Effects of Crop Rotation and Irrigation on Verticillium dahliae Microsclerotia in Soil and Wilt in Cauliflower

ABSTRACT Experiments were conducted in field plots to evaluate the effects of broccoli residue on population dynamics of Verticillium dahliae in soil and on Verticillium wilt development on cauliflower under furrow and subsurface-drip irrigation and three irrigation regimes in 1994 and 1995. Treatments were a factorial combination of three main plots (broccoli crop grown, harvested, and residue incorporated in V.dahliae-infested plots; no broccoli crop or residue in infested plots; and fumigated control plots), two subplots (furrow and subsurface-drip irrigation), and three sub-subplots (deficit, moderate, and excessive irrigation regimes) arranged in a split-split-plot design with three replications. Soil samples collected at various times were assayed for V. dahliae propagules using the modified Anderson sampler technique. Incidence and severity of Verticillium wilt on cauliflower were assessed at 7- to 10-day intervals beginning a month after cauliflower transplanting and continuing until harvest. Number of propagules in all broccoli plots declined significantly (P < 0.05) after residue incorporation and continued to decline throughout the cauliflower season. The overall reduction in the number of propagules after two broccoli crops was approximately 94%, in contrast to the fivefold increase in the number of propagules in infested main plots without broccoli after two cauliflower crops. Disease incidence and severity were both reduced approximately 50% (P < 0.05) in broccoli treatments compared with no broccoli treatments. Differences between furrow and subsurface-drip irrigation were not significant, but incidence and severity were significantly (P < 0.05) lower in the deficit irrigation regime compared with the other two regimes. Abundance of microsclerotia of V. dahliae on cauliflower roots about 8 weeks after cauliflower harvest was significantly (P < 0.05) lower in treatments with broccoli compared with treatments without broccoli. Rotating broccoli with cauliflower and incorporating broccoli residues into the soils is a novel means of managing Verticillium wilt on cauliflower and perhaps on other susceptible crops. This practice would be successful regardless of the irrigation methods or regimes followed on the susceptible crops.     

Relationships Between Verticillium dahliae Inoculum Density and Wilt Incidence, Severity, and Growth of Cauliflower

ABSTRACT Microplot and field experiments were conducted to evaluate the effects of inoculum density on Verticillium wilt and cauliflower growth. Soil containing Verticillium dahliae microsclerotia was mixed with various proportions of fumigated soil to establish different inoculum densities (fumigated soil was used as the noninfested control). Seven inoculum density treatments replicated four times were established, and the treatments were arranged in a randomized complete block design. Soil was collected from each microplot immediately after soil infestation for V. dahliae assay by plating onto sodium polypectate agar (NP-10) selective medium using the Anderson sampler technique. Five-week-old cauliflower was transplanted into two beds within each 1.2- by 1.2-m microplot. At the same time, several extra plants were also transplanted at the edge of each bed for destructive sampling to examine the disease onset (vascular discoloration) after planting. Cauliflower plants were monitored for Verticillium wilt development. Stomatal resistance in two visually healthy upper and two lower, diseased leaves in each microplot was measured three times at weekly intervals after initial wilt symptoms occurred. At maturity, all plants were uprooted, washed free of soil, and wilt incidence and severity, plant height, number of leaves, and dry weights of leaves and roots were determined. The higher the inoculum density, the earlier was disease onset. A density of 4 microsclerotia per g of dry soil caused 16% wilt incidence, but about 10 microsclerotia per g of soil caused 50% wilt incidence. Both wilt incidence and severity increased with increasing inoculum density up to about 20 microsclerotia per g of soil, and additional inoculum did not result in significantly higher disease incidence and severity. A negative exponential model described the disease relationships to inoculum levels under both microplot and field conditions. Stomatal resistance of diseased leaves was significantly higher at higher inoculum densities; in healthy leaves, however, no treatment differences occurred. The height, number of leaves, and dry weights of leaves and roots of plants in the fumigated control were significantly higher than in infested treatments, but the effects of inoculum density treatments were variable between years. Timing of cauliflower infection, crop physiological processes related to hydraulic conductance, and wilt intensity (incidence and severity) were thus affected by the inoculum density. Verticillium wilt management methods used in cauliflower should reduce inoculum density to less than four micro-sclerotia per g of soil to produce crops with the fewest number of infected plants.     

