高效抑制松材线虫的复合木腐菌筛选

doi:10.11707/j.1001-7488.LYKX20240705

摘要/Abstract

摘要：

目的: 筛选一组能够高效抑制松材线虫的复合木腐菌，为研发松材线虫病伐桩的环保除治新方式提供理论依据。方法: 以17组复合木腐菌为对象，分别测定白腐菌（W）与褐腐菌（B）共培养过程中的抑制率，以此作为初步筛选标准获得15组复合木腐菌；观察计算松材线虫在复合培养木腐菌平板上的死亡率，获得对松材线虫具有抑制作用的复合木腐菌；将红松和马尾松接种至含有复合木腐菌的培养瓶中，分别培养一定时间后获得降解率高的复合木腐菌。将筛选得到的复合木腐菌W5473:B80995（桦褶孔菌与红缘拟层孔菌）进行傅里叶红外光谱分析，明确红松和马尾松的降解情况；将复合木腐菌制成微生物菌剂应用于林间，统计分析伐桩内松材线虫数量的变化和伐桩的降解率，获得菌剂的林间应用效果。结果: 1） 17组复合木腐菌中，2组复合木腐菌在培养过程中始终存在抑制作用，选择其余15组相互间没有持续性抑制作用的复合木腐菌作为下一步筛选试验的材料。2）初步筛选试验获得的15组复合木腐菌中，9组复合木腐菌对松材线虫的抑制作用达到100%，14组复合木腐菌中的松材线虫死亡率大于88%；在复合木腐菌降解红松和马尾松的第30、60、90天，W5473:B80995的降解率显著高于其他复合木腐菌，综合松材线虫死亡率与木块降解率的试验结果，选择W5473:B80995作为下一步试验的材料。3） W5473:B80995对马尾松的降解率高于红松，木质素降解缓慢，降解速率低于纤维素和半纤维素。降解至第90天时，半纤维素降解基本完成，马尾松纤维素的降解速率显著减缓并趋于稳定，而红松纤维素仍保持较高的降解速率。结论: 通过对17组复合木腐菌进行筛选，获得复合木腐菌W5473:B80995。该复合木腐菌对松材线虫的抑制率达96.7%；在第90天时对红松的降解率达37.58%，对马尾松的降解率达49.88%，具有良好的应用前景。相较于红松，该复合木腐菌对马尾松的降解效率更高。降解过程中，纤维素和半纤维素的分解主要集中在前中期，木质素则较难分解；降解后期，马尾松的物质降解基本趋于稳定。经复合木腐菌处理后，伐桩内松材线虫数量减少，伐桩质量显著降低，伐桩内松材线虫数量减少率与伐桩降解率具有正相关关系。

关键词: 复合木腐菌, 松材线虫, 伐桩除治, 降解率

Abstract:

Objective: This study aims to obtain a set of co-cultured wood rot fungi that can efficiently inhibit the growth of Bursaphelenchus xylophilus, so as to provide a theoretical basis for the research and development of a new environmentally friendly treatment way of wood stumps infected by B. xylophilus. Method: Seventeen co-cultured wood rot fungi were used as the object, and the inhibition rates during co-cultivation of white rot fungi (W) and brown rot fungi (B) were measured as preliminary screening criteria, and 15 groups of co-cultured fungi were obtained. The mortality of B. xylophilus in co-cultured fungal cultures was observed and calculated to identify B. xylophilus-inhibiting fungi. Pinus koraiensis and P. massoniana blocks were inoculated into jars with co-cultured fungi, and degradation rates were evaluated after specific periods. The selected optimal co-cultured fungi W5473 (Lenzites betulinus):B80995 (Fomitopsis pinicola) were analyzed via Fourier transform infrared (FTIR) spectroscopy to clarify the wood degradation status of P. koraiensis and P. massoniana. The co-cultured wood rot fungi were used as a microbial agent and applied in woodland trials, and the changes in B. xylophilus populations and stump degradation rates were counted and statistically analyzed to obtain the application effect of the microbial agent in the forest. Result: 1) Among 17 groups of co-cultured wood rot fungi, 2 groups exhibited sustained mutual inhibition throughout the cultivation process. The remaining 15 groups of co-cultured wood rot fungi without mutual inhibition were selected for further testing. 2) Among the 15 groups of co-cultured wood rot fungi obtained from the preliminary screening experiment, 9 groups achieved 100% inhibitory effect on B. xylophilus, and 14 groups caused the mortality rates of B. xylophilus more than 88%. At 30, 60, and 90 days of degradation of P. koraiensis and P. massoniana by co-cultured wood rot fungi, the degradation rate of W5473:B80995 was significantly higher than that of other co-cultured wood rot fungi. Based on the experimental results of the mortality of B. xylophilus and the degradation performance of wood blocks, the fungi W5473:B80995 were selected for the further experiment. 3) The fungi W5473:B80995 degraded P. massoniana more efficiently than P. koraiensis. Lignin degradation was slower than cellulose and hemicellulose. By day 90, hemicellulose degradation was complete, P. massoniana cellulose degradation slowed and stabilized, while P. koraiensis cellulose maintained higher degradation rates. Conclusion: The optimal co-cultured fungi W5473:B80995 have been screened from 17 candidates, and their suppression rate against B. xylophilus reaches 96.7%. At 90 days, the degradation rate of P. koraiensis reaches 37.58%, and of P. massoniana reaches 49.88%, showing strong application potential. The fungi W5473:B80995 have higher degradation efficiency for P. massoniana than for P. koraiensis. The decomposition of cellulose and hemicellulose degradation is concentrated in early-mid phases, while lignin remains recalcitrant. Degradation tends to stabilize in later phases for P. massoniana. After treatment with co-cultured wood rot fungi, B. xylophilus populations and stump mass are significantly reduced in the woodland applications. And B. xylophilus reduction is positively correlated to stump degradation rates.

