Sudden death syndrome of soybean in South America is caused by four species of Fusarium: Fusarium brasiliense sp. nov., F. cuneirostrum sp. nov., F. tucumaniae, and F. virguliforme

Soybean sudden death syndrome (SDS) pathogens and dry bean root-rot pathogens were studied taxonomically, phylogenetically, and pathologically. Detailed phenotypic comparisons of macro- and microscopic features and phylogenetic analyses of multilocus DNA sequence data, including those on the nuclear ribosomal intergenic spacer region and the single copy nuclear gene translation elongation factor 1-a, indicated that they comprised five distinct species of Fusarium. Two new species causing soybean SDS in Brazil, F. brasiliense and F. cuneirostrum, are formally described. Fusarium cuneirostrum is responsible for soybean SDS in Brazil and dry bean or mung bean root-rot in the United States, Canada, and Japan. Strains of each species, including F. cuneirostrum isolates from dry bean and mung bean and F. phaseoli isolates from dry bean, were inoculated on soybean cultivar Pioneer 9492RR to determine their pathogenicity. Although intraspecific variation in pathogenicity was observed, all the species were able to induce typical SDS symptoms on soybean plants in the artificial inoculation tests. Comparisons of the key diagnostic morphological features reveal that all five species can be diagnosed using conidial morphology.     

Viability staining of soybean suspension-cultured cells and a seedling stem cutting assay to evaluate phytotoxicity of Fusarium solani f. sp. glycines culture filtrates

The phytotoxicity of culture filtrates of Fusarium solani f. sp. glycines, the fungus causing sudden death syndrome (SDS) of soybean (Glycine max), was tested with a viability stain of soybean suspension-cultured cells and a stem cutting assay of soybean seedlings. Suspension-cultured cells from a SDS-susceptible soybean cultivar were exposed to cell-free culture filtrates of F. solani f. sp. glycines or other F. solani isolates for 2, 4, 6, and 8 days and then stained with 0.1% phenosafranin. The percentage of dead soybean suspension-cultured cells was greater (P<0.001) with filtrates prepared from F. solani f. sp. glycines than from other F. solani isolates, and dead cells increased over time and with higher concentrations of culture filtrate. Cuttings of soybean seedlings with their stems immersed in culture filtrates of F. solani f. sp. glycines isolates developed SDS-like foliar symptoms, but not when immersed in filtrates of other isolates. There was a positive correlation (r=0.94, P<0.001) between soybean foliar symptom severity and percentage of stained soybean suspension-cultured cells. Both methods were used to determine the phytotoxicity of fungal culture filtrates. Received: 9 December 1997 / Revision received: 10 August 1998 / Accepted: 28 August 1998     

Pathogenicity of Fusarium solani f. sp. glycines Isolates on Soybean and Green Bean Plants

Green bean plants were grown in a greenhouse in soil removed from a soybean field in 1996 that had a high incidence of soybean sudden death syndrome (SDS). Over a period of 4 weeks, isolations were made from taproot tissue of green bean plants to recover Fusarium isolates. Ten isolates of Fusarium solani were recovered and used to inoculate soybean and green bean plants in the greenhouse. These 10 isolates caused typical SDS symptoms on the soybean plants and caused a root and crown rot on green bean plants. The green bean plants did not develop typical symptoms associated with soybean SDS but, rather, leaves on infected plants showed yellowing and necrosis. Molecular data indicated that these 10 isolates were identical to Fusarium solani f. sp. glycines that cause soybean sudden death syndrome. All isolates were re-isolated from greenhouse-inoculated soybean and green bean plants.     