Response of Six Potato Cultivars to Amount of Applied Water and Verticillium dahliae

ABSTRACT Six potato cultivars were grown with or without the addition of Verticillium dahliae inoculum and were watered at 50, 75, or 100% estimated consumptive use. The applied water x cultivar interaction was significant (P = 0.009 and P = 0.001 for 1996 and 1997, respectively) for the relative area under the senescence progress curve (RAUSPC). With a decrease in water, there was an increase in RAUSPC. A significant interaction of inoculum density x cultivar also was found, based on RAUSPC (P = 0.0194 and P = 0.0033 for 1996 and 1997, respectively). In V. dahliae-infested plots, 'Katahdin' and 'Ranger Russet' were resistant to Verticillium wilt. Population size of V. dahliae in stem apices was significantly lower in 'Katahdin' in both 1996 and 1997 (P = 0.0001) and in 'Ranger Russet' in 1997 (P = 0.0001) than in the other cultivars. 'Russet Burbank' and 'Shepody' had large apical stem populations of V. dahliae and higher RAUSPC values associated with both V. dahliae inoculum and decreased amount of applied water. Marketable tuber yield was unaffected by V. dahliae in both years. Cultivar resistance to Verticillium wilt was related to cultivar tolerance to moisture deficit stress. Results suggest that moisture deficit stress response has the potential to be a useful tool in protocols for screening potato for Verticillium resistance.     

Phenological and phytochemical changes correlate with differential interactions of Verticillium dahliae with broccoli and cauliflower

Cauliflower (Brassica oleracea var. botrytis subvar. cauliflora) is susceptible to wilt caused by Verticillium dahliae but broccoli (B. oleracea var. italica subvar. cyamosa) is not. Infection of broccoli and cauliflower by a green fluorescent protein-expressing isolate of V. dahliae was examined using epifluorescence and confocal laser-scanning microscopy to follow infection and colonization in relation to plant phenology. Plant glucosinolate, phenolic, and lignin contents were also assayed at 0, 4, 14, and 28 days postinoculation. V. dahliae consistently infected and colonized the vascular tissues of all cauliflower plants regardless of age at inoculation, with the pathogen ultimately appearing in the developing seed; however, colonization decreased with plant age. In broccoli, V. dahliae infected and colonized root and stem xylem tissues of plants inoculated at 1, 2, or 3 weeks postemergence. However, V. dahliae colonized only the root xylem and the epidermal and cortical tissues of broccoli plants inoculated at 4, 5, and 6 weeks postemergence. The frequency of reisolation of V. dahliae from the stems (4 to 22%) and roots (10 to 40%) of mature broccoli plants was lower than for cauliflower stems (25 to 64%) and roots (31 to 71%). The mean level of aliphatic glucosinolates in broccoli roots was 6.18 times higher than in the shoots and did not vary with age, whereas it was 3.65 times higher in cauliflower shoots than in the roots and there was a proportional increase with age. Indole glucosinolate content was identical in both cauliflower and broccoli, and both indole and aromatic glucosinolates did not vary with plant age in either crop. Qualitative differences in characterized glucosinolates were observed between broccoli and cauliflower but no differences were observed between inoculated and noninoculated plants for either broccoli or cauliflower. However, the phenolic and lignin contents were significantly higher in broccoli following inoculation than in noninoculated broccoli or inoculated cauliflower plants. The increased resistance of broccoli to V. dahliae infection was related to the increase in phenolic and lignin contents. Significant differential accumulation of glucosinolates associated with plant phenology may also contribute to the resistant and susceptible reactions of broccoli and cauliflower, respectively, against V. dahliae.     

Mechanism of broccoli-mediated verticillium wilt reduction in cauliflower

ABSTRACT Broccoli is resistant to Verticillium dahliae infection and does not express wilt symptoms. Incorporation of broccoli residues reduces soil populations of V. dahliae. The effects of broccoli residue were tested on the colonization of roots by V. dahliae, plant growth response, and disease incidence of both broccoli and cauliflower in soils with different levels of V. dahliae inoculum and with or without fresh broccoli residue amendments. The three soils included a low-Verticillium soil, a high-Verticillium soil, and a broccoli-rotation soil (soil from a field after two broccoli crops) with an average of 13, 38, and below-detectable levels of microsclerotia per g of soil, respectively. Cauliflower plants in broccoli-amended high-Verticillium soil had significantly (P 相似文献   

