草莓花器应答灰霉病菌侵染的表现特征及抗病性评价方法

doi:10.3864/j.issn.0578-1752.2026.07.006

摘要/Abstract

摘要：

【目的】草莓（Fragaria × ananassa）灰霉病是由灰葡萄孢（Botrytis cinerea）侵染引起的一种毁灭性病害，可危害草莓多个组织、器官，其中花器是主要的初侵染点，然而不同草莓种质花器对灰霉病的抗性不明确。本文旨在探究草莓花器应答灰葡萄孢的特征，建立以花器为接种材料评价不同草莓资源灰霉病抗性的方法，快速鉴定不同种质对灰霉病的抗性差异，筛选抗/感资源。【方法】以草莓抗/感品种‘艳丽’和‘红颜’离体花器为材料，接种灰葡萄孢Bc05.10分生孢子，鉴定不同组织的表现特征；对31个草莓品种花器离体接种Bc05.10并统计雄蕊病情指数，调查部分品种田间花器灰霉病发病率，并对两者进行相关性分析。【结果】两个品种雄蕊最先出现褐色病斑，并随着接种时间延长病斑从花药扩展到花丝，最终蔓延至花萼。‘红颜’雄蕊的病情指数显著高于‘艳丽’；接种后4 h，分生孢子在‘艳丽’雄蕊的萌发率（20.30%）显著低于‘红颜’（80.42%）。利用分生孢子接种离体花器的雄蕊，对31个草莓品种进行灰霉病抗性评价，其中‘俏佳人’‘弥生姬’‘粉佳人’以及‘光点’为抗病品种，‘红颜’‘天使8号’‘丰香’以及‘粉玉’为高感品种。田间灰霉病自然发病率调查结果显示，‘艳丽’‘晶玉’‘梦之莹’‘晶硕’以及‘粉佳人’花器田间发病率较低，‘香野’‘女峰’以及‘红颜’田间发病率较高。不同品种田间发病率与接种后12、24 h的病情指数相关系数分别为r=0.565（P=0.035）、r=0.610（P=0.021），呈显著正相关关系；与36 h的病情指数相关系数为r=0.328（P=0.252），无显著相关性；12 h+24 h的累计病情指数与田间发病率极显著正相关（r=0.713，P=0.004）。【结论】建立了以雄蕊为离体接种材料用于快速评价草莓对灰霉病抗性的评价体系，鉴定出一批草莓种质资源花器对灰霉病的抗性水平，为草莓灰霉病抗性资源筛选提供了新方法和参考依据。

关键词: 草莓, 灰霉病, 灰葡萄孢, 花器, 抗病性, 病情指数

Abstract:

【Objective】Strawberry (Fragaria × ananassa) gray mold, caused by the pathogen Botrytis cinerea, is a commercially devastating disease. This pathogen infects multiple tissues and organs of strawberry, with floral organs as the main primary infection sites. However, the resistance of floral organs among different strawberry germplasm to gray mold remains unclear. The present study aims to investigate the response characteristics of strawberry floral organs to B. cinerea infection, establish an in vitro floral inoculation method for evaluating gray mold resistance, rapidly identify the gray mold resistance differences among strawberry germplasm, and to screen out resistant and susceptible resources.【Method】In this study, detached flowers of strawberry resistant/susceptible cultivars ‘Yanli’ and ‘Benihoppe’ were used as experimental materials, and inoculated with conidia of B. cinerea strain Bc05.10 to identify the phenotypic characteristics of different tissues and the disease index of stamens. Floral organs of 31 strawberry cultivars were inoculated in vitro with Bc05.10 conidia to determine the stamen disease index. The field incidence of gray mold was surveyed, and a correlation analysis between the stamen disease index and field incidence was performed.【Result】Brown lesions first appeared on the stamens of two cultivars; as the inoculation time prolonged, the lesions spread from the anthers to the filaments, and eventually extended to the sepals. The disease index of stamens in ‘Benihoppe’ was significantly higher than that in ‘Yanli’. At 4 hours post-inoculation (hpi), the conidial germination rate on the stamens of ‘Yanli’ (20.30%) was significantly lower than that of ‘Benihoppe’ (80.42%). A total of 31 strawberry cultivars were evaluated for gray mold resistance by inoculating conidia of Bc05.10 onto the stamens of detached flowers. Among them, ‘Qiaojiaren’ ‘Yayohime’ ‘Fenjiaren’ and ‘Guangdian’ were identified as resistant cultivars, while ‘Benihoppe’ ‘Tianshi No. 8’ ‘Toyonoka’ and ‘Fenyu’ were highly susceptible cultivars. Field investigation on the natural incidence of gray mold revealed that the floral organs of ‘Yanli’ ‘Jingyu’ ‘Mengzhiying’ ‘Jingshuo’ and ‘Fenjiaren’ had the lowest field incidence, while ‘Tochiotome’ ‘Nyohō’ and ‘Benihoppe’ had the highest field incidence. The correlation coefficients between the field incidence of different cultivars and the disease index at 12 hpi and 24 hpi were r=0.565 (P=0.035) and r=0.610 (P=0.021), respectively, showing significant positive correlations; no significant correlation was observed between the field incidence and the disease index at 36 hpi (r=0.328, P=0.252). Additionally, the cumulative disease index at 12 hpi + 24 hpi showed a highly significant positive correlation with the field disease incidence (r=0.713, P=0.004).【Conclusion】A rapid evaluation system of strawberry resistance to gray mold was established by using isolated stamens as inoculation materials. It accurately assessed the resistance level of floral organs of different strawberry germplasm resources to gray mold, thereby providing a new method and reference for the screening of resistant strawberry resources.

Key words: strawberry (Fragaria × ananassa), gray mold, Botrytis cinerea, floral organ, resistance, disease index

张东梅, 周鑫鑫, 肖桂林, 曾祥国, 王春燕, 王泽先, 韩永超. 草莓花器应答灰霉病菌侵染的表现特征及抗病性评价方法[J]. 中国农业科学, 2026, 59(7): 1456-1466.

ZHANG DongMei, ZHOU XinXin, XIAO GuiLin, ZENG XiangGuo, WANG ChunYan, WANG ZeXian, HAN YongChao. Phenotypic Characteristics of Strawberry Floral Organs in Response to Botrytis cinerea Infection and Methods for Gray Mold Resistance Evaluation[J]. Scientia Agricultura Sinica, 2026, 59(7): 1456-1466.

图/表 7

图1

图2

图3

图4

表1

利用雄蕊评价不同草莓品种对灰霉病的抗性"

品种名 Cultivar name	病情指数Disease index			抗病等级 Disease resistance grade
品种名 Cultivar name	12 h	24 h	36 h	抗病等级 Disease resistance grade
俏佳人Qiaojiaren	5.95±3.89efgh	19.92±1.48efghij	26.19±4.76h	抗病R
弥生姬Yayohime	4.76±1.35fgh	10.95±0.89kl	28.57±5.35gh	抗病R
粉佳人Fenjiaren	5.00±1.01fgh	10.48±0.67l	29.52±4.53gh	抗病R
光点Guangdian	7.50±0.36cdefg	15.36±2.50hijkl	30.00±3.64gh	抗病R
白雪公主Baixuegongzhu	9.86±0.96bcd	15.05±0.26hijkl	30.61±1.67gh	中抗MR
丽红Lihong	5.95±1.52efgh	15.63±1.34ghijkl	31.12±2.55gh	中抗MR
宁丰Ningfeng	7.14±2.19cdefg	17.86±1.79ghijkl	31.25±4.46gh	中抗MR
淡雪Awakuki Yuki	6.55±1.83defg	16.96±5.69ghijkl	32.74±11.04gh	中抗MR
美味C Meiwei C	11.16±0.45b	19.64±3.18fghijk	35.12±3.67fgh	中抗MR
艳丽Yanli	2.98±0h	16.35±1.37ghijkl	36.90±0.71efgh	中抗MR
真红美玲Shinku Mirei	7.14±1.29cdefg	12.50±1.75ijkl	37.20±2.68efgh	中抗MR
晶硕Jingshuo	4.17±0.84gh	11.51±0.74jkl	38.39±0.30efgh	中抗MR
天使Tianshi	10.42±0.89bc	11.90±0.60jkl	38.69±10.12efgh	中抗MR
申馨Shenxin	10.32±1.12bc	28.17±0.74bcde	38.76±1.66efgh	中抗MR
梦之莹Mengzhiying	4.29±0gh	16.79±3.21ghijkl	39.00±1.07efgh	中抗MR
天仙醉Tianxianzui	10.27±0.45bc	22.77±5.80cdefgh	39.78±4.27efgh	中抗MR
晶玉Jingyu	9.52±0.97bcd	16.67±5.52ghijkl	39.88±9.52efgh	中抗MR
女峰Nyohō	9.26±0.99bcde	16.80±0.82ghijkl	40.08±6.62efgh	感病S
梦之芙Mengzhifu	7.50±0.36cdefg	18.57±1.01ghijkl	42.14±1.01efg	感病S
初恋Chulian	3.10±0.71h	17.78±2.97ghijkl	48.10±3.50def	感病S
香野Tochiotome	7.30±0.59cdefg	23.65±2.97cdefgh	48.25±3.51def	感病S
晶怡Jingyi	7.62±1.43cdefg	16.90±1.18ghijkl	50.66±5.40cde	感病S
卡姆罗莎Camarosa	14.29±0a	27.98±5.12bcdef	57.14±7.72bcd	感病S
佐贺清香Saga Seikou	4.82±0.54fgh	24.29±3.44cdefg	59.17±4.27bcd	感病S
熿香Huangxiang	7.29±1.17cdefg	21.48±3.94defgh	60.94±2.01bcd	感病S
京桃香Jingtaoxiang	5.95±1.05efgh	20.92±3.18defghi	61.96±10.63bc	感病S
妙香7号Miaoxiang No.7	7.44±0.30cdefg	30.95±4.64bc	64.88±2.98ab	感病S
天使8号Tianshi No.8	6.07±0.36efgh	28.81±5.42bcd	65.71±4.29ab	高感HS
红颜Benihoppe	8.14±0.74bcdef	39.09±5.84a	67.26±0.60ab	高感HS
丰香Toyonoka	9.72±1.12bcd	16.67±2.38ghijkl	68.65±2.45ab	高感HS
粉玉Fenyu	4.93±1.05fgh	28.74±3.13bcd	77.55±5.07a	高感HS

表1

图5

表2

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皮尔森相关系数 Pearson correlation coefficient	病情指数Disease index
皮尔森相关系数 Pearson correlation coefficient	12 h	24 h	36 h	12 h+24 h	12 h+24 h+36 h
田间发病率Field incidence	r=0.565*, P=0.035	r=0.610*, P=0.021	r=0.328, P=0.252	r=0.713**, P=0.004	r=0.596*, P=0.025