Ma Xiaofang, Zhai Lifeng, Jiang Yingchun, Wang Zhijing, He Ligang, Song Fang, Wu Liming
Hubei Academy of Agricultural Sciences, Research Institute of Fruit and Tea, No.10,Nanhu Avenue, Hongshan District, Wuhan, China, 430064;
Yangtze Normal University, College of Life Science and Technology, No16, Juxian Road, Fuling District, Chongqing, China, 408100;
Plant Dis. 2022 Jul 25. doi: 10.1094/PDIS-03-22-0694-PDN.
Trifoliate orange (Poncirus trifoliata L) is a thorny tree of the Rue family, which is extensively used as citrus rootstock in China. In January 2021, several leaf yellowing, declining, and wilting citrus seedlings grafted on trifoliate orange rootstock with rotted main roots were observed in orchards located in Wuhan city, Hubei, China. In old orchards, the incidence of diseased roots was approximately 90%. Diseased roots from seven plants were collected and cut into small pieces (0.2 to 0.5 cm). These pieces were then surface-sterilized using 0.1% mercury bichloride for 3 min, 75% ethanol for 3 min, rinsed with sterile distilled water for several times, and then placed on potato dextrose agar (PDA) supplemented with 0.05% lactic acid (v/v), and incubated at at 25±2°C in dark. Fifty-threesingle-conidium isolates with morphological characteristics similar to Fusarium spp. were obtained (Leslie and Summerell 2006), which displayed two kinds of colony morphology. Thirty isolates showed white to orange-white abundant aerial mycelium in rings and acquired a yellow to orange pigmentation, tweenty-three isolates showed white to pink, fluffy aerial mycelium in rings and acquired an orange to red pigmentation. Isolate WG-1 and HrmY-9 from each group were used for future identification. The average colony growth rate of WG-1 and HrmY-9 on PDA was 0.95±0.06 and 0.69±0.11 mm/day, n=4, respectively. WG-1 produced numerous oval, unicellular microconidia without septa, 4.03-9.87×1.01-5.13 µm, n=80 and very few macroconidia with two to four septa, narrowed at both ends, 11.08-22.64×1.67-4.91 µm, n=30. HrmY-9 produced numerous curved macroconidia with three to four septa, 18.03-37.33×2.16-7.8 µm, n=80, microconidia were unicellular, oval, and 5.33-16.19×1.74-6.51 µm, n=50. Sequences of internal transcribed spacer (ITS), translation elongation factor 1-alpha (EF-1α), and DNA-directed RNA polymerase largest subunit (RPB1) genes were amplified with the primers ITS1/ITS4, EF1a-F/EF1a-R, and RPB1-F5/RPB1-R8, respectively (White et al. 1990, O'Donnell et al. 1998, O'Donnell et al. 2010), sequenced and deposited in GenBank. Sequences of isolate WG-1 (GenBank accession No. ON045437, ON063232 and ON089664) and HrmY-9 (GenBank accession No. ON045438, ON063233 and ON089665) were 100% identical with the corresponding sequences of Fusarium oxysporum (OM876904, JF430180, and MT568959) and F. solani (MT605584, MK617767, and MT305110), respectively. Based on above results, WG-1 and HrmY-9 was identified as F. oxysporum and F. solani, respectively. Pathogenicity test were performed on healthy one-year-old trifoliate orange seedlings by dipping their injured roots into conidial suspension (50 ml, 1×106 conidia/mL) for 1 h and the rest of conidial suspension was added to the pot after replanting to make sure the inoculum was in contact with the roots. Roots of control plants were inoculated with sterilized water. All experiments were repeated twice. All plants were cultured at 26°C under a 16-h light/dark cycle. Typical symptoms developed on most of inoculated seedlings two months post inoculation. No disease symptoms appeared on control plants. Same colonies were reisolated from the inoculated roots, confirming Koch's postulates. To our knowledge, this is the first report of F. oxysporum and F. solani causing root rot on trifoliate orange rootstock in China. The identification of F. oxysporum and F. solani as the causal agents of the observed root rot on trifoliate orange rootstock is critical to the prevention and control of this disease in the future.
枳(Poncirus trifoliata L)是芸香科的一种带刺树木,在中国被广泛用作柑橘类砧木。2021年1月,在中国湖北省武汉市的果园中,观察到几株嫁接到枳砧木上的柑橘幼苗出现叶片发黄、衰弱和枯萎现象,主根腐烂。在老果园中,病根发生率约为90%。采集了七株患病植株的根,切成小块(0.2至0.5厘米)。然后将这些小块用0.1%升汞表面消毒3分钟,再用75%乙醇消毒3分钟,用无菌蒸馏水冲洗几次,然后置于添加了0.05%乳酸(v/v)的马铃薯葡萄糖琼脂(PDA)上,在25±2°C黑暗条件下培养。获得了53个形态特征与镰刀菌属相似的单分生孢子分离株(Leslie和Summerell,2006),这些分离株表现出两种菌落形态。30个分离株呈现出白色至橙白色的丰富气生菌丝环,并产生黄色至橙色色素,23个分离株呈现出白色至粉红色的蓬松气生菌丝环,并产生橙色至红色色素。每组中的分离株WG-1和HrmY-9用于后续鉴定。WG-1和HrmY-9在PDA上的平均菌落生长速率分别为0.95±0.06和0.69±0.11毫米/天,n = 4。WG-1产生大量椭圆形、单细胞、无隔膜的小分生孢子,4.03 - 9.87×1.01 - 5.13微米,n = 80,很少有具2至4个隔膜且两端狭窄的大分生孢子,11.08 - 22.64×1.67 - 4.91微米,n = 30。HrmY-9产生大量具3至4个隔膜的弯曲大分生孢子,(18.03 - 37.33×2.16 - 7.8微米,n = 80,小分生孢子为单细胞、椭圆形,5.33 - 16.19×1.74 - 6.51微米,n = 50。分别用引物ITS1/ITS4、EF1a-F/EF1a-R和RPB1-F5/RPB1-R8扩增内部转录间隔区(ITS)、翻译延伸因子1-α(EF-1α)和DNA指导的RNA聚合酶最大亚基(RPB1)基因的序列(White等人,1990;O'Donnell等人,1998;O'Donnell等人,2010),测序后存入GenBank。分离株WG-1(GenBank登录号ON045437、ON063232和ON089664)和HrmY-9(GenBank登录号ON045438、ON063233和ON089665)的序列分别与尖孢镰刀菌(OM876904、JF430180和MT568959)和茄病镰刀菌(MT605584、MK617767和MT305110)的相应序列100%相同。基于上述结果,WG-1和HrmY-9分别被鉴定为尖孢镰刀菌和茄病镰刀菌。通过将健康的一年生枳幼苗受伤的根浸入分生孢子悬浮液(50毫升,1×10⁶分生孢子/毫升)1小时,并在重新种植后将其余的分生孢子悬浮液加入花盆中以确保接种物与根接触,对其进行致病性测试。对照植株的根接种无菌水。所有实验重复两次。所有植株在26°C、16小时光照/黑暗周期下培养。接种后两个月,大多数接种的幼苗出现典型症状。对照植株未出现病害症状。从接种的根中重新分离出相同的菌落,证实了柯赫氏法则。据我们所知,这是中国首次报道尖孢镰刀菌和茄病镰刀菌引起枳砧木根腐病。将尖孢镰刀菌和茄病镰刀菌鉴定为观察到的枳砧木根腐病的病原菌,对于今后该病的预防和控制至关重要。