Study of Genetic Variability Among Monopycnidial and Monopycnidiospore Isolates Derived from Single Pycnidia of Stagonospora ssp. and Septoria tritici with the use of RAPD-PCR, MP-PCR and rep-PCR Techniques

Thirty-six isolates of Stagonospora avenae f. sp. triticea, S. nodorum and Septoria tritici recovered from asexual fruiting bodies - pycnidia and their spores were assessed for DNA polymorphism with the use of three molecular techniques: microsatellite-primed polymerase chain reaction (MP-PCR), primers correspond to dispersed repetitive elements (rep-PCR) and random amplified polymorphic DNA (RAPD-PCR). These polymerase chain reaction (PCR)-based techniques were simultaneously evaluated for their capacity to detect genetic variation at DNA level. The most polymorphic DNA profiles of monopycnidial and monopycnidiospore isolates were detected with diverse microsatellite motifs used for PCR priming. The lowest similarity values 0.86, 0.76 and 0.84 were identified among monopycnidiospore isolates derived from the same pycnidium of S. avenae f. sp. triticea, S. nodorum and S. tritici, respectively. The above, rather low similarities, found for isolates recovered from single pycnidia, supported a hypothesis that heterokaryosis resulted from high mutation rate of microsatellites and transposons activity. This would have fundamental consequences for the genetic status of asexual populations of Stagonospora spp. and S. tritici. The data produced by this study indicate that more attention should be paid to asexual reproduction as a possible source of genetic variability among populations of the pathogens.     

Characterization of Fusarium oxysporum Isolates from Common Bean and Sugar Beet Using Pathogenicity Assays and Random-amplified Polymorphic DNA Markers

Fusarium wilt is an economically important fungal disease of common bean and sugar beet in the Central High Plains (CHP) region of the USA, with yield losses approaching 30% under appropriate environmental conditions. The objective of this study was to characterize genetic diversity and pathogenicity of isolates of Fusarium oxysporum obtained from common bean and sugar beet plants in the CHP that exhibited Fusarium wilt symptoms. A total of 166 isolates of F. oxysporum isolated from diseased common bean plants were screened for pathogenicity on the universal susceptible common bean cultivar ‘UI 114’. Only four of 166 isolates were pathogenic and were designated F. oxysporum f.sp. phaseoli (Fop). A set of 34 isolates, including pathogenic Fop, F. oxysporum f.sp. betae (Fob) isolates pathogenic on sugar beet, and non‐pathogenic (Fo) isolates, were selected for random‐amplified polymorphic DNA (RAPD) analysis. A total of 12 RAPD primers, which generated 105 polymorphic bands, were used to construct an unweighted paired group method with arithmetic averages dendrogram based on Jaccard's coefficient of similarity. All CHP Fop isolates had identical RAPD banding patterns, suggesting low genetic diversity for Fop in this region. CHP Fob isolates showed a greater degree of diversity, but in general clustered together in a grouping distinct from Fop isolates. As RAPD markers revealed such a high level of genetic diversity across all isolates examined, we conclude that RAPD markers had only limited usefulness in correlating pathogenicity among the isolates and races in this study.     

Metabolism of the phytoalexins medicarpin and maackiain by Fusarium solani

Non-inhibitory concentrations of the pterocarpan phytoalexin medicarpin were completely metabolized by isolates of Fusarium solani f. sp. pisi, f. sp. cucurbitae, f. sp. phaseoli and two other F. solani isolates genetically related to f. sp. pisi during 24 hr of growth in liquid medium. The major metabolic products accumulated without significant further degradation. Medicarpin was modified at one of three adjacent carbon atoms to form either an isoflavanone derivative, a 1a-hydroxydienone derivative or 6a-hydroxymedicarpin. Whereas each isolate degraded medicarpin to one or more metabolises, the isolates varied as to which metabolise they produced. Maackiain, another pterocarpan phytoalexin, was also metabolized by all the isolates to products analogous to those formed from medicarpin. The ability to metabolize medicarpin and maackiain was not always associated with the ability to metabolize pisatin and phaseollin, two other pterocarpan phytoalexins that were degraded by several of the isolates. Tolerance of medicarpin and maackiain was similarly not always associated with tolerance to pisatin.     

Molecular characterization of Rhizoctonia solani isolates the incitant of soybean root rot

Rhizoctonia solani isolates used in this investigation were identified as anastomosis-4 (AG-40), collected from different localities from Assiut governorate in Egypt. Pathogenicity test of seven isolates of R. solani was evaluated on soybean Giza 111 cultivar under greenhouse conditions. All tested isolates were able to infect soybean plants causing root rot with different degrees of severities, isolate No. 1, 2 and 3 showed significantly highest root rot severity, while isolate No. 5 gave the lowest percentage of root rot rating. The sodium dodecyl sulphate polyacrylamide gel electrophoresis patterns were used to compare three isolates of R. solani. There are no variations among R. solani isolates except a few exceptions according to their protein patterns. DNA markers obtained from all isolates showed genetic similarity among different isolates obtained from different geographical regions barring few exceptions. Correlation between DNA patterns of R. solani isolates and their virulence was detected, but no correlation with anastomosis groups (AG).     

Genetic Structure and Aggressiveness of Rhizoctonia solani AG1‐IA,the Cause of Sheath Blight of Rice in Southern China

One hundred and eighty isolates of Rhizoctonia solani AG1‐IA, the causal agent of rice sheath blight, were obtained from six locations in southern China. The genetic structure of R. solani isolates was investigated using random amplified polymorphic DNA (RAPD) markers, and a considerable genetic variation among R. solani isolates was observed. Most of the genetic diversity was distributed within populations, rather than among them. The distribution pattern of the genetic variation of R. solani appears to be the result of high gene flow (Nm) and low‐genetic differentiation among populations. The aggressiveness of R. solani was visually assessed by rice seedlings of five different cultivars in the glasshouse. All isolates tested were found to induce significantly different levels of disease severity, reflecting considerable variation in aggressiveness. The isolates were divided into highly virulent, moderately virulent and weakly virulent groups, and the moderately virulent isolates were dominant in R. solani population. No significant correlation was observed among the genetic similarity, pathogenic aggressiveness and geographical origins of the isolates. Information obtained from this study may be useful for breeding for improved resistance to sheath blight.     

Developmental Regulation of Susceptibility and Tolerance to Fusarium Root Rot in Beans

The soil-borne fungus, Fusarium solani f. sp. phaseoli, attacks roots and hypocotyls of bean (Phaseolus vulgaris) plants causing a devastating disease called root and foot rot. In a study of the host-pathogen relationship it was found that young bean roots, with the radicle just emerging, were highly tolerant to the pathogen, whereas older bean seedlings, with a fully developed root system, were completely susceptible. Investigations by low-temperature scanning electron microscopy demonstrated that significantly fewer spores and hyphae were present on the root surface of young bean seedlings as compared to older ones. A similar pattern of attachment was found when bean roots were inoculated with spores of F. solani f. sp. pisi, a related pathogen causing disease on peas but not on beans. Light microscopic studies showed that F. solani f. sp. pisi did not penetrate the root but rapidly formed thick-walled resting spores on the root surface. F. solani f. sp. phaseoli on the other hand quickly penetrated the root and formed an extensive network of fungal hyphae. These results demonstrate that the ability of fungal propagules to adhere to and to penetrate host tissues are two distinct processes. Furthermore, the data indicate that young bean roots lack a surface component necessary for attachment of fungal spores which may help explain their tolerance to Fusarium root rot.     

Microsatellite marker-based detection of Fusarium wilt pathogens of Psidium guajava L.

Wilt of Psidium guajava L., incited by Fusarium oxysporum f. sp. psidii and Fusarium solani is a serious soil-borne disease of guava in India. Forty-two isolates each of F. oxysporum f. sp. psidii (Fop) and F. solani (Fs) collected from different agro climatic zones of India showing pathogenicity were subjected to estimate the genetic and molecular characterisation in terms of analysis of microsatellite marker studies. Out of eight microsatellite markers, only four microsatellite markers, viz. MB 13, MB 17, RE 102 and AY212027 were amplified with single band pattern showing the character of identical marker for molecular characterisation and genetic identification. Microsatellite marker MB 13 was amplified in F. oxysporum f. sp. psidii and F. solani isolates. Product size of 296 bps and 1018 bps were exactly amplified with a single banding pattern in all the isolates of F. oxysporum f. sp. psidii and F. solani, respectively. Microsatellite markers, viz. MB 17, RE 102 and AY212027 were also exactly amplified with a single banding pattern. MB 17 was amplified in F. oxysporum f. sp. psidii isolates with a product size of 300 bp. RE 102 and AY212027 were amplified in F. solani isolates with the product size of 153 bp and 300 bp, respectively. Therefore, amplified microsatellite marker may be used as identifying DNA marker.     

Use of RAPD and ISSR Markers in Detection of Genetic Variation and Population Structure among Fusarium oxysporum f. sp. ciceris Isolates on Chickpea in Turkey

Genetic variation among the isolates of Fusarium oxysporum f. sp. ciceris, the causal agent of chickpea wilt worldwide, was analysed using pathogenicity tests and molecular markers – random amplified polymorphic DNA (RAPD) and inter‐simple sequence repeat (ISSR) polymorphism. Hundred and eight isolates were obtained from diseased chickpea plants in 13 different provinces of Turkey, out of which 74 isolates were assessed using 30 arbitrary decamer primers and 20 ISSR primers. Unweighted pair‐grouped method by arithmetic average cluster analysis of RAPD, ISSR and RAPD + ISSR datasets provided a substantially similar discrimination among Turkish isolates and divided into three major groups. Group 1, 2 and 3 consisted of 41, 18 and 15 isolates, respectively. These methods revealed a considerable genetic variation among Turkish isolates, but no correlation with regard to the clustering of isolates from different geographic regions. Analysis of molecular variance confirmed that most genetic variability resulted from the differences among isolates within regions. Our results also indicated that the low‐genetic differentiation (F_ST) and high gene flow (Nm) among populations had a significant effect on the emergence and evolutionary development of F. oxysporum f. sp. ciceris. This is the first report on genetic diversity and population structure of F. oxysporum isolates on chickpea in Turkey.     

Pea saponins in the pea-Fusarium solani interaction

Saponin-like compounds isolated fromPisum sativum were tested for antifungal activity, effect on pea tissue, and effect on chitin and chitosan synthesis inFusarium solani. Growth ofFusarium solani f. sp.phaseoli and f. sp.pisi macroconidia was inhibited by saponins at concentrations of 150 and 300 μg/ml, respectively. Pod endocarp tissue treated with saponins showed temporary reduction in cell viability (esterase activity); however, there was no significant reduction in resistance toF. solani f. sp.phaseoli, normally incompatible on peas. Macroconidia germinated in the presence of saponin showed decreased incorporation ofN-[³H]acetylglucosamine into chitin and chitosan at concentrations as low as 32 μg/ml. Thus, a reduction in chitin and chitosan synthesis may be associated with inhibition of fungal growth. Saponins may contribute to the disease resistance of peas     

Identification of Cyst Nematodes of Agronomic and Regulatory Concern with PCR-RFLP of ITS1

The first internally transcribed spacer region (ITS1) from cyst nematode species (Heteroderidae) was compared by nucleotide sequencing and PCR-RFLP. European, Asian, and North American isolates of five heterodefid species were examined to assess intraspecific variation. PCR-RFLP patterns of amplified ITS1 DNA from pea cyst nematode, Heterodera goettingiana, from Northern Ireland were identical with patterns from Washington State. Sequencing demonstrated that ITS1 heterogeneity existed within individuals and between isolates, but did not result in different restriction patterns. Three Indian and two U.S. isolates of the corn cyst nematode, Heterodera zeae, were compared. Sequencing detected variation among ITS1 clones from the same individual, between individuals, and between isolates. PCR-RFLP detected several restriction site differences between Indian and U.S. isolates. The basis for the restriction site differences between isolates from India and the U.S. appeared to be the result of additional, variant ITS1 regions amplified from the U.S. isolates, which were not found in the three India isolates. PCR-RFLP from individuals of the U.S. isolates created a composite pattern derived from several ITS1 types. A second primer set was specifically designed to permit discrimination between soybean (H. glycines) and sugar beet (H. schachtii) cyst nematodes. Fok I digestion of amplified product from soybean cyst nematode isolates displayed a uniform pattern, readily discernible from the pattern of sugar beet and clover cyst nematode (H. trifolii).     

Genetic Diversity of Fusarium oxysporum Strains from Common Bean Fields in Spain

Fusarium wilt is an endemic disease in El Barco de Avila (Castilla y León, west-central Spain), where high-quality common bean cultivars have been cultured for the last century. We used intergenic spacer (IGS) region polymorphism of ribosomal DNA, electrophoretic karyotype patterns, and vegetative compatibility and pathogenicity analyses to assess the genetic diversity within Fusarium oxysporum isolates recovered from common bean plants growing in fields around El Barco de Avila. Ninety-six vegetative compatibility groups (VCGs) were found among 128 isolates analyzed; most of these VCGs contained only a single isolate. The strains belonging to pathogenic VCGs and the most abundant nonpathogenic VCGs were further examined for polymorphisms in the IGS region and electrophoretic karyotype patterns. Isolates belonging to the same VCG exhibited the same IGS haplotype and very similar electrophoretic karyotype patterns. These findings are consistent with the hypothesis that VCGs represent clonal lineages that rarely, if ever, reproduce sexually. The F. oxysporum f. sp. phaseoli strains recovered had the same IGS haplotype and similar electrophoretic karyotype patterns, different from those found for F. oxysporum f. sp. phaseoli from the Americas, and were assigned to three new VCGs (VCGs 0166, 0167, and 0168). Based on our results, we do not consider the strains belonging to F. oxysporum f. sp. phaseoli to be a monophyletic group within F. oxysporum, as there is no correlation between pathogenicity and VCG, IGS restriction fragment length polymorphism, or electrophoretic karyotype.     

Molecular cloning and characterization of a pea chitinase gene expressed in response to wounding,fungal infection and the elicitor chitosan

The fungicidal class I endochitinases (E.C.3.3.1.14, chitinase) are associated with the biochemical defense of plants against potential pathogens. We isolated and sequenced a genomic clone, DAH53, corresponding to a class I basic endochitinase gene in pea, Chil. The predicted amino acid sequence of this chitinase contains a hydrophobic C-terminal domain similar to the vacuole targeting sequences of class I chitinases isolated from other plants. The pea genome contains one gene corresponding to the chitinase DAH53 probe. Chitinase RNA accumulation was observed in pea pods within 2 to 4 h after inoculation with the incompatible fungal strain Fusarium solani f. sp. phaseoli, the compatible strain F. solani f.sp. pisi, or the elicitor chitosan. The RNA accumulation was high in the basal region (lower stem and root) of both fungus challenged and wounded pea seedlings. The sustained high levels of chitinase mRNA expression may contribute to later stages of pea's non-host resistance.     

Chitosan as a Component of Pea-Fusarium solani Interactions

Chitosan, a polymer of β-1,4-linked glucosamine residues with a strong affinity for DNA, was implicated in the pea pod-Fusarium solani interaction as an elicitor of phytoalexin production, an inhibitor of fungal growth and a chemical which can protect pea tissue from infection by F. solani f. sp. pisi. Purified Fusarium fungal cell walls can elicit phytoalexin production in pea pod tissue. Enzymes from acetone powders of pea tissue release eliciting components from the F. solani f. sp. phaseoli cell walls. Hydrochloric acid-hydrolyzed F. solani cell walls are about 20% glucosamine. The actual chitosan content of F. solani cell walls is about 1%. However, chitosan assays and histochemical observations indicate that chitosan content of F. solani spores and adjacent pea cells increases following inoculation. Dormant F. solani spores also accumulate chitosan. Concentrations of nitrous acid-cleaved chitosan as low as 0.9 microgram per milliliter and 3 micrograms per milliliter elicit phytoalexin induction and inhibit germination of F. solani macroconidia, respectively. When chitosan is applied to pea pod tissue with or prior to F. solani f. sp. pisi, the tissue is protected from infection.     

Identification of 1 a-hydroxy phaseollone,a phaseollin metabolite produced by Fusarium solani

A structure for the phaseollin metabolite of Fusarium solani f. sp phaseoli has been proposed and assigned the name 1 a-hydroxyphaseollone.     

Clustering among loci underlying soybean resistance to Fusarium solani, SDS and SCN in near-isogenic lines

In the soybean [Glycine max (L.) Merr.] cultivar ’Forrest’ a single chromosomal region underlies co-inheritance of field resistance of the sudden-death syndrome (SDS), caused by the fungus Fusarium solani (Mart.) Sacc. f. sp. glycines (Burk.) Snyd. & Hans. and soybean cyst nematode (SCN) race 3 (caused by Heterodera glycines Ichinohe). Our objectives were to verify that co-inheritance was derived from a single chromosomal region in near-isogenic lines and to separate component gene clusters. DNA markers were compared with a SDS leaf-scorch index (DX), F. solani root-infection severity (IS) and a SCN index of parasitism (IP) among 80 near-isogenic lines (NILs). The genomic region identified by the RFLP marker Bng122D was strongly associated (0.0004 ≤P≤ 0.006) with mean SDS DX (R ² > 16–38%) and IS (R ² > 38–73%), but only marginally associated with resistance to SCN. However, the linked (4.3–7.4 cM) microsatellite marker SATT309 was strongly associated with both resistance to SCN (0.0001 ≤P≤ 0.0003; R ² > 24–97%) and mean leaf DX (0.0001 ≤P≤ 0.0003; R ² > 25–63%), but not root IS. Recombination events among markers and traits enabled separation of the qualitative loci underlying resistance to SDS and SCN. Our data showed that resistance to SDS DX, SDS IS and SCN IP in Forrest may be caused by four genes in a cluster with two pairs in close linkage or by a two-gene cluster with each gene displaying pleiotropy, one conditioning SDS IS and DX and the other SCN IP and SDS DX. Received: 22 September 1998 / Accepted: 12 May 1999     

Race Differentiation in Fusarium oxysporum f.sp. chrysanthemi

The pathogenicity of different isolates of Fusarium oxysporum obtained from plants of Gerbera (Gerbera jamesonii), Chrysanthemum (Chrysanthemum morifolium), Paris daisy (Argyranthemum frutescens) and African daisy (Osteospermum sp.), all in the family Asteraceae, was tested on different cultivars of these hosts, to assess their pathogenicity. The reactions were compared with those of isolates of F. oxysporum f. sp. chrysanthemi and of f.sp. tracheiphilum obtained from the American Type Culture Collection. We found that isolates of F. oxysporum f. sp. chrysanthemi can be distinguished as three physiological races on the basis of their pathogenicity to the panel of differential cultivars. Sequencing of the intergenic spacer (IGS) region of ribosomal DNA (rDNA) and phylogenetic analysis showed that the Fusarium races fell into three phylogenetic groups, which coincided with those observed in pathogenicity tests. Analysis of the IGS sequences revealed a high degree of similarity among strains from Italy and Spain from different host species, suggesting that recent outbreaks in these ornamentals were probably caused by introduction of infected nursery material from a common origin.     

黑龙江省大豆菌核病菌核盘菌遗传多样性分析

了解黑龙江省不同地区侵染大豆核盘菌菌株分离物间的主要特性差异,利用PDA培养基对核盘菌进行分离和纯化,同时利用RAPD和rDNA-ITS标记方法对核盘菌进行遗传多样性分析,获得了50株纯化的核盘菌,用RAPD标记确定的遗传相似系数范围为0.54-0.98,平均相似系数为0.76,说明供试的核盘菌菌株的基因型具有一定的差异。对50个测定序列有差异的32个核盘菌ITS和5.8S rDNA片段的多序列对位分析,在ITS1区域的1-40bp种间变化较大,主要以碱基颠换和转换为进化形式。ITS2区域非常保守没有变异位点。黑龙江省核盘菌菌株在DNA水平上和ITS间隔区上具有较显著的遗传变异,显示出丰富的遗传多样性。