Verticillium longisporum and V. dahliae: infection and disease in Brassica napus

Verticillium wilt of oilseed rape ( Brassica napus ) is caused primarily by Verticillium longisporum and has become a serious problem in northern Europe. In order to evaluate whether V. longisporum and V. dahliae differ in their interaction with oilseed rape, phenotypical and molecular assessments were made. Oilseed rape plants for fungal assessments were inoculated with V. longisporum and V. dahliae via root-dipping and samples were taken from roots, stems, leaves, flowers, pods and seeds during plant development. The infection by V. longisporum was found to start mainly in lateral roots and root-hairs, followed by colonization of the xylem vessels and extensive spread in stems and leaves, whereas V. dahliae infected the main roots and remained in the region below the cotyledon node of the plants. Re-isolation studies, together with PCR analysis of samples taken from early growth stages through to fully ripe plants, showed that the onset of flowering was a critical phase for V . longisporum to colonize plants. No seeds infected with V. longisporum were found. Mycelial growth from V. dahliae but not V. longisporum was significantly reduced on media containing tissue from a low glucosinolate B. napus genotype compared with growth on media containing tissue from a high glucosinolate cultivar. The results of this study suggest that V. longisporum favours B. napus as host and that the transition from the vegetative to the generative phase is of importance for the spread of the fungus in oilseed rape plants.     

Host Range Specificity in Verticillium dahliae

ABSTRACT Verticillium dahliae isolates from artichoke, bell pepper, cabbage, cauliflower, chili pepper, cotton, eggplant, lettuce, mint, potato, strawberry, tomato, and watermelon and V. albo-atrum from alfalfa were evaluated for their pathogenicity on all 14 hosts. One-month-old seedlings were inoculated with a spore suspension of about 10(7) conidia per ml using a root-dip technique and incubated in the greenhouse. Disease incidence and severity, plant height, and root and shoot dry weights were recorded 6 weeks after inoculation. Bell pepper, cabbage, cauliflower, cotton, eggplant, and mint isolates exhibited host specificity and differential pathogenicity on other hosts, whereas isolates from artichoke, lettuce, potato, strawberry, tomato, and watermelon did not. Bell pepper was resistant to all Verticillium isolates except isolates from bell pepper and eggplant. Thus, host specificity exists in some isolates of V. dahliae. The same isolates were characterized for vegetative compatibility groups (VCGs) through complementation of nitrate nonutilizing (nit) mutants. Cabbage and cauliflower isolates did not produce nit mutants. The isolate from cotton belonged to VCG 1; isolates from bell pepper, eggplant, potato, and tomato, to VCG 4; and the remaining isolates, to VCG 2. These isolates were also analyzed using the random amplified polymorphic DNA (RAPD) method. Forty random primers were screened, and eighteen of them amplified DNA from Verticillium. Based on RAPD banding patterns, cabbage and cauliflower isolates formed a unique group, distinct from other V. dahliae and V. albo-atrum groups. Minor genetic variations were observed among V. dahliae isolates from other hosts, regardless of whether they were host specific or not. There was no correlation among pathogenicity, VCGs, and RAPD banding patterns. Even though the isolates belonged to different VCGs, they shared similar RAPD profiles. These results suggest that management of Verticillium wilt in some crops through crop rotation is a distinct possibility.     

新疆榆树黄萎病病原菌鉴定

2013年以来,在石河子大学农学院试验站榆树苗上,出现了一种病害,可导致叶片褪绿,变黄,萎蔫,甚至枯死,剖茎检查可见维管束变成褐色。采用常规组织分离法对病茎组织进行分离、纯化获得单孢纯培养菌株;通过常规纸钵撕底蘸根法对其进行致病性测定;用形态学和rDNA-ITS序列分析方法对病原菌进行鉴定。结果表明,分离菌株的菌落形态、分生孢子梗和分生孢子的形态都与大丽轮枝菌(Verticillium dahliae)一致;经分子生物学鉴定,该菌的rDNA-ITS序列与中国棉花黄萎病菌(V.dahliae)的ITS序列(登录号EU 835817.1)相似性达99.0%,故将引起新疆榆树黄萎病的病原菌鉴定为大丽轮枝菌(V.dahliae)。     

Colonization of resistant and susceptible lettuce cultivars by a green fluorescent protein-tagged isolate of Verticillium dahliae

