不同原料栽培花脸香蘑E70子实体农艺性状及营养成分分析

doi:10.11924/j.issn.1000-6850.casb2024-0621

摘要/Abstract

摘要： 针对花脸香蘑野生资源匮乏、规模化栽培技术缺乏、产量与品质不稳定的问题，为筛选适宜花脸香蘑优质高产的栽培基质配方，以花脸香蘑‘E70’菌株为试材，设置5种以麦草、玉米芯、棉籽壳、稻草为主要原料的栽培配方（A~E），采用一次发酵料畦栽法栽培，通过测定子实体农艺性状、营养成分及氨基酸组成，结合氨基酸比值系数（RCAA）、比值系数分（SRCAA）进行营养价值评价。结果表明：5种配方栽培的花脸香蘑在农艺性状、营养成分及氨基酸组成上存在显著差异。配方D（玉米芯50%+干牛粪26%+谷壳20%+石灰2%+石膏2%）表现最优，产量（46.73±0.15 a）%，生物学效率(46.73±0.15)%，显著或极显著高于其他配方，且子实体菌柄最粗壮、菌盖适中、颜色呈紫色，商品性最佳；其多糖含量4.76 g/100g，为配方A的2.44倍，SRCAA值68.56，必需氨基酸组成比例最合理。配方B（玉米芯60%+干牛粪36%+石灰2%+石膏2%）蛋白含量最高（36.70 g/100g），较配方A提高17.63%；配方E（稻草50%+干牛粪26%+谷壳20%+石灰2%+石膏2%）鲜味氨基酸含量最高（13.6 g/100g），较配方A提升13.14%，药用价值突出；配方C（棉籽壳56%+玉米芯20%+麸皮20%+石灰2%+石膏2%）氨基酸总量最高（25.6 g/100g），甜味氨基酸含量为7.41 g/100g，较配方D提升21.87%。5个配方蛋氨酸RCAA值最小且均小于1，为花脸香蘑的第一限制氨基酸。结论：配方D为花脸香蘑‘E70’菌株规模化栽培的最优配方，本研究结果为花脸香蘑标准化栽培技术研发与产业推广提供了科学依据，未来可进一步开展多菌株适配性及栽培工艺优化研究。

关键词: 花脸香蘑, 栽培基质, 农艺性状, 营养分析, 粗多糖, 氨基酸, 氨基酸评价分析

Abstract:

To investigate the effects of different cultivation substrates on the agronomic traits and quality of Lepista sordida, a formula cultivation experiment was conducted using the 'E70' strain of L. sordida. Five cultivation formulas (designated as A, B, C, D and E), were set up with wheat straw, corncob, cottonseed hull, and rice straw as the main cultivation substrates respectively. L. sordida was cultivated by the method of one-time fermented material bed cultivation. After the fruiting bodies formed, the agronomic traits and nutritional components of the fruiting bodies were determined to evaluate the impacts of fermented materials with different formulas on the agronomic traits and quality of L. sordida. The results showed that there were significant differences in yield, morphology, color and nutritional components of L. sordida among the five cultivation formulas. The biological efficiency of D (corncob 50% + dry cow dung 26% + husk 20% + lime 2% + gypsum 2%) was (46.73±0.15)%, which was significantly or extremely significantly higher than that of other formulas. Comprehensive assessment revealed that the fruiting bodies grown with D exhibited the optimal marketability, characterized by the highest yield, thickest stipe, small pilei, and purple color. The fruiting bodies of L. sordida in the five groups were rich in protein, polysaccharides, and amino acids. Specifically, protein of B (corncob 60% + dry cow dung 36% + lime 2% + gypsum 2%) was 36.70 g/100g; while the polysaccharide of D was 4.76 g/100g, which was 2.44 times that of A (straw 56% + corncob 28% + bran 8% + rapeseed cake 5% + lime 2% + gypsum 1%). The composition of taste amino acids followed the descending order of umami amino acids > bitter amino acids > sweet amino acids > aromatic amino acids. Notably, the umami amino acids of L. sordida in E (rice straw 50% + dry cow dung 26% + husk 20% + lime 2% + gypsum 2%) all exceeded the taste threshold, with a total content of 13.6 g/100g, representing 13.14% increase compared with A, respectively. The sweet amino acid content in C (cottonseed hull 56% + corncob 20% + bran 20% + lime 2% + gypsum 2%) reached 7.41 g/100g, 21.87% rise relative to D. The aspartic acid content in D was 2.7 g/100g, which was 90 times higher than its taste threshold. The glutamic acid content in E hit 6.3 g/100g, 126-fold higher than its taste threshold. Meanwhile, the SRCAA (Sorce of Ratio of Commonly Used Amnio Acids) value of amino acids in D was 68.56, suggesting that this formula had the most balanced proportion of essential amino acids among all test groups. The RCAA (Ratio of Commonly Used Amino Acids) value of methionine in all five formulas was the lowest (all<1), confirming that methionine is the first limiting amino acid of L. sordida. Formula D is the optimal formula for large-scale cultivation of L. sordida 'E70' strain. The results of this study provide a scientific basis for the research and development of standardized cultivation techniques and industrial promotion of L. sordida. In the future, multi-strain adaptation and cultivation process optimization can be further studied.

