Zee Kar Yan, Asib Norhayu, Ismail Siti Izera
Universiti Putra Malaysia, 37449, Department of Plant Protection, Faculty of Agriculture, Serdang, Selangor, Malaysia;
Plant Dis. 2021 Apr 14. doi: 10.1094/PDIS-12-20-2732-PDN.
Guava (Psidium guajava L.) is an economically important tropical fruit crop and is cultivated extensively in Malaysia. In September and October 2019, postharvest fruit rot symptoms were observed on 30% to 40% of guava fruit cv. Kampuchea in fruit markets of Puchong and Ipoh cities in the states of Selangor and Perak, Malaysia. Initial symptoms appeared as brown, irregular, water-soaked lesions on the upper portion of the fruit where it was attached to the peduncle. Subsequently, lesions then progressed to cover the whole fruit (Fig.1A). Lesions were covered with an abundance of black pycnidia and grayish mycelium. Ten symptomatic guava fruit were randomly collected from two local markets for our investigation. For fungal isolation, small fragments (5×5 mm) were excised from the lesion margin, surface sterilized with 0.5% NaOCl for 2 min, rinsed three times with sterile distilled water, placed on potato dextrose agar (PDA) and incubated at 25 °C with 12-h photoperiod for 2-3 days. Eight single-spore isolates with similar morphological characteristics were obtained and two representative isolates (P8 and S9) were characterized in depth. Colonies on PDA were initially composed of grayish-white aerial mycelium, but turned dark-gray after 7 days (Fig. 1B). Abundant black pycnidia were observed after incubation for 4 weeks. Immature conidia were hyaline, aseptate, ellipsoid, thick-walled, and mature conidia becoming dark brown and 1-septate with longitudinal striations, 25.0 - 27.0 ± 2.5 × 13.0 - 14.0 ± 1.0 μm (n = 30) (Fig.1C, D). On the basis of morphology, both representative isolates were identified as Lasiodiplodia theobromae (Pat.) Griffon & Maubl. (Alves et al. 2008). For molecular identification, genomic DNA of the two isolates was extracted using the DNeasy plant mini kit (Qiagen, USA). The internal transcribed spacer (ITS) region of rDNA and translation elongation factor 1-alpha (EF1-α) genes were amplified using ITS5/ITS4 and EF1-728F/EF1-986R primer set, respectively (White et al. 1990, Carbone and Kohn 1999). BLASTn analysis of the resulting ITS and EF1-α sequences indicated 100% identity to L. theobromae ex-type strain CBS 164.96 (GenBank accession nos: AY640255 and AY640258, respectively) (Phillips et al. 2013). The ITS (MW380428, MW380429) and EF1-α (MW387153, MW387154) sequences were deposited in GenBank. Phylogenetic analysis using the maximum likelihood based on the combined ITS-TEF sequences indicated that the isolates formed a strongly supported clade (100% bootstrap value) to the related L. theobromae (Kumar et al. 2016) (Fig.2). A pathogenicity test of two isolates was conducted on six healthy detached guava fruits per isolate. The fruit were surface sterilized using 70% ethanol and rinsed twice with sterile water prior inoculation. The fruit were wound-inoculated using a sterile needle according to the method of de Oliveira et al. (2014) and five-mm-diameter mycelial agar plugs from 7-days-old PDA culture of the isolates were placed onto the wounds. Six additional fruit were wound inoculated using sterile 5-mm-diameter PDA agar plugs to serve as controls. Inoculated fruit were placed in sterilized plastic container and incubated in a growth chamber at 25 ± 1 °C, 90% relative humidity with a photoperiod of 12-h. The experiment was conducted twice. Five days after inoculation, symptoms as described above developed on the inoculated sites and caused a fruit rot, while control treatment remained asymptomatic. L. theobromae was reisolated from all symptomatic tissues and confirmed by morphological characteristics and confirmed by PCR using ITS region. L. theobromae has recently been reported to cause fruit rot on rockmelon in Thailand (Suwannarach et al. 2020). To our knowledge, this is the first report of L. theobromae causing postharvest fruit rot on guava in Malaysia. The occurrence of this disease needs to be monitored as this disease can reduce the marketable yield of guava. Preventive strategies need to be developed in the field to reduce postharvest losses.
番石榴(Psidium guajava L.)是一种具有重要经济价值的热带水果作物,在马来西亚广泛种植。2019年9月和10月,在马来西亚雪兰莪州蒲种市和霹雳州怡保市的水果市场中,30%至40%的柬埔寨番石榴品种出现采后果实腐烂症状。最初症状表现为果实与果柄连接处上部出现褐色、不规则、水渍状病斑。随后,病斑蔓延至整个果实(图1A)。病斑上覆盖着大量黑色分生孢子器和灰白色菌丝体。从两个当地市场随机收集了10个有症状的番石榴果实用于调查。为进行真菌分离,从病斑边缘切取小片段(5×5毫米),用0.5%次氯酸钠表面消毒2分钟,用无菌蒸馏水冲洗三次,置于马铃薯葡萄糖琼脂(PDA)上,在25°C、12小时光周期条件下培养2 - 3天。获得了8个形态特征相似的单孢分离株,并对两个代表性分离株(P8和S9)进行了深入鉴定。PDA上的菌落最初由灰白色气生菌丝组成,但7天后变为深灰色(图1B)。培养4周后观察到大量黑色分生孢子器。未成熟分生孢子无色、无隔膜、椭圆形、壁厚,成熟分生孢子变为深褐色且具1个隔膜,有纵向条纹,大小为25.0 - 27.0 ± 2.5 × 13.0 - 14.0 ± 1.0 μm(n = 30)(图1C、D)。基于形态学,两个代表性分离株均被鉴定为可可毛色二孢(Lasiodiplodia theobromae (Pat.) Griffon & Maubl.)(阿尔维斯等人,2008年)。为进行分子鉴定,使用DNeasy植物微量提取试剂盒(美国Qiagen公司)提取两个分离株的基因组DNA。分别使用引物对ITS5/ITS4和EF1 - 728F/EF1 - 986R扩增核糖体DNA的内部转录间隔区(ITS)和翻译延伸因子1 - α(EF1 - α)基因(怀特等人,1990年;卡尔博内和科恩,1999年)。对所得ITS和EF1 - α序列进行BLASTn分析表明,与可可毛色二孢模式菌株CBS 164.96的序列同一性为100%(GenBank登录号分别为AY640255和AY640258)(菲利普斯等人,2013年)。ITS(MW380428、MW380429)和EF1 - α(MW387153、MW387154)序列已存入GenBank。基于ITS - TEF联合序列使用最大似然法进行系统发育分析表明,分离株与相关的可可毛色二孢形成了一个得到强烈支持的分支(自展值为100%)(库马尔等人,2016年)(图2)。对两个分离株进行致病性测试,每个分离株对6个健康离体番石榴果实进行接种。接种前,果实先用70%乙醇表面消毒,并用无菌水冲洗两次。按照德奥利维拉等人(2014年)的方法,使用无菌针头对果实进行伤口接种,并将来自分离株7天龄PDA培养物的5毫米直径菌丝琼脂块置于伤口上。另外6个果实使用无菌的5毫米直径PDA琼脂块进行伤口接种作为对照。接种后的果实置于消毒塑料容器中,在生长室中于25 ± 1°C、相对湿度90%、12小时光周期条件下培养。该实验进行了两次。接种5天后,接种部位出现上述症状并导致果实腐烂,而对照处理保持无症状。从所有有症状组织中重新分离出可可毛色二孢,并通过形态特征和使用ITS区域的PCR进行确认。最近有报道称可可毛色二孢在泰国导致甜瓜采后果实腐烂(苏万纳拉奇等人,2020年)。据我们所知,这是可可毛色二孢在马来西亚导致番石榴采后果实腐烂的首次报道。需要对这种病害的发生情况进行监测,因为这种病害会降低番石榴的可销售产量。需要在田间制定预防策略以减少采后损失。
