 陈长锟, 等, 2020. 海洋曲霉属真菌抗菌活性物质的研究进展[J]. 生物资源, 42(4): 382-387.
|
[6] |
靳锦, 赵庆, 张晓梅, 等, 2018. 植物内生菌活性代谢产物最新研究进展[J]. 微生物学杂志, 38(3): 103-113.
|
[7] |
李庆欣, 史雪凤, 黄智, 等, 2013. 海洋真菌来源吲哚生物碱类化合物的结构和活性研究[J]. 热带海洋学报, 32(1): 35-47.
|
[8] |
林鹏, 2001. 中国红树林研究进展[J]. 厦门大学学报 (自然科学版), 40(2): 592-603.
|
[9] |
马丽丽, 田新朋, 李桂菊, 等, 2021. 海洋微生物来源天然产物研究现状与态势[J]. 热带海洋学报, 40(5): 134-146.
|
[10] |
王成, 张国建, 刘文典, 等, 2019. 海洋药物研究开发进展[J]. 中国海洋药物, 38(6): 35-69.
|
[11] |
王友绍, 2021. 全球气候变化对红树林生态系统的影响、挑战与机遇[J]. 热带海洋学报, 40(3): 1-14.
|
[12] |
杨曦亮, 任梦瑶, 刘倩, 等, 2021. 近十年海洋来源木霉属真菌次生代谢产物研究进展[J]. 广西科学, 28(5): 440-450.
|
[13] |
张敏, 2015. 红树林内生真菌Trichoderma sp. Xy24萜类代谢产物及Harzianone的微生物转化[D]. 北京: 北京中医药大学.
|
[14] |
张娜, 傅小雪, 王文婧, 2021. 泰国红树内生真菌土曲霉xy03菌株中新杂萜类成分[J]. 菌物学报, 40(1): 222-231.
|
[15] |
朱伟明, 王俊锋, 2011. 海洋真菌生物活性物质研究之管见[J]. 菌物学报, 30(2): 218-228.
|
[16] |
朱琰兰, 2020. 红树内生真菌Aspergillus sp. xy14的次生代谢产物研究[D]. 广州: 南方医科大学.
|
[17] |
|
[18] |
|
[19] |
|
[20] |
|
[21] |
|
[22] |
|
[23] |
|
[24] |
|
[25] |
|
[26] |
|
[27] |
|
[28] |
|
[29] |
|
[30] |
|
[31] |
|
[32] |
|
[33] |
|
[34] |
|
[35] |
|
[36] |
|
[37] |
|
[38] |
|
[39] |
|
[40] |
|
[41] |
|
[42] |
|
[43] |
|
[44] |
|
[45] |
|
/
〈 | 〉 |