Yang X B, Workneh F, Lundeen P
Department of Plant Pathology, Iowa State University, Ames 50011.
Plant Dis. 1998 Feb;82(2):264. doi: 10.1094/PDIS.1998.82.2.264B.
Stem rot of soybean caused by Sclerotinia sclerotiorum (Lib.) de Bary was not recognized as an important problem in the North Central Region of the United States until severe outbreaks occurred in 1992, 1994, and 1996 (2). Although sclerotia mixed with seeds are known to be important to the spread of this disease, the role of internally infested soybean seed in dissemination of the disease is unknown. Tu (1) demonstrated in dry bean, which differs from soybean in seed size and plant architecture, that internally infected seeds are important to the spread of the disease, by producing sclerotia in the soil after the seeds are planted. Experiments were conducted to determine if sclerotia are formed in soils from internally infected soybean seeds. Soybean seed from a field with 70% disease severity were collected and sorted into three classes: (i) normal quality seed, which included moderate or good seed; (ii) poor quality seed (shriveled and/or whitish); and (iii) seed of regular size with visible mycelial mats (S. sclerotiorum or Peronospora manshurica (Naumov) Syd. in Gäum) on the seed coat. Transfer of surface-disinfested seeds to potato dextrose agar and subsequent production of sclerotia showed that 2, 44, and 6% of the seed from each respective class were infested with S. sclerotiorum. One hundred seeds from each of these classes were planted into sterilized and nonsterilized soil at a rate of 5 seeds per pot. Toothpicks were placed to identify the location of each seed, and seeds were covered with 2 cm of soil. Pots were placed in growth chambers with a 14-h photoperiod under two temperature regimes: (i) at 20°C; and (ii) at 10°C for 10 days and then raised to 20°C. Soil was kept saturated by periodically top watering the pots for the first 10 days and bottom watering after that. Two weeks after planting, seeds were examined for formation of sclerotia and the percentages of seeds from which sclerotia were formed were calculated. The experiments were conducted four times. One to two (occasionally three) sclerotia were found in place of each seed that did not germinate. Sclerotia were mainly found from seeds of poor quality, with an average of 12% seeds that produced sclerotia. The frequency of sclerotia found in normal quality seeds was 0.4%, and no sclerotia were found from seeds with mycelial mats. The sclerotia were 2.36 ± 1.07 mm in width, 3.33 ± 1.11 mm in length, and 6.8 ± 3.7 mg in weight, with an averaged germination rate of 88% 8 months after production. Sclerotia production frequencies were 11.4 and 15.4% for temperature regimes (i) and (ii), respectively. Higher percentages of sclerotium production were found in sterilized soil (15.6%) than nonsterilized soil (7.5%). Our results indicate the possibility of internally infected soybean seeds as a means for field-to-field dissemination of S. sclerotiorum. References: (1) J. C. Tu. J. Phytopathol. 121:40, 1988. (2) X. B. Yang. ICM Newsl. 18, 1997.
由核盘菌(Sclerotinia sclerotiorum (Lib.) de Bary)引起的大豆菌核病,直到1992年、1994年和1996年该病严重爆发时,才被认为是美国中北部地区的一个重要问题(2)。虽然已知混在种子中的菌核对这种病害的传播很重要,但带菌大豆种子在病害传播中的作用尚不清楚。图(1)在菜豆(其种子大小和植株结构与大豆不同)上证明,带菌种子在播种后在土壤中产生菌核,对病害传播很重要。开展试验以确定带菌大豆种子在土壤中是否会形成菌核。从病害严重程度达70%的田块收集大豆种子,并分为三类:(i)正常质量种子,包括中等或优质种子;(ii)劣质种子(皱缩和/或发白);(iii)种皮上有可见菌丝层(核盘菌或东北霜霉(Peronospora manshurica (Naumov) Syd. in Gäum))的常规大小种子。将表面消毒的种子转接至马铃薯葡萄糖琼脂上,随后产生菌核,结果表明,各相应类别种子中分别有2%、44%和6%被核盘菌侵染。从这些类别中各取100粒种子,以每盆5粒种子的播种量种入灭菌和未灭菌土壤中。放置牙签以确定每粒种子的位置,种子上覆盖2厘米厚的土壤。将花盆置于生长室中,在两种温度条件下,光周期为14小时:(i)20℃;(ii)10℃处理10天,然后升至20℃。在前10天通过定期从花盆顶部浇水使土壤保持饱和状态,之后从底部浇水。播种两周后,检查种子是否形成菌核,并计算形成菌核的种子百分比。试验进行了4次。在每粒未发芽的种子位置发现一至两个(偶尔三个)菌核。菌核主要来自劣质种子,平均有12%的种子产生菌核。在正常质量种子中发现菌核的频率为0.4%,在有菌丝层的种子中未发现菌核。菌核宽度为2.36±1.07毫米,长度为3.33±1.11毫米,重量为6.8±3.7毫克,产生8个月后的平均发芽率为88%。温度条件(i)和(ii)下菌核产生频率分别为11.4%和15.4%。在灭菌土壤(15.6%)中发现的菌核产生百分比高于未灭菌土壤(7.5%)。我们的结果表明,带菌大豆种子有可能作为核盘菌在田间传播的一种途径。参考文献:(1)J. C. 图。《植物病理学杂志》121:40,1988年。(2)X. B. 杨。《国际作物管理新闻》18,1997年。