Interactions between lettuce and a green fluorescent protein (GFP)-expressing, race 1 isolate of Verticillium dahliae, were studied to determine infection and colonization of lettuce cultivars resistant and susceptible to Verticillium wilt. The roots of lettuce seedlings were inoculated with a conidial suspension of the GFP-expressing isolate. Colonization was studied with the aid of laser scanning confocal and epi-fluorescence microscopes. Few differences in the initial infection and colonization of lateral roots were observed between resistant and susceptible cultivars. Hyphal colonies formed on root tips and within the root elongation zones by 5 days, leading to the colonization of cortical tissues and penetration of vascular elements regardless of the lettuce cultivar by 2 weeks. By 8 to 10 weeks after inoculation, vascular discoloration developed within the taproot and crown regions of susceptible cultivars well in advance of V. dahliae colonization. Actual foliar wilt coincided with the colonization of the taproot and crown areas and the eruption of mycelia into surrounding cortical tissues. Advance colonization of stems, pedicels, and inflorescence, including developing capitula and mature achenes was observed. Seedborne infection was limited to the maternal tissues of the achene, including the pappus, pericarp, integument, and endosperm; but the embryo was never compromised. Resistant lettuce cultivars remained free of disease symptoms. Furthermore, V. dahliae colonization never progressed beyond infected lateral roots of resistant cultivars. Results indicated that resistance in lettuce may lie with the plant's ability to shed infected lateral roots or to inhibit the systemic progress of the fungus through vascular tissues into the taproot.     

基质中添加西兰花残体对大丽轮枝菌GFP标记菌株在棉花体内扩展的影响

 由大丽轮枝菌引起的棉花黄萎病是一种难以防治的土传病害,西兰花残体还对其有一定的防治作用,防效为62.82%。为解析西兰花残体对棉花黄萎病的防治机制,本研究通过土壤杆菌转化的方法构建了大丽轮枝菌的绿色荧光标记菌株,采用共聚焦显微镜观察标记菌株在添加西兰花残体营养基质中和空白对照营养基质种植的棉花体内的侵染和扩展情况。结果表明构建的标记菌株gfp-wx-1与野生菌株wx-1的生物学特性无显著性差异。同时发现大丽轮枝菌在添加西兰花残体营养基质中棉花体内扩展较慢,具体表现为:在空白营养基质种植的棉花体内,大丽轮枝菌在接种第2 d时就可侵染根尖表层及根内部,第3 d到达茎部维管束,第5 d叶片可观察到少量病原菌,第7 d第一片子叶呈现大量病原菌,后期迅速扩展,叶片出现黄萎病斑;而在营养基质中添加西兰花残体种植的棉花体内,大丽轮枝菌在接种第2 d时就可侵染根尖表层,第3 d侵染根尖内部,第5 d侵染茎部维管束,直到第7 d第一片子叶才出现少量病原菌,后期扩展慢,叶片病斑较少。本研究通过荧光定量PCR方法检测了大丽轮枝菌在两个处理棉花根部定殖情况,结果表明西兰花残体能够显著降低大丽轮枝菌在棉花根部定殖的量。该研究初步明确了西兰花残体对棉花黄萎病的防治机制,为棉花黄萎病的绿色防治提供了一条新的途径。     

基质中添加西兰花残体对大丽轮枝菌GFP标记菌株在棉花体内扩展的影响

 由大丽轮枝菌引起的棉花黄萎病是一种难以防治的土传病害,西兰花残体还对其有一定的防治作用,防效为62.82%。为解析西兰花残体对棉花黄萎病的防治机制,本研究通过土壤杆菌转化的方法构建了大丽轮枝菌的绿色荧光标记菌株,采用共聚焦显微镜观察标记菌株在添加西兰花残体营养基质中和空白对照营养基质种植的棉花体内的侵染和扩展情况。结果表明构建的标记菌株gfp-wx-1与野生菌株wx-1的生物学特性无显著性差异。同时发现大丽轮枝菌在添加西兰花残体营养基质中棉花体内扩展较慢,具体表现为:在空白营养基质种植的棉花体内,大丽轮枝菌在接种第2 d时就可侵染根尖表层及根内部,第3 d到达茎部维管束,第5 d叶片可观察到少量病原菌,第7 d第一片子叶呈现大量病原菌,后期迅速扩展,叶片出现黄萎病斑;而在营养基质中添加西兰花残体种植的棉花体内,大丽轮枝菌在接种第2 d时就可侵染根尖表层,第3 d侵染根尖内部,第5 d侵染茎部维管束,直到第7 d第一片子叶才出现少量病原菌,后期扩展慢,叶片病斑较少。本研究通过荧光定量PCR方法检测了大丽轮枝菌在两个处理棉花根部定殖情况,结果表明西兰花残体能够显著降低大丽轮枝菌在棉花根部定殖的量。该研究初步明确了西兰花残体对棉花黄萎病的防治机制,为棉花黄萎病的绿色防治提供了一条新的途径。     

北疆棉花黄萎病发病率调查及土壤中黄萎病菌微菌核数量与种群类型分析

为了解北疆棉花黄萎病的发生情况及发病与土壤中黄萎病菌微菌核数量的关系和病原菌种群类型, 2021年对北疆石河子?奎屯?博乐等8市(县)棉田棉花黄萎病发病率?土壤中黄萎病菌的微菌核数量?菌株种群类型进行了抽样调查?结果表明, 北疆未发生棉花黄萎病的棉田占49.2%, 0%<发病率<5.0%的棉田占32.7%, 发病率≥5.0%的棉田占18%?与2013年?2015年相比, 2021年无病田率分别增加17.7和12.7百分点, 发病率≥5%的棉田分别减少15.7和21.6百分点?从棉田黄萎病发病率与土壤中微菌核数量的关系来看, 整体上北疆棉田棉花黄萎病发病率与微菌核数量相关性不显著(r=0.119 1); 分区域看, 石河子-沙湾片区?奎屯-乌苏片区?精河-博乐片区棉田黄萎病发病率与微菌核数量的相关系数分别为0.033 2?0.007 6?0.062 3, 均无显著相关性; 而呼图壁-玛纳斯片区棉田黄萎病发病率与微菌核数量的相关系数为0.635 7, 呈中度正相关?土壤中的黄萎病菌菌株以菌核型为主, 占57.9%, 菌丝型占23.2%, 中间型占18.9%?用特异性引物进行PCR检测表明, 土壤中黄萎病菌落叶型菌株占97.6%, 占绝对优势?本研究将为北疆棉区棉花黄萎病的综合防控提供理论依据?     

Verticillium longisporum and Fusarium solani: two new species in the complex of internal discoloration of horseradish roots

This study was conducted to determine the causal agent(s) of internal discoloration of horseradish roots. In 1999, 133 roots from 31 fields, and in 2000, 108 roots from nine fields, were assayed to determine the incidence and severity of internal discoloration of horseradish roots as well as the pathogen(s) associated with discoloured tissue. Verticillium dahliae , Verticillium longisporum and Fusarium solani were isolated from 14, 16 and 23% of roots in 1999, and from 24, 20 and 19% of roots in 2000, respectively. Verticillium longisporum on horseradish was identified for the first time. Pathogenicity tests of isolated microorganisms were conducted on horseradish in the glasshouse. In one experiment on the susceptible cultivar 1573, roots (sets) were inoculated by dipping the sets in a suspension of either V. dahliae microsclerotia, V. longisporum microsclerotia, or F. solani conidia and then grown in a soil mix over 5 months. Plants inoculated with any of the three species developed root discoloration similar to that observed in commercial fields. Internal root discoloration symptoms developed over a period of 5 months. For all three pathogens, severity of root discoloration was significantly higher after 5 months compared with 2 months from inoculation. In another experiment on cultivar 1590, tissue culture-generated seedlings and sets were planted in an infested soil mix with V. dahliae or V. longisporum and grown in the glasshouse. Plants developed root discoloration, as observed in the field. The pathogens were reisolated from inoculated plants in both experiments. No pathogen was isolated from the control plants in the experiments. The results of this study suggest that internal discoloration of horseradish roots is a disease complex caused by at least three fungal species.     

棉花组织结构与黄萎病抗性的关系

 黄萎病严重危害棉花生产。本试验以温室种植31 个不同抗性的棉花品种为材料,通过对供试品种的组织结构研究,使用根系扫描法和石蜡切片法,了解棉花对黄萎病的抗性机制。结果如下:棉花根系的吸收根根长密度与相对病指呈显著正相关,相关系数为0. 923;抗病品种与耐病品种、感病品种的总长度、总投影面积、总表面积和吸收根根长密度差异显著,但耐病品种与感病品种的这4 个指标差异不显著。抗病材料根、茎的组织中薄层细胞密度大于感病材料,耐病品种根、茎的薄层细胞密度介于两者之间;抗病品种的根和茎的导管数最多,导管直径最小,其次是耐病品种,感病品种的根和茎中导管数最少,但是导管直径最大。棉花根系的吸收根根长密度,根和茎的薄层细胞密度,导管数可以作为对黄萎病抗性的检测指标。     

A real-time PCR assay for detection and quantification of Verticillium dahliae in spinach seed

Verticillium dahliae is a soilborne fungus that causes Verticillium wilt on multiple crops in central coastal California. Although spinach crops grown in this region for fresh and processing commercial production do not display Verticillium wilt symptoms, spinach seeds produced in the United States or Europe are commonly infected with V. dahliae. Planting of the infected seed increases the soil inoculum density and may introduce exotic strains that contribute to Verticillium wilt epidemics on lettuce and other crops grown in rotation with spinach. A sensitive, rapid, and reliable method for quantification of V. dahliae in spinach seed may help identify highly infected lots, curtail their planting, and minimize the spread of exotic strains via spinach seed. In this study, a quantitative real-time polymerase chain reaction (qPCR) assay was optimized and employed for detection and quantification of V. dahliae in spinach germplasm and 15 commercial spinach seed lots. The assay used a previously reported V. dahliae-specific primer pair (VertBt-F and VertBt-R) and an analytical mill for grinding tough spinach seed for DNA extraction. The assay enabled reliable quantification of V. dahliae in spinach seed, with a sensitivity limit of ≈1 infected seed per 100 (1.3% infection in a seed lot). The quantification was highly reproducible between replicate samples of a seed lot and in different real-time PCR instruments. When tested on commercial seed lots, a pathogen DNA content corresponding to a quantification cycle value of ≥31 corresponded with a percent seed infection of ≤1.3%. The assay is useful in qualitatively assessing seed lots for V. dahliae infection levels, and the results of the assay can be helpful to guide decisions on whether to apply seed treatments.     

Long-term effect of soil solarization in controlling verticillium wilt of globe artichokes in Greece

Soil solarization, either singly or in combination with a reduced dosage (34 g/m²) of methyl bromide, was effective in controlling verticillium wilt of globe artichokes for three successive cropping seasons. Both treatments resulted in greatly reduced natural populations of Verticillium dahliae microsclerotia, which were positively correlated with significant reductions in diseased plants as well as with the early formation of primary artichoke heads and increased yield. Propagules of Talaromyces flavus increased and survived better in solarized than in solarized and fumigated soils and could be partially involved in the effectiveness of solarization. Propagules of Aspergillus terreus invariably increased in treated plots but their involvement in the longevity of the treatment is questionable.     

Interactive Effects of Two Soilborne Pathogens, Phytophthora capsici and Verticillium dahliae, on Chile Pepper

ABSTRACT Phytophthora capsici and Verticillium dahliae are two mycelial microorganisms associated with wilt symptoms on chile pepper (Capsicum annuum). Both pathogens occur in the same field and can infect a single plant. This study examined the nature of the co-occurrence of P. capsici and V. dahliae. Chile pepper plants were inoculated with each pathogen separately or with both pathogens concomitantly or sequentially. In concomitant inoculations, plants were inoculated with a mixture of zoospores of P. capsici and conidia of V. dahliae. In sequential inoculations, plants were inoculated with zoospores of P. capsici 4 days prior to inoculation with conidia of V. dahliae, or plants were inoculated with conidia of V. dahliae 4 days prior to inoculation with zoospores of P. capsici. Stem necrosis and leaf wilting were visible 3 to 4 days earlier in plants inoculated with both P. capsici and V. dahliae than in plants inoculated with P. capsici alone. Stem necrosis and generalized plant wilting were observed in plants inoculated with P. capsici alone, and stem necrosis, generalized plant wilting, and vascular discoloration were observed in plants inoculated with both P. capsici and V. dahliae by 21 days after inoculation. These symptoms were not observed in control plants or plants inoculated with V. dahliae alone. The frequency of recovery of V. dahliae from stems was approximately 85 to 140% higher across inoculum levels when plants were inoculated with both P. capsici and V. dahliae than when plants were inoculated by V. dahliae alone. Similarly, the frequency of recovery of V. dahliae from roots was approximately 13 to 40% higher across inoculum levels when plants were inoculated with both P. capsici and V. dahliae than when plants were inoculated by V. dahliae alone. There was no apparent antagonism between the two pathogens when they were paired on growth media. In general, when P. capsici and V. dahliae were paired on growth media, mycelial growth of each pathogen grown alone was not significantly different from mycelial growth when the pathogens were paired. Results suggest that wilt development is hastened by the presence of both P. capsici and V. dahliae in the same plants. The presence of P. capsici and V. dahliae in the same inoculum court enhanced infection and colonization of chile pepper by V. dahliae.     

一种新的棉花黄萎病快速接种技术及其在病原菌致病力和寄主抗病性鉴定上的应用

 棉花品种抗黄萎病鉴定一般在田间病圃中进行,其结果受病圃中病原菌分布均匀程度、气象等因素影响极大,往往导致鉴定结果不准确。为了使鉴定方法简单、科学、可靠,我们在温室条件下比较了3种苗期接种棉花黄萎病的方法,即切根蘸孢子法(接种浓度为10⁶分生孢子/mL);菌培养物土壤接种法(0.5%、1%、2%,w/w);微菌核土壤接种法(10³个微菌核/g土)。结果表明,切根蘸孢子法导致棉苗发病均匀、严重、迅速,播种35~45 d后即可得到均匀一致的发病结果。而其它2种接种方法在播种75 d后才得到相对稳定的发病结果。同时,研究还表明接种浓度为10⁴分生孢子/mL所导致的黄萎病显著比10⁵或10⁶的轻。利用切根蘸孢子法在室内鉴定12个棉花品种或品系的抗黄萎病能力,证明该方法是抗黄萎病快速鉴定的有效方法。此外,该鉴定方法还可快速鉴定黄萎病菌不同菌株的致病性,并可应用于作物对其它土传病害的抗病性鉴定上。     

土壤大丽轮枝菌微菌核的快速定量检测

 微菌核是大丽轮枝菌在土壤中的主要存活结构和黄萎病的初侵染来源。对土壤中大丽轮枝菌微菌核进行定量是黄萎病监测和预警的基础。本研究以大丽轮枝菌Internal Transcribed Spacer (ITS)区特异性引物对P1/P2扩增产物的重组质粒为标准品,构建SYBR Green I实时荧光定量PCR反应的标准曲线,结合土样水筛法建立了土壤大丽轮枝菌微菌核定量检测体系。同时,建立了土壤中微菌核数量与棉花黄萎病发病率的关系模型。结果表明,实时定量PCR检测灵敏度比常规PCR高10倍,检测下限为1个微菌核/克土,在5.54×10²～5.54×10⁷copies范围内,DNA拷贝数的对数值与Ct值具有良好的线性关系。建立的土壤中微菌核个数n与Ct值之间的关系为n=e^7.3-Ct/3.905。温室人工接种微菌核数量与棉花黄萎病发病率间的线性关系为y=2.710n+0.251。     

Dry mycelium of<Emphasis Type="Italic">Penicillium chrysogenum</Emphasis> induces resistance against verticillium wilt and enhances growth of cotton plants

Dry mycelium (DM) ofPenicillium chrysogenum and its water extract (DME) were examined for their effects on induced resistance against Verticillium wilt and plant growth of cotton in the greenhouse. Soil application of 0.1–5% DM or 0.5–5% DME provided significant protection against the wilt, relative to the control. As neither DM nor DME inhibited mycelial growth ofVerticillium dahliae in vitro, it is suggested that the disease-controlling effects of DM or DME are attributed to induced resistance. DME (5%), as well as DME treated with chloroform or cold acetone, were as effective as 2% DM in reducing disease severity of Verticillium wilt, implying that the resistance-inducing substance(s) in DM are mostly water-soluble, with neither proteins nor lipids likely to be responsible for the induction of resistance. No significant difference in root colonization withV. dahliae was found between control-inoculated and 2% DM- or 5% DME-inoculated plants. However, colonization of hypocotyls and epicotyls was drastically suppressed by either 2% DM or 5% DME relative to the control. Treatments with 2% DM or 5% DME significantly increased ionically-bound peroxidase (POX) activity in roots, hypocotyls and the second leaf of cotton plants, with the hypocotyls expressing the highest increase. Soil application of DM or DME increased plant height, fresh and dry weight of inoculated and non-inoculated cotton plants, relative to their corresponding controls. It is concluded that DM may be used in cotton crops to promote plant growth and to induce resistance againstV. dahliae. POX might be associated with the defense against Verticillium wilt. http://www.phytoparasitica.org posting Jan. 9, 2002.