Key words: Lepista sordida, cultivation substrate, agronomic traits, nutritional analysis, polysaccharides, amino acids, amino acid evaluation analysis

赵辉, 何雪梅, 李彪, 冯慧, 邓力, 孙传齐, 马洁, 付亮. 不同原料栽培花脸香蘑E70子实体农艺性状及营养成分分析[J]. 中国农学通报, 2026, 42(5): 83-91.

ZHAO Hui, HE Xuemei, LI Biao, Feng Hui, DENG Li, SUN Chuanqi, MA Jie, FU Liang. Agronomic Traits and Nutritional Components Analysis of Lepista sordida E70 Cultivated with Different Raw Materials[J]. Chinese Agricultural Science Bulletin, 2026, 42(5): 83-91.

图/表 8

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配方	原基发生时间/d	菌柄直径/cm	菌柄长度/cm	菌盖直径/cm	菌盖厚度/cm	子实体单重/g	生物学效率/%
A	55	1.82	8.43	6.65	1.95	20.33	35.64±0.18 b
B	52	2.13	8.00	7.68	2.19	20.62	41.33±0.23 ab
C	50	1.78	6.72	5.60	1.98	18.99	28.92±0.11 bc
D	42	2.32	8.50	7.80	2.54	25.22	46.73±0.15 a
E	42	1.69	5.53	9.03	1.73	15.31	21.56±0.08 c

配方	原基发生时间/d	菌柄直径/cm	菌柄长度/cm	菌盖直径/cm	菌盖厚度/cm	子实体单重/g	生物学效率/%
A	55	1.82	8.43	6.65	1.95	20.33	35.64±0.18 b
B	52	2.13	8.00	7.68	2.19	20.62	41.33±0.23 ab
C	50	1.78	6.72	5.60	1.98	18.99	28.92±0.11 bc
D	42	2.32	8.50	7.80	2.54	25.22	46.73±0.15 a
E	42	1.69	5.53	9.03	1.73	15.31	21.56±0.08 c

氨基酸类型	A	B	C	D	E
苏氨酸*	1.16	1.27	1.39	1.22	1.27
缬氨酸*	1.05	1.21	1.27	1.18	1.18
甲硫氨酸（蛋氨酸）*#	0.3	0.29	0.33	0.29	0.31
异亮氨酸*	0.92	1.02	1.06	1.00	1.01
亮氨酸*#	1.54	1.67	1.8	1.68	1.66
苯丙氨酸#	0.94	1.05	1.1	1.14	1.04
赖氨酸*#	1.56	1.67	1.74	1.57	1.60
天冬氨酸#	2.33	2.53	2.64	2.70	2.64
酪氨酸#	0.50	0.55	0.60	0.54	0.56
丝氨酸	1.22	1.25	1.36	1.25	1.27
谷氨酸#	5.38	5.61	4.44	6.19	6.30
丙氨酸	1.76	2.05	2.25	1.59	1.86
甘氨酸#	1.11	1.23	1.37	1.17	1.20
组氨酸	1.22	0.79	1.5	1.36	0.79
精氨酸#	1.58	1.66	1.57	1.36	1.76
脯氨酸	0.91	0.92	1.04	0.85	0.92
必需氨基酸	7.47	8.18	8.69	8.08	8.07
非必需氨基酸	16.01	16.59	16.77	17.01	17.30
药用氨基酸	15.24	16.26	15.59	16.64	17.07
总氨基酸	23.5	24.8	25.6	25.1	25.4
必需氨基酸/总氨基酸	0.32	0.36	0.34	0.32	0.32
必需氨基酸/非必需氨基酸	0.47	0.49	0.52	0.48	0.47

氨基酸类型	A	B	C	D	E
苏氨酸*	1.16	1.27	1.39	1.22	1.27
缬氨酸*	1.05	1.21	1.27	1.18	1.18
甲硫氨酸（蛋氨酸）*#	0.3	0.29	0.33	0.29	0.31
异亮氨酸*	0.92	1.02	1.06	1.00	1.01
亮氨酸*#	1.54	1.67	1.8	1.68	1.66
苯丙氨酸#	0.94	1.05	1.1	1.14	1.04
赖氨酸*#	1.56	1.67	1.74	1.57	1.60
天冬氨酸#	2.33	2.53	2.64	2.70	2.64
酪氨酸#	0.50	0.55	0.60	0.54	0.56
丝氨酸	1.22	1.25	1.36	1.25	1.27
谷氨酸#	5.38	5.61	4.44	6.19	6.30
丙氨酸	1.76	2.05	2.25	1.59	1.86
甘氨酸#	1.11	1.23	1.37	1.17	1.20
组氨酸	1.22	0.79	1.5	1.36	0.79
精氨酸#	1.58	1.66	1.57	1.36	1.76
脯氨酸	0.91	0.92	1.04	0.85	0.92
必需氨基酸	7.47	8.18	8.69	8.08	8.07
非必需氨基酸	16.01	16.59	16.77	17.01	17.30
药用氨基酸	15.24	16.26	15.59	16.64	17.07
总氨基酸	23.5	24.8	25.6	25.1	25.4
必需氨基酸/总氨基酸	0.32	0.36	0.34	0.32	0.32
必需氨基酸/非必需氨基酸	0.47	0.49	0.52	0.48	0.47

氨基酸类型	氨基酸	味觉氨基酸含量阈值比(RCT)			味觉阈值/%
氨基酸类型	氨基酸	最大值	最小值	平均值	味觉阈值/%
甜味氨基酸	甘氨酸	1.25(C)	1.00(E)	1.09	1.10
	丙氨酸	3.75(C)	2.60(E)	3.07	0.60
	丝氨酸	0.91(C)	0.81(A)	0.85	1.50
	苏氨酸	0.53(C)	0.45(A)	0.49	2.60
	脯氨酸	0.35(C)	0.28(D)	0.31	3.00
苦味氨基酸	缬氨酸	0.85(C)	0.70(A)	0.78	1.50
	亮氨酸	0.47(C)	0.41(A)	0.44	3.80
	异亮氨酸	1.17(C)	1.02(A)	1.11	0.90
	蛋氨酸	1.10(C)	0.97(B)	1.01	0.30
	精氨酸	16.60(B)	13.60(D、E)	15.06	0.10
	组氨酸	7.50(C)	3.80(E)	5.63	0.20
	苯丙氨酸	0.76(D)	0.63(A)	0.70	1.50
鲜味氨基酸	谷氨酸	126(E)	88.8(C)	107.28	0.05
	天冬氨酸	90.00(D)	77.67(A)	84.53	0.03
	苯丙氨酸	0.76(D)	0.63(A)	0.70	1.50
	酪氨酸	0.23(E)	0.19(A)	0.21	2.60
	甘氨酸	1.25(C)	1.00(E)	1.09	1.10
	丙氨酸	3.75(C)	2.60(E)	3.07	0.60
芳香味氨基酸	苯丙氨酸	0.76(D)	0.63(A)	0.70	1.50
	酪氨酸	0.23(E)	0.19(A)	0.21	2.60
	半胱氨酸	—	—	—	0.02