内生真菌对新渡户树蜂共生真菌的抑制作用

doi:10.11707/j.1001-7488.20220512

摘要/Abstract

摘要：

目的: 研究不同寄主树种对新渡户树蜂共生真菌的种类影响，及寄主樟子松体内死亡新渡户树蜂幼虫体表的优势内生真菌对新渡户树蜂共生真菌的拮抗作用，从微观角度探索寄主内新渡户树蜂幼虫死亡的原因，为新渡户树蜂的生物防治提供新的思路和依据。方法: 根据形态特征和ITS序列鉴定不同寄主树种内新渡户树蜂的共生真菌种类，通过平板对峙和发酵液试验及显微观察判定优势内生真菌大伏革菌Phlebiopsis gigantea和绿色木霉Trichoderma viride对新渡户树蜂共生真菌Amylostereum chailletii和A. areolatum的拮抗能力。结果: 不同寄主树种中均能分离到新渡户树蜂的共生真菌A. chailletii和A. areolatum，但2种共生真菌的检出率差异显著。在樟子松中新渡户树蜂更易携带A. chailletii，而在油松中则更易携带A. areolatum。2种内生真菌的生长速率均快于共生真菌，其中绿色木霉的生长速率最快，共生真菌A. areolatum的生长速率最慢。绿色木霉和大伏革菌均能抑制共生真菌菌丝生长，并缠绕、寄生或穿插生长在共生真菌菌丝上，使得共生真菌菌丝扭曲、变形、异常膨大，最终完全覆盖共生真菌菌落，导致共生真菌无法生长而死亡。2种内生真菌发酵液对共生真菌A. chailletii和A. areolatum的分生孢子萌发有抑制作用，其中绿色木霉发酵液抑制效果高于大伏革菌，且发酵液稀释倍数越高，抑制效果越差。结论: 2种内生真菌对新渡户树蜂共生真菌均具有较强的拮抗效果，且内生真菌菌丝均可完全抑制并杀死共生菌菌丝，研究结果有望为新渡户树蜂的生物防治提供可用菌株。

关键词: 新渡户树蜂, 共生真菌, 内生真菌, 抑制作用

Abstract:

Objective: In this study, we investigated the influence of different host tree species on the types of symbiotic fungi of Sirex nitobei, and the antagonistic effect of dominant fungi on the body surface of the dead S. nitobei larvae in the host Pinus sylvestris var. mongolica on symbiotic fungi of S. nitobei, in order to explore the causes of death of S. nitobei larvae in the host tree from a microscopic perspective, so as to offer new ideas and basis for biocontrol of S. nitobei. Method: According to morphological characteristics and ITS sequences, the species of symbiotic fungi in different host tree species were identified, and the antagonistic ability of dominant endophytic fungi of Phlebiopsis gigantea and Trichoderma viride against symbiotic fungi (Amylostereum chailletii and A. areolatum) of S. nitobei was determined by plate confrontation, fermentation broth test and microscopic observation. Result: The symbiotic fungi of A. chailletii and A. areolatum were isolated from different host tree species, but the detection rates of two symbiotic fungi of S. nitobei were significantly different. The wasps in P. sylvestris var. mongolica were more likely to carry A. chailletii, while the wasps in P. tabulaeformis were easier to carry A. areolatum. The growth rate of the two endophytic fungi was faster than that of symbiotic fungi, of which Trichoderma viride had the fastest growth rate and symbiotic fungus of A. areolatum had the slowest growth rate. Both Trichoderma viride and Phlebiopsis gigantea were able to inhibit the growth of symbiotic fungal hyphae, and they wrapped, parasitized or interspersed on the symbiotic fungal hyphae, resulting in the distortion, deformation and abnormal expansion of symbiotic fungal hyphae. Eventually, the two endophytic fungi completely covered the colonies of symbiotic fungi, which caused the symbiotic fungi to be unable to grow and die. The fermentation broth of two endophytic fungi inhibited the conidial germination of symbiotic fungi of A. chailletii and A. areolatum. The inhibitiory effect of Trichoderma viride fermentation broth was higher than that of Phlebiopsis gigantea fermentation broth, furthermore, the higher the dilution ratio of fermentation broth, the worse the inhibitory effect. Conclusion: The two endophytic fungal species have strong antagonistic effects on the symbiotic fungi of S. nitobei, and these endophytic fungal hyphae can completely inhibit and kill the symbiotic fungal hyphae. The research results would provide available fungal strains for the biological control of S. nitobei.

Key words: Sirex nitobei, symbiotic fungi, endophytic fungi, inhibitory effect

中图分类号:

王立祥,崔树鹏,孔露露,王萱,杨宗基,任利利,骆有庆. 内生真菌对新渡户树蜂共生真菌的抑制作用[J]. 林业科学, 2022, 58(5): 113-120.

Lixiang Wang,Shupeng Cui,Lulu Kong,Xuan Wang,Zongji Yang,Lili Ren,Youqing Luo. Inhibitory Effects of Endophytic Fungi in Host Tree on the Symbiotic Fungi of Sirex nitobei (Hymenoptera: Siricidae)[J]. Scientia Silvae Sinicae, 2022, 58(5): 113-120.

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发酵液稀释倍数 Fermentation filtrates (multiple)	T VF抑制率 Inhibition of TVF(%)		PPF抑制率 Inhibition of PPF(%)
发酵液稀释倍数 Fermentation filtrates (multiple)	A. chailletii	A. areolatum	A. chailletii	A. areolatum
1	42.06±1.97a	46.19±1.84a	20.67±1.36a	18.17±1.19a
5	37.88±1.38a	39.57±1.88b	15.06±1.29b	13.06±1.16b
10	20.01±1.37b	26.98±1.01c	9.07±0.73c	9.85±1.07b
20	7.21±0.54c	11.12±1.29d	2.98±0.48d	2.64±0.34c
50	1.33±0.73d	2.21±0.62e	1.07±0.48d	0.86±0.54c

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