Characterization of virulent gene locus in the genome of Fusarium spp. causing wilt disease of Psidium guajava L. in India

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 their virulence factor in terms of analysis using virulent gene-related microsatellite loci. The erratic spread and occurrence of guava wilt in different areas may be due to variable aggressiveness or virulence of different pathogenic isolates in the soil. Out of 10 virulent gene locus related microsatellite markers ofFusarium spp., only six marker viz. Xyl, KHS1, PelA1, PG6/7, CHS1/2 and FMK1/MAPK1 were successfully amplified. This indicates that all the tested Fusarium sp. isolates of guava are having virulence gene in their genome. Microsatellite marker for virulence factor genes of Xyl loci was amplified in both Fop and Fs isolates. Product size of 281 bps was exactly amplified with a single banding pattern in all the isolates of Fop and Fs. It has been observed that other five microsatellite marker for virulence factor genes such as KHS1, PelA1, PG6/7, CHS1/2 and FMK1/MAPK1 were amplified with specific band pattern. PG6/7, CHS1/2 and FMK1/MAPK1 were only amplified in Fop isolates with a product size of 765 bps, 1566 bps; 1010 bps and 1244 bps. PelA1 and KHS1were amplified only in Fs isolates with the product size of 586 bps; 1359 bps, respectively. The results indicate that virulence factor genes are in response to produce wilt disease like symptoms in guava plants and also having pathogenic gene-related locus.     

Characterization of Fusarium spp. associated with pineapple fruit rot and leaf spot in Peninsular Malaysia

Pineapple (Ananas comosus) is one the important fruit crops planted in Malaysia, and this study was conducted to determine Fusarium spp. associated with diseases of the fruit crop as Fusarium is prevalent in tropical countries. Our objective was to identify and characterize Fusarium spp. associated with pineapple fruit rot and leaf spot mainly found on the fruits and leaves in Peninsular Malaysia. Fusarium isolates (n = 108) associated with pineapple fruit rot and leaf spot were characterized by morphological, molecular and phylogenetic analyses, a mating study and pathogenicity testing. TEF‐1α sequence analysis identified Fusarium proliferatum, Fusarium verticillioides, Fusarium sacchari and Fusarium sp. Mating was successful only between tester strains of F. proliferatum and F. verticillioides. Sexual crosses with standard tester strains showed that 82 isolates of F. proliferatum produced fertile crosses with mating population D (Gibberella intermedia) and three isolates of F. verticillioides were fertile with the tester strain of mating population A (Gibberella moniliformis). All isolates were pathogenic, causing pineapple fruit rot and leaf spot, thus fulfilling Koch's postulates.     

Histological changes in guava root during wilting induced by Fusarium spp.

Wilt is the most destructive disease of guava in India. Fusarium oxysporum f. sp. psidii and Fusarium solani are reported as most commonly isolated pathogens and are considered to be associated singly or in combination with roots of wilt affected plants of guava (Psidium guajava L.). Histopathological observations were made of the roots of wilt affected guava plants in the present investigation. The observations of wilted guava root showed disintegration/necrosis of the epidermal tissue, cortex tissue and vascular bundle cells. In T.S. of root of wilted plant the normal shape of the epidermis was disrupted and there was breaking and opening in the epidermis through which pathogen may enter in the host tissue. Necrosis of the internal tissue and vascular bundle restricts the movement of water and nutrient and thus results wilting.     

Identification and Characterization of Toxigenic Fusaria Associated with Sorghum Grain Mold Complex in India

Fusarium species are dominant within the sorghum grain mold complex. Some species of Fusarium involved in grain mold complex produce mycotoxins, such as fumonisins. An attempt was made to identify Fusarium spp. associated with grain mold complex in major sorghum-growing areas in India through AFLP-based grouping of the isolates and to further confirm the species by sequencing part of α-Elongation factor gene and comparing the sequences with that available in the NCBI database. The dendrogram generated from the AFLP data clustered the isolates into 5 groups. Five species of Fusarium—F. proliferatum, F. thapsinum, F. equiseti, F. andiyazi and F. sacchari were identified based on sequence similarity of α-Elongation factor gene of the test isolates with those in the NCBI database. Fusarium thapsinum was identified as predominant species in Fusarium—grain mold complex in India and F. proliferatum as highly toxigenic for fumonisins production. Analysis of molecular variance (AMOVA) revealed 54% of the variation in the AFLP patterns of 63 isolates was due to the differences between Fusarium species, and 46% was due to differences between the strains within a species.     

Real-time PCR Assay Based on Topoisomerase-II Gene for Detection of <Emphasis Type="Italic">Fusarium udum</Emphasis>

Fusarium wilt is an important soilborne disease of pigeonpea, caused by Fusarium udum. In this study, we have designed a real-time PCR assay for the detection of Fusarium udum from infected pigeonpea plants. Based on Topoisomerase-II gene sequence data from Fusarium udum and other related Fusarium species, a pair of primer was designed. The species-specific primers were tested in real-time PCR SYBR green assay. No increasing fluorescence signals exceeding the baseline threshold was observed with tested microbes, except Fusarium udum DNA. A single dissociation peak of increased fluorescence was obtained for the specific primers at melting temperature of 81.25°C. The real-time PCR showed a lowest detection of 0.1 pg genomic DNA. The assay was more sensitive, accurate and less time consuming for detection of Fusarium udum in infected plants root.     

Effect of delayed harvest on contamination of pearl millet grain with mycotoxin-producing fungi and mycotoxins

The response to delayed harvest of fungal and mycotoxin contamination of grain of the pearl millet hybrid HGM 100 was examined in 1992 and 1993. Samples of grain were assayed from seven plantings at locations near Tifton, Georgia, USA. Grain was harvested at 30, 40, and 50 days after anthesis and evaluated for infection byFusarium species andAspergillus flavus, and mycotoxin contamination. Mean isolation frequencies ofF. semitectum (35.6%) andF. chlamydosporum (17.2%) increased linearly with delayed harvest.Fusarium moniliforme andF. equisiti were infrequently isolated (<0.5%) and did not increase in the grain when harvest was delayed. Low mean concentrations of zearalenone (0.17 ppm), nivalenol (0.42 ppm), and deoxynivalenol (0.01 ppm) were detected but were not affected by delayed harvest. Isolation frequencies ofF. chlamydosporum andF. equiseti were correlated (P=0.07) with levels of nivalenol.Aspergillus flavus was not isolated from the grain, and aflatoxin concentrations averaged 1.9 ppb.     

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.     

Development of species-specific primers for rapid identification by PCR of the ecologically important pathogen Fusarium keratoplasticum from isolated and environmental samples

The genus Fusarium contains many fungal species known to be pathogenic to animals and plants alike. One species complex within this genus, the Fusarium solani species complex (FSSC), is of particular concern due to its high numbers of pathogenic members. FSSC members are known to contribute significantly to plant, human and other animal fungal disease. One member of the FSSC, Fusarium keratoplasticum, is of particular ecological concern and has been implicated in low hatching success of endangered sea turtle eggs, as well as contribute to human and other animal Fusarium pathogenesis. Species-specific primers for molecular identification of F. keratoplasticum currently do not exist to our knowledge, making rapid identification, tracking and quantitation of this pathogenic fungus difficult. The objective of this study was to develop primers specific to F. keratoplasticum that could be applied to DNA from isolated cultures as well as total (mixed) DNA from environmental samples. RPB2 sequence from 109 Fusarium isolates was aligned and analysed to determine nucleotide polymorphisms specific to F. keratoplasticum useful for primer design. A set of primers were generated and found to be effective for identification of F. keratoplasticum from total DNA extracted from sand surrounding sea turtle nesting sites.     

Comparative molecular analysis of <Emphasis Type="Italic">Fusarium solani</Emphasis> isolates by RFLP and RAPD

Fusarium solani is an important pathogen causing wilt disease of guava in India. In this work, we analyzed seven representative isolates of F. solani, collected from different places of India, by restriction fragment length polymorphism (RPLP) using HindIII or DraI restriction endonucleases and random amplified polymorphic DNA (RAPD). Pattern of restriction enzyme revealed a similar restriction cut type cluster in the isolate namely, Allahabad (isolate-3), Faizabad (isolate-4), Unnao (isolate-5) and Lucknow (isolate-6) region, while other cluster was consist of isolate from Ranchi (isolate-2) and Ludhiana (isolate-7). Slightly variable results were obtained when 10 randomly amplified polymorphic DNA markers (OPA01–OPA10) tested in the genome of Fusarium solani and grouped on basis of obtained allelic data. RAPD fingerprinting showed a higher variability than RFLP, and each isolate had a unique electrophoretic pattern with five of the ten primers used. Our results show that RAPD much efficient to distinguish between all F. solani isolate tested.     

The distribution ofFusarium species in soils planted to millet and sorghum in Lesotho,Nigeria and Zimbabwe

Samples from soils planted to millet and sorghum from Lesotho, Nigeria, and Zimbabwe were processed and a total of 3,291Fusarium cultures were recovered. Of these 1,296 cultures were isolated from plant debris and 1,995 cultures were recovered from soil dilutions. The most prevalent species recovered wereF. oxysporum (37%),F. equiset (30%),F. solani (14%),F. moniliforme (6%),F. compactum (5%),F. nygamai (4%), andF. chlamydosporum (2%). OtherFusarium species isolated wereF. merismoides, F. polyphialidicum, F. graminearum, F. subglutinans, F. sambucinum, F. longipes, F. semitectum, F. dimerum, F. lateritium, and a group of cultures designated as population A which resembleF. camptoceras. Fusarium equiseti was the predominant species in soil samples from Nigeria and Zimbabwe, whileF. oxysporum was the predominant species recovered from soil from Lesotho.Contribution No. 1881, Fusarium Research Center, Department of Plant Pathology, The Pennsylvania State University.     

Guava Decline: A Complex Disease Involving Meloidogyne mayaguensis and Fusarium solani

In Brazil, Meloidogyne mayaguensis has become a threat to guava production. Approximately a third of the cultivated area is infested, leading almost inevitably to the decimation of the orchards. Because parasitized trees develop rotten roots as the disease progresses, the possibility that a soil‐borne pathogen could be involved was investigated. From several nematode‐free or nematode‐infested orchards, nearly 2000 root fragments were tested for bacteria and fungi. Positive isolations were obtained from nematode‐infested areas only and were predominantly identified as Fusarium sp. In a 5‐month microplot experiment, guava seedlings were uninoculated (control) or were inoculated with M. mayaguensis only or with this nematode and 21 days later with one of 11 Fusarium sp. isolates. A Scott–Knot analysis of several vegetative variables and of the extent of root rot allowed the generation of a dissimilarity dendrogram that indicated that four Fusarium sp. isolates were particularly associated with damage to the seedlings. Upon identification of these isolates as Fusarium solani, a 6‐month microplot experiment was set up, in which guava seedlings were uninoculated or were inoculated with one of the following: (i) M. mayaguensis only, (ii) four F. solani isolates, separately, (iii) four F. solani isolates separately, combined with physical injury of the roots with a knife, (iv) M. mayaguensis, and 21 days later with four F. solani isolates, separately. No root rot and virtually no effect on all variables were observed in the seedlings inoculated with the fungus isolates, with or without physical injury. Major root rot and a negative effect on all variables were observed in the seedlings inoculated with M. mayaguensis and all four F. solani isolates. This characterizes guava decline as a complex disease caused by the synergistic effect of these organisms, in which parasitism by the nematode predisposes the plants to root decay caused by the fungus.     

Molecular characterization of pathogenic Fusarium species in cucurbit plants from Kermanshah province, Iran

Fusarium is one of the important phytopathogenic genera of microfungi causing serious losses on cucurbit plants in Kermanshah province, the largest area of cucurbits plantation in Iran. Therefore, the objectives in this study were to isolate and identify disease-causing Fusarium spp. from infected cucurbit plants, to ascertain their pathogenicity, and to determine their phylogenetic relationships. A total of 100 Fusarium isolates were obtained from diseased cucurbit plants collected from fields in different geographic regions in Kermanshah province, Iran. According to morphological characters, all isolates were identified as Fusarium oxysporum, Fusarium proliferatum, Fusarium equiseti, Fusarium semitectum and Fusarium solani. All isolates of the five Fusarium spp. were evaluated for their pathogenicity on healthy cucumber (Cucumis sativus) and honeydew melon (Cucumis melo) seedlings in the glasshouse. F. oxysporum caused damping-off in 20–35 days on both cucurbit seedlings tested. Typical stem rot symptoms were observed within 15 days after inoculation with F. solani on both seedlings. Based on the internal transcribed spacer (ITS) regions of ribosomal DNA (rDNA) restriction fragment length polymorphism (RFLP) analysis, the five Fusarium species were divided into two major groups. In particular, isolates belonging to the F. solani species complex (FSSC) were separated into two RFLP types. Grouping among Fusarium strains derived from restriction analysis was in agreement with criteria used in morphological classification. Therefore, the PCR-ITS-RFLP method provides a simple and rapid procedure for the differentiation of Fusarium strains at species level. This is the first report on identification and pathogenicity of major plant pathogenic Fusarium spp. causing root and stem rot on cucurbits in Iran.     

Fusarium rot in cucumber greenhouses of Jiroft region

The present work was done to identify Fusarium species that cause Fusarium rot in greenhouse cucumber crop in Jiroft region (Kerman, Iran), in 2006–2007. During these years, a vast sampling was done from several greenhouses of Jiroft. The plants with rot symptoms as well as the soil samples of greenhouse were transferred to lab. The isolates of plants and soil samples were detached by direct isolation of the infected tissue and soil suspension methods, respectively. Totally 120 isolates were obtained, which were classified into the following six species according to their morphological and physiological characteristics: Fusarium oxysporum, Fusarium solani, Fusarium culmorum, Fusarium monoliforme, Fusarium sambucinum, Fusarium subglutinans. It is the first time that three of these taxons, i.e. F. culmorum, F. monoliforme and F. subglutinan are reported in cucumber of Iran. Pathogenesis studies of the isolates were done by mycelium placement and spore suspension injection methods in sterile soil under greenhouse conditions. Then the disease symptoms were investigated.     

Detection of Fusarium wilt pathogens of Psidium guajava L. in soil using culture independent PCR (ciPCR)

Traditional culturing methods take a long time for identification of pathogenic isolates. A protocol has been developed for the detection of Fusarium from soil samples in the early stage of infection. Seventeen soil samples from different locations were collected before the onset of rains to find out the presence of Fusarium spp. population present in the soil of guava orchards and to correlate its presence with incidence of wilt. A PCR based method was developed for the molecular characterization of Fusarium using Fusarium spp. specific primer. DNA extracted by this method was free from protein and other contaminations and the yield was sufficient for PCR amplification. The primer developed in this study was amplifying ∼230 bp in all infected samples while not in healthy soil. The specificity and sensitivity of primer were tested on several Fusarium spp. and found that this primer was amplifying 10⁻⁶ dilution of the fungal DNA. The present study facilitates the rapid detection of Fusarium spp. from infected soil samples of guava collected from different agroclimatic regions in India. A rapid detection method for pathogens and a diagnostic assay for disease would facilitate an early detection of pathogen and lead to more effective control strategies.     

A Case of Primary Localized Cutaneous Infection Due to <Emphasis Type="Italic">Fusarium oxysporum</Emphasis>

Fusarium is a ubiquitous hyalohyphomycete isolated from food, widespread in the environment (plants, soil) and present at all latitudes. Fusarium oxysporum and Fusarium solani are the most frequent pathogenic species, followed by F. moniliforme and F. chlamydosporum. Infections due to this mold may be disseminated or localized. Localized forms include cutaneous and subcutaneous infection, onychomycosis, endophtalmitis, otitis, sinusitis, arthritis, osteomyelitis, and brain abscess. Disseminated forms are those in which two or more noncontiguous sites may be involved. These latter are observed in patients with severe neutropenia. Wounds, digital ulcers, onychomycosis, and paronychia are the typical cutaneous portal of entry. We report a case of primary localized cutaneous infection due to Fusarium in a 29-year-old woman presenting with a nodular lesion, partially ulcerated, asymptomatic on the first finger of the left hand, appeared 4 months earlier. Histological examination showed spongiosis and acanthosis in the stratum corneum, ulceration and inflammation with prevalently mononucleate cells and septate and branched fungal structures in the epidermis and in dermis. The fungus was identified as Fusarium oxysporum by culture of biopsy fragments on Sabouraud dextrose agar with chloramphenicol. The culture was deposited in the culture collection of the mycology section of IHEM, Brussels (IHEM21984 col no. 125). The patient had normal immune status and was successfully treated with surgical excision. Recovery was confirmed at follow-up 8 months later.     

Interaction of Rotylenchulus reniformis with Seedling Disease Pathogens of Cotton

The impact of 10 Fusarium species in concomitant association with Rotylenchulus reniformis on cotton seedling disease was examined under greenhouse conditions. In experiment 1, fungal treatments consisted of Fusarium chlamydosporum, F. equiseti, F. lateritium, F. moniliforme, F. oxysporum, F. oxysporum f.sp. vasinfectum, F. proliferatum, F. semitectum, F. solani, and F. sporotrichioides; Rhizoctonia solani; and Thielaviopsis basicola. The experimental design was a 2 × 14 factorial consisting of the presence or absence of R. reniformis and the 12 fungal treatments plus two controls in autoclaved field soil. In experiment 2, the same fungal and nematode treatments were examined in autoclaved or non-autoclaved soil. This experimental design was a 2 × 2 × 14 factorial consisting of field or autoclaved soil, presence or absence of R. reniformis, and the 12 fungal treatments plus two controls. In both tests, Fusarium oxysporum f. sp. vasinfectum, F. solani, R. solani, and T. basicola consistently displayed extensive root and hypocotyl necrosis that was more severe (P ≤ 0.05) in the presence of R. reniformis. Soil treatment (autoclaved vs. non-autoclaved) influenced the impact of the Fusarium species on cotton seedling disease, with disease being more severe in the autoclaved soil. Rotylenchulus reniformis reproduction on cotton seedlings was greater in field soil compared to autoclaved soil (P ≤ 0.05). This study suggests the importance of Fusarium species and R. reniformis in cotton seedling disease.     

A multiplex real-time PCR method using hybridization probes for the detection and the quantification of Fusarium proliferatum, F. subglutinans, F. temperatum, and F. verticillioides

Maize contamination with Fusarium species is one of the major sources of mycotoxins in food and feed derivates. In the present study, a LightCycler^® real-time PCR method using hybridization probes was developed for the specific identification, detection, and quantification of Fusarium proliferatum, Fusarium subglutinans, Fusarium temperatum, and Fusarium verticillioides, four mycotoxin-producing pathogens of maize. Primers and hybridization probes were designed to target the translation elongation factor 1α (EF-1α) gene of F. subglutinans and F. temperatum or the calmodulin (Cal) gene of F. proliferatum and F. verticillioides. The specificity of the real-time PCR assays was confirmed for the four Fusarium species, giving no amplification with DNA from other fungal species commonly recovered from maize. The assays were found to be sensitive, detecting down to 5 pg and 50 pg of Fusarium DNA in simplex and multiplex conditions respectively, and were able to quantify pg-amounts of Fusarium DNA in artificially Fusarium-contaminated maize samples. The real-time PCR method developed provides a useful tool for routine identification, detection, and quantification of toxigenic Fusarium species in maize.     

Cloning and Sequence Analysis of the Endopolygalacturonase Gene from the Pitch Canker Fungus, Fusarium circinatum

The fungus Fusarium circinatum causes pitch canker disease on mature pine trees and root rot and damping-off of pine seedlings. Endopolygalacturonases (endoPGs) play a major role during penetration of plants by fungi. Digestion of the pectic polysaccharides in the plant primary cell walls is one of the earliest functions of endoPGs during infection. The research objective was to clone and characterize the gene encoding endopolygalacturonase in F. circinatum. A 970-bp DNA fragment was cloned by using degenerate PCR amplification from F. circinatum DNA. Sequence data for this fragment were used to design specific primers for use in genome walking to amplify and sequence the remaining portion of the F. circinatum endoPG gene (Fcpg). The amino acid sequence predicted from this gene showed 90% and 87% similarity to Fusarium oxysporum and Fusarium moniliforme endoