Incidence of Fusarium spp. and Levels of Fumonisin B1 in Maize in Western Kenya

Maize kernel samples were collected in 1996 from smallholder farm storages in the districts of Bomet, Bungoma, Kakamega, Kericho, Kisii, Nandi, Siaya, Trans Nzoia, and Vihiga in the tropical highlands of western Kenya. Two-thirds of the samples were good-quality maize, and one-third were poor-quality maize with a high incidence of visibly diseased kernels. One hundred fifty-three maize samples were assessed for Fusarium infection by culturing kernels on a selective medium. The isolates obtained were identified to the species level based on morphology and on formation of the sexual stage in Gibberella fujikuroi mating population tests. Fusarium moniliforme (G. fujikuroi mating population A) was isolated most frequently, but F. subglutinans (G. fujikuroi mating population E), F. graminearum, F. oxysporum, F. solani, and other Fusarium species were also isolated. The high incidence of kernel infection with the fumonisin-producing species F. moniliforme indicated a potential for fumonisin contamination of Kenyan maize. However, analysis of 197 maize kernel samples by high-performance liquid chromatography found little fumonisin B₁ in most of the samples. Forty-seven percent of the samples contained fumonisin B₁ at levels above the detection limit (100 ng/g), but only 5% were above 1,000 ng/g, a proposed level of concern for human consumption. The four most-contaminated samples, with fumonisin B₁ levels ranging from 3,600 to 11,600 ng/g, were from poor-quality maize collected in the Kisii district. Many samples with a high incidence of visibly diseased kernels contained little or no fumonisin B₁, despite the presence of F. moniliforme. This result may be attributable to the inability of F. moniliforme isolates present in Kenyan maize to produce fumonisins, to the presence of other ear rot fungi, and/or to environmental conditions unfavorable for fumonisin production.     

Identification of airborne propagules of the Gibberella fujikuroi species complex during maize production

The airborne dispersal of the anamorphs of the Gibberella fujikuroi species complex was studied under pre- and postharvest maize (corn) production conditions using a 3-stage Andersen sampler. The aim of this study was to identify and analyse the size distribution of such species in air samples. Differences were observed between the concentration of large- and small-sized propagules (identified as aggregates and single microconidia, respectively), but the difference was only significant during a high concentration period (October 2007, P = 0.009). No correlation was found between the concentration of fusaria found at different sampling heights (10 and 150 cm above ground level). Fusarium isolates were collected and identified based on morphological characters and using species-specific PCR assays. The PCR analysis confirmed morphological identification of F. verticillioides, F. proliferatum and F. subglutinans. High concentrations were found during the maize harvest, loading and corn shelling. Our results showed that the monitoring of F. verticillioides should be performed at a single sampling height.     

Differentiation of Fusarium subglutinans f. sp. pini by Histone Gene Sequence Data

Fusarium subglutinans f. sp. pini (= F. circinatum) is a pathogen of pine and is one of eight mating populations (i.e., biological species) in the Gibberella fujikuroi species complex. This species complex includes F. thapsinum, F. moniliforme (= F. verticillioides), F. nygamai, and F. proliferatum, as well as F. subglutinans associated with sugarcane, maize, mango, and pineapple. Differentiating these forms of F. subglutinans usually requires pathogenicity tests, which are often time-consuming and inconclusive. Our objective was to develop a technique to differentiate isolates of F. subglutinans f. sp. pini from other isolates identified as F. subglutinans. We sequenced the histone H3 gene from a representative set of Fusarium isolates. The H3 gene sequence was conserved and contained two introns in all the isolates studied. From both the intron and the exon sequence data, we developed a PCR-restriction fragment length polymorphism technique that reliably distinguishes F. subglutinans f. sp. pini from the other biological species in the G. fujikuroi species complex.     

Fusarium fractiflexum sp. nov. and two other species within theGibberella fujikuroi species complex recently discovered in Japan that form aerial conidia in false heads

Morphological and molecular phylogenetic analyses were conducted on 12 strains ofFusarium, deposited in MAFF asF. subglutinans (≡F. moniliforme var.subglutinans≡F. sacchari var.subglutinans) orFusarium sp. because they formed aerial conidia in false heads in the dark. These strains were resolved as three distinct species within theGibberella fujikuroi species complex. A new species,F. fractiflexum, and two species new to Japan,F. circinatum andF. concentricum, are described and illustrated and their morphological features are discussed.Fusarium fractiflexum, isolated from diseased yellow leaf spots ofCymbidium spp., is differentiated from other fusaria based on its yellowish colonies and aerial conidia formed in false heads in the dark and in zigzag-like conidial chains under black light. Japanese strains ofF. circinatum also formed elongate, coiled sterile hyphae. Phialidic aerial conidia with a pointed apex and a wedgeshaped base were found inF. concentricum cultured under black light and represent a new diagnostic character of the species, in addition to colonies with alternating concentric rings when cultured on PDA. Based on DNA sequences of the β-tubulin gene and two other loci, strains ofF. fractiflexum were resolved phylogenetically as members of the Asian clade of theG. fujikuroi species complex. In addition, Japanese strains ofF. circinatum andF. concentricum were phylogenetically identical to the ex-type strains.     

Gibberella fujikuroi mating population E is associated with maize and teosinte

Isolates of Fusarium subglutinans mating population E are usually found on maize. This fungus forms part of the so-called Gibberella fujikuroi species complex. Previously, F. subglutinans has been associated with two additional mating populations (B and H) and a variety of plant hosts. This was mainly due to a lack of diagnostic morphological characters, but the use of DNA sequence information showed that the strains making up mating populations B, E and H, as well as those associated with the different plant hosts, represent separate species. Recently, another putative mating population has been reported on the wild teosinte relatives of maize. Based on sexual compatibility studies, these isolates were apparently closely related to the pitch canker fungus, F. subglutinans f. sp. pini (= F. circinatum;G. fujikuroi mating population H). The aim of the current study was to determine whether the population of F. subglutinans from teosinte constitutes a new or an existing lineage within the G. fujikuroi complex. For this purpose, portions of the mitochondrial small subunit ribosomal DNA, calmodulin and β-tubulin genes from the fungi were sequenced. Phylogenetic analyses and comparison with sequences from public domain databases indicated that the F. subglutinans isolates from teosinte are most closely related to strains of G. fujikuroi mating population E. These results were confirmed using sexual compatibility studies. The putative mating population from the wild relatives of maize therefore forms part of the existing E-mating population and does not constitute a new lineage in the G. fujikuroi species complex.     

Occurrence and toxicity ofFusarium subglutinans from Peruvian maize

Twenty-five samples of maize kernels collected at harvest time from geographically different corn fields in Peru, were examined for the occurrence of toxigenicFusarium species. The most frequently recovered species wereF. subglutinans (48%),F. moniliforme (46%), andF. equiseti (5%). OtherFusarium species isolated (up to 1%) includedF. graminearum, F. acuminatum, F. solani, F. oxysporum, andF. culmorum. Assays ofFusarium culture extracts usingArtemia salina larvae, showedF. subglutinans as one of the most toxigenic species, and its toxicity was mostly correlated to the capability to produce beauvericin (BEA). All eight tested isolates ofF. subglutinans grown on autoclaved corn kernels produced BEA (from 50 to 250 mg/Kg) as well as moniliformin (M) (from 70 to 270 mg/Kg). This is the first report on BEA and M production by maize isolates ofF. subglutinans from South America.     

Molecular Identification,Mycotoxin Production and Comparative Pathogenicity of Fusarium temperatum Isolated from Maize in China

A recently isolated Fusarium population from maize in Belgium was identified as a new species, Fusarium temperatum. From a survey of Fusarium species associated with maize ear rot in nineteen provinces in 2009 in China, ten strains isolated from Guizhou and Hubei provinces were identified as F. temperatum. Morphological and molecular phylogenetic analyses based on the DNA sequences of individual translation elongation factor 1‐alpha and β‐tubulin genes revealed that the recovered isolates produced macroconidia typical of four‐septate with a foot‐shaped basal cell and belonged to F. temperatum that is distinctly different from its most closely related species F. subglutinans and others within Gibberella fujikuroi complex species from maize. All the strains from this newly isolated species were able to infect maize and wheat in field, with higher pathogenicity on maize. Mycotoxin determination of maize grains infected by the strains under natural field condition by ultra‐high‐performance liquid chromatography–tandem mass spectrometry and gas chromatography–mass spectrometry analyses showed that among fifteen mycotoxins assayed, two mycotoxins fumonisin B₁ and B₂ ranging from 9.26 to 166.89 μg/g were detected, with massively more FB₂ mycotoxin (2.8‐ to 108.8‐fold) than FB₁. This mycotoxin production profile is different from that of the Belgian population in which only fumonisin B₁ was barely detected in one of eleven strains assayed. Comparative analyses of the F. temperatum and F. subglutinans strains showed that the highest fumonisin producers were present among the F. temperatum population, which were also the most pathogenic to maize. These results suggested a need for proper monitoring and controlling this species in the relevant maize‐growing regions.     

Occurrence of Fusaproliferin and Beauvericin in Fusarium-Contaminated Livestock Feed in Iowa

Fusarium fungal contaminants and related mycotoxins were investigated in eight maize feed samples submitted to the Iowa State University Veterinary Diagnostic Laboratory. Fusarium moniliforme, F. proliferatum, and F. subglutinans were isolated from seven, eight, and five samples, respectively. These strains belonged to mating populations A, D, and E of the teleomorph Gibberella fujikuroi. Fusaproliferin was detected at concentrations of 0.1 to 30 μg/g in four samples, and beauvericin was detected (0.1 to 3.0 μg/g) in five samples. Fumonisins were detected in all eight samples (1.1 to 14 μg/g). Ten of 11 strains of F. proliferatum and all 12 strains of F. subglutinans isolated from the samples produced fusaproliferin in culture on whole maize kernels (4 to 350 and 100 to 1,000 μg/g, respectively). Nine F. proliferatum strains also produced beauvericin in culture (85 to 350 μg/g), but none of the F. subglutinans strains produced beauvericin. Fumonisin B₁ was produced by all nine F. moniliforme strains (50 to 2,000 μg/g) and by 10 of the F. proliferatum strains (1,000 to 2,000 μg/g). This is the first report of the natural occurrence of fusaproliferin outside Italy and of the natural occurrence of beauvericin in North America.     

Characterization of gibberellin producing strains of Fusarium moniliforme based on DNA polymorphism

The gibberellins are one of the major groups of growth promoting hormones and are secondary metabolites of the fungus Fusarium moniliforme (Perfect stage: Gibberella fujikuroi). Sixteen strains of Fusarium from different geographical regions and different hosts were analysed for their ability to produce gibberellins (GA) and for genetic relatedness by random amplified polymorphic DNA (RAPD). Range of gibberellin production varied between 28.9 to 600.0 mg g^-1 dry weight of mycelium in different strains of Fusarium. RAPD analysis showed completely different pattern between high, moderate and low producing strains. High producers formed nearly identical RAPD patterns, whereas the low and moderate producers gave heterologous amplification patterns. Since Fusarium pallidoroseum was in another group, it was possible to distinguish between different species of the genus Fusarium by RAPD. These investigations may find an application in the diagnosis of unknown Fusarium species and in distinguishing isolates of Gibberella fujikuroi within the section of Liseola. This revised version was published online in June 2006 with corrections to the Cover Date.     