Key words: co-cultured wood rot fungi, Bursaphelenchus xylophilus, treatment of stumps, degradation rate

中图分类号:

S763

原燕枝,余璐,胡坚,顾蝶,薛寒,李永,汪来发,程相称,韩珊,王曦茁. 高效抑制松材线虫的复合木腐菌筛选[J]. 林业科学, 2025, 61(11): 116-124.

Yanzhi Yuan,Lu Yu,Jian Hu,Die Gu,Han Xue,Yong Li,Laifa Wang,Xiangchen Cheng,Shan Han,Xizhuo Wang. Screening of Co-Cultured Wood Rot Fungi for Efficient Inhibition of Bursaphelenchus xylophilus[J]. Scientia Silvae Sinicae, 2025, 61(11): 116-124.

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木腐菌Wood rot fungi	真菌Fungi	菌株Strains
白腐菌 White rot fungi	烟管菌Bjerkandera adusta	CFCC 5294
	一色齿毛菌Cerrena unicolor	CFCC 6884
	桦褶孔菌Lenzites betulinus	CFCC 5473
	黄孢原毛平革菌Phanerochaete chrysosporium	CFCC 6676
	毛韧革菌Stereum hirsutum	CFCC 89107
	扁韧革菌Stereum ostrea	CFCC 82502
	毛栓菌Trametes hirsute	CFCC 81037
	东方栓孔菌Trametes orientalis	CFCC 82905
	绒毛栓孔菌Trametes pubescens	CFCC 81039
	香栓菌Trametes suaveolens	CFCC 81038
	变色栓菌Trametes versicolor	CFCC 7341
褐腐菌 Brown rot fungi	红缘拟层孔菌Fomitopsis pinicola	CFCC 80995
	香菇Lentinula edodes	CFCC 5457
	松杉暗孔菌Phaeolus schweinitzii	CFCC 81263
	多脂鳞伞Pholiota adiposa	CFCC 8569
	桦剥管菌Piptoporus betulinus	CFCC 87226
	绵皮卧孔菌Postia placenta	CFCC 5608
	茯苓Wolfiporia extensa	CFCC 81525

复合木腐菌 Co-cultured wood rot fungi	D1	D2	D3	D4	D5	D6	D7	D8
W81038:B5608	0.00	30.77	15.25	–3.85	2.97	–7.34
W81038:B5608	–10.00	–9.46	–32.67	–38.76	–45.64	–27.87

W6884:B87226	14.29	16.87	14.73	0.00	2.58	–3.69
W6884:B87226	49.33	45.79	45.65	45.00	29.52	21.35

W6676:B80995	52.63	56.72
W6676:B80995	–278.95	–293.62

W6676:B81525	63.16	7.46
W6676:B81525	–18.18	7.34

W6676:B5457	1.32	7.96
W6676:B5457	100.00	–164.86

W6676:B81263	63.16	5.97
W6676:B81263	78.00	33.86

W6676:B5608	63.16	8.46
W6676:B5608	–37.50	0.00

W89107:B5608	–6.67	15.00	3.45	35.50
W89107:B5608	–47.50	-21.62	–2.97	–10.85

W5473:B5457	5.56	45.00	8.75	–2.06	6.04	4.40	13.90	3.06
W5473:B5457	100.00	40.54	19.15	–10.91	-5.41	–12.79	–19.00	–19.66

W81037:B81525	14.29	9.92
W81037:B81525	6.06	6.42

W5294:B8569	8.82	–1.20	9.56	13.47	9.09
W5294:B8569	0.00	–5.71	–3.64	–7.81	8.64

W5473:B80995	0.00	4.76	–6.49	–5.75	–5.00	–3.08
W5473:B80995	0.00	6.25	21.88	20.45	22.52	14.06

W82502:B5608	–17.65	–2.11	39.72
W82502:B5608	–30.00	–4.05	–5.94

W7341:B81263	–6.45	–17.74	–51.28
W7341:B81263	74.00	26.98	22.22

W82905:B81263	–4.00	–22.45	–1.33
W82905:B81263	71.33	35.98	27.35

W81039:B5608	33.33	16.95	5.75	16.05	27.49
W81039:B5608	–70.00	–21.62	–3.96	–6.98	–5.37

W81039:B81263	20.51	11.86	–11.49
W81039:B81263	81.33	38.10	28.63

类型Type	伐桩编号 Stump No.	松材线虫数量 Number of B. xylophilus		松材线虫减少率 Reduction rate of B. xylophilus (%)	伐桩降解率 Degradation rate of stumps (%)
类型Type	伐桩编号 Stump No.	接种前 Pre-plant	接种后 Post-plant	松材线虫减少率 Reduction rate of B. xylophilus (%)	伐桩降解率 Degradation rate of stumps (%)
对照 Control	1	608.2±20.75b	359.4±15.88b	40.91	3.93±0.03e
	2	23.4±9.58e	11.8±2.28e	49.57	3.6±0.03e
	3	311.2±22.95c	194±20.51c	37.66	7.18±0.07d
	4	589.4±31.6b	284.2±26.06b	51.78	4.87±0.06de
	5	68.2±6.18e	39.2±8.32e	42.52	4.61±0.35e
处理Treatment	6	232.4±29.01d	91.8±15.47d	60.5	32.64±2.04ab
	7	669.4±31.5a	252.2±36.07a	62.32	34.5±0.1a
	8	54.4±23.54e	13.4±4.28e	75.37	31.39±1.26b
	9	265±38.96cd	122.2±22.74cd	53.89	30.94±1.03b
	10	321.6±36.2c	172.6±25.19c	46.33	28.09±0.77c

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