Biodiversity of Fusarium species in Mexico associated with ear rot in maize, and their identification using a phylogenetic approach

Fusarium proliferatum, F. subglutinans, and F. verticillioides are known causes of ear and kernel rot in maize worldwide. In Mexico, only F. verticillioides and F. subglutinans, have been reported previously as causal agents of this disease. However, Fusarium isolates with different morphological characteristics to the species that are known to cause this disease were obtained in the Highland-Valley region of this country from symptomatic and symptomless ears of native and commercial maize genotypes. Moreover, while the morphological studies were not sufficient to identify the correct taxonomic position at the species level, analyses based in the Internal Transcribed Spacer region and the Nuclear Large Subunit Ribosomal partial sequences allowed for the identification of F. subglutinans, F. solani, and F. verticillioides, as well as four species (F. chlamydosporum, F. napiforme, F. poae, and F. pseudonygamai) that had not previously been reported to be associated with ear rot. In addition, F. napiforme and F. solani were absent from symptomless kernels. Phylogenetic analysis showed genetic changes in F. napiforme, and F. pseudonygamai isolates because they were not true clones, and probably constitute separate sibling species. The results of this study suggest that the biodiversity of Fusarium species involved in ear rot in Mexico is greater than that reported previously in other places in the world. This new knowledge will permit a better understanding of the relationship between all the species involved in ear rot disease and their relationship with maize.     

Gibberellin biosynthesis and gibberellin oxidase activities in Fusarium sacchari,Fusarium konzum and Fusarium subglutinans strains

Several isolates of three Fusarium species associated with the Gibberella fujikuroi species complex were characterized for their ability to synthesize gibberellins (GAs): Fusarium sacchari (mating population B), Fusarium konzum (mating population I) and Fusarium subglutinans (mating population E). Of these, F. sacchari is phylogenetically related to Fusarium fujikuroi and is grouped in the Asian clade of the complex, while F. konzum and F. subglutinans are only distantly related to Fusarium fujikuroi and belong to the American clade. Variability was found between the different F. sacchari strains tested. Five isolates (B-12756; B-1732, B-7610, B-1721 and B-1797) were active in GA biosynthesis and accumulated GA₃ in the culture fluid (2.76–28.4 μg/mL), while two others (B-3828 and B-1725) were inactive. GA₃ levels in strain B-12756 increased by 2.9 times upon complementation with ggs2 and cps-ks genes from F. fujikuroi. Of six F. konzum isolates tested, three (I-10653; I-11616; I-11893) synthesized GAs, mainly GA₁, at a low level (less than 0.1 μg/mL). Non-producing F. konzum strains contained no GA oxidase activities as found for the two F. subglutinans strains tested. These results indicate that the ability to produce GAs is present in other species of the G. fujikuroi complex beside F. fujikuroi, but might differ significantly in different isolates of the same species.     

Rapid diagnosis of rice bakanae caused by Fusarium fujikuroi and F. proliferatum using loop‐mediated isothermal amplification assays

Rice bakanae is an important disease that causes serious rice production loss worldwide. We describe a new method for rapid diagnosis of rice bakanae caused by Fusarium fujikuroi and F. proliferatum, based on loop‐mediated isothermal amplification (LAMP) assays. After screening, primers were selected to target FusariumDNA sequences, that is, the intergenic spacer (IGS) region of the nuclear ribosomal operon and reductase‐coding region (RED1) in F. fujikuroi and F. proliferatum, respectively. Both LAMP assays efficiently amplified target genes in 70 min at 62°C. A colour change from purple to sky blue (visible to the unaided eye) was observed in the presence of the DNA of the targeted pathogens only, by adding hydroxynaphthol blue to the reaction system prior to amplification. The minimum of genomic DNA needed in the assays was 67 and 346 pg/μl for F. fujikuroi and F. proliferatum, respectively. Using the two assays described here, we successfully and rapidly diagnosed suspected diseased rice plant and seed samples collected from Jiangsu Province.     

Moniliformin produced by cultures of Fusarium moniliforme var. subglutinans isolated from swine feed

Feed samples from Iowa suspected of causing vomiting and enlarged vulva as well as mortalities of swine were examined for toxigenic fungi and mycotoxins Fusarium moniliforme Sheldon and F. moniliforme Sheldon var. subglutinans Wollenew. & Reink. accounted for 43% and 18.5%, respectively, of the total count of 4.75×10⁵ propagules filamentous fungi per gram of swine feed, but representatives of various Penicillium spp. and Aspergillus spp. were also found. Eight isolates of F. moniliforme var. subglutinans from the feed produced 51–540 g of moniliformin per g on cracked corn at 25°C for six weeks. Zearalenone was not detected in these corn fermentations. Eight isolates of F. moniliforme from the feed did not produce detectable amounts of either zearalenone or monoliformin on cracked corn. Moniliformin was not detected in the feed samples.     

Fusarium fujikuroi associated with stem rot of red‐fleshed dragon fruit (Hylocereus polyrhizus) in Malaysia

Stem rot was recorded as one of serious diseases of red‐fleshed dragon fruit, (Hylocereus polyrhizus), in Malaysia. Fusarium fujikuroi was recovered from stem rot lesion of H. polyrhizus and the species was identified using TEF1‐α sequence and mating study. From maximum likelihood phylogenetic tree using combined TEF1‐α and β‐tubulin sequences, the F. fujikuroi isolates from stem rot were grouped according to three geographical locations, namely Peninsular Malaysia, Sabah and Sarawak. Phylogenetic analysis indicated that F. fujikuroi isolates from stem rot of H. polyrhizus were clustered separately from F. fujikuroi isolates from rice because of intraspecific variation. From amplification of MAT allele‐specific primers, 20% of the isolates carried MAT‐1 allele while 80% carried MAT‐2 allele. From isolates that carried MAT‐1 allele, 65% crossed‐fertile with MP‐C (mating population of F. fujikuroi) tester strain while for MAT‐2 allele, 56% crossed‐fertile with MP‐C. None of the isolates were identified as MP‐D (mating population of F. proliferatum). Pathogenicity test conducted on 40 representative isolates showed that the stem rot symptoms were similar with the symptoms observed in the field, and can be categorized as low, moderate and high aggressiveness, which indicated variation in pathogenicity and virulence among the isolates. This study provides novel findings regarding Fusarium species associated with stem rot of H. polyrhizus and indicated that F. fujikuroi as a new causal pathogen of the disease.     

Frequency and diversity of Fusarium spp. colonizing roots of Egyptian cottons

Abstract

Fusarium species are known to play a role in several diseases of cotton including the seedling disease complex, wilt, and boll rot. Therefore, a mycoflora study was conducted in 1998 in order to identify Fusarium species found in association with cotton roots. A total of 109 samples of cotton seedlings infected with post-emergence damping-off or rotted roots of adult plants were obtained from different cotton-growing areas in Egypt. Forty-six isolates were recovered and were identified as follows: F. oxysporum (28 isolates), F. moniliforme (9), F. solani (6), F. avenaceum (2), F. chlamydosporum (1). F. oxysporum, F. moniliforme and F. solani, the dominant species, accounted for 60.9%, 19.6% and 13% of the total isolates, respectively in 1998. F. oxysporum showed the highest isolation frequency in Beharia and Minufiya while F. moniliforme showed the most isolation frequency in Minufiya and Gharbiya. F. oxysporum was one of the major taxa of the Fusarium assemblage from Giza 70. F. oxysporum showed the most frequently isolated fungus in May while F. moniliforme and F. solani were the most frequently isolated fungi in August. Isolation frequency of Fusarium spp. during July and August was significantly greater than that of April or June. This implies that cotton roots are subjected more to colonization by Fusarium spp. as plants mature. Regarding pathogenicity, of the 46 isolates of Fusarium spp. tested under greenhouse conditions, 38 isolates (82.4%) were pathogenic to seedlings of Giza 89. This study indicates that F. oxysporum and F. moniliforme are important pathogens in the etiology of cotton damping-off in Egypt.     

Mycotoxin production by Fusarium species isolated from New Zealand maize fields

Forty Fusarium isolates obtained from maize fields were screened for moniliformin production on maize kernels. Twelve isolates, including seven of F. subglutinans, were found to produce moniliformin at levels ranging from 0.4 to 64 ppm. Twenty six isolates were also screened for production of deoxynivalenol, diacetoxyscirpenol, T-2 toxin and zearalenone. Of these, 22, including all 11 isolates of F. graminearum, produced zearalenone at levels ranging from 0.1 to 96.0 ppm, while 13 produced T-2 toxin at low levels, (<1.1 ppm). Deoxynivalenol and diacetoxyscirpenol were each produced by six isolates, also at low levels (<1.0 ppm). Three isolates of F. graminearum and one of F. sambucinum produced four toxins simultaneously.     

Production of moniliformin by Canadian isolates of Fusarium

Twenty-eight Canadian isolates of Fusarium were tested for their ability to produce moniliformin in corn. Both F. moniliforme (2/6 isolates) and F. subglutinans (11/15 isolates) produced the mycotoxin, while F. graminearum did not. Field-corn inoculated with F. moniliforme M3783 was able to support production of both moniliformin and fusarin C.     

Protection of maize seedlings byFusarium moniliforme against infection byFusarium graminearum in the soil

The incidence ofFusarium moniliforme in surface-sterilized kernels in two commercial South African white maize cultivars was 64% and 6%, respectively. Heat treatment completely eliminated seedborneF. moniliforme from kernels of both cultivars. Heat treated, uncontaminated maize germlings were pre-inoculated with different isolates ofF. moniliforme and planted in steam-treated soil containing inoculum of different isolates ofF. graminearum Group 1 and Group 2. Seedling weights of germlings pre-inoculated with some isolates ofF. moniliforme were significantly higher than those of controls when exposed to some isolates ofF. graminearum in the soil. The protective effect of pre-inoculation withF. moniliforme was particularly evident in maize seedlings exposed to inoculum of an aggressive isolate ofF. graminearum Group 1. This is the first report of the protection of maize seedlings byF. moniliforme against infection byF. graminearum in the soil.     

Leaf axil sampling of midwest U.S. maize for mycotoxigenic Fusarium fungi using PCR analysis

PCR analysis was used to detect Fusarium species generically, as well as the mycotoxin-producing species F.␣subglutinans, F. proliferatum, and F. verticillioides in leaf axil and other maize tissues during ear fill in a multiyear study in central Illinois. The frequency of Fusarium detected varied from site to site and year to year. Fusarium was generically detected more frequently in leaf axil material than in leaf/husk lesions. In two growing seasons, the leaf axil samples were also tested for the presence of the mycotoxin producing species F. proliferatum, F. subglutinans, and F. verticillioides. Overall, F. proliferatum and F. verticillioides were detected less often than F. subglutinans. Fusarium was generically and specifically detected most commonly where visible fungal growth was present in leaf axil material. Disclaimer: The mention of firm names or trade products in this article does not imply that they are endorsed or recommended by the United States Department of Agriculture over other firms or similar products not mentioned.     

Interactions of Fusarium moniliforme,its metabolites and bacteria with corn

Fusarium moniliforme Sheldon is an economically important pathogen of corn (Zea mays L.) which causes stalk, root and ear rot. Several mycotoxins have also been isolated, identified and implicated in both animal and human toxicoses. The fungus can be disseminated in symptomless corn seed and can also survive in crop residues in the soil. Asymptomatic infection may be related to different corn cultivars, fungal strains, and environmental factors. Symptomatic expression of pathogenicity may vary, but usually the result of such infections is death of the plant. The greatest concern is the asymptomatic infection, since it is in this form that fungal toxins may surreptitiously enter animal and human food chains. F. moniliforme produces both fusaric acid, which is phytotoxic to corn and interferes with seed germination, and plant growth regulators that may affect pathogenicity of the fungus or be associated with the production of mycotoxins. Other metabolites, including fusarin C, moniliformin, and the fumonisins, may or may not be phytotoxic, but are associated with animal and human toxicoses. The control of F. moniliforme in corn is therefore quite important. One potential means to accomplish this reduction is biocontrol by the application of antagonistic rhizobacteria to corn kernels at planting. To be effective the bacteria must be able to colonize the corn root system and be able to prevent root infection by successful competing with F. moniliforme which may be accomplished by siderophore and or antibiotic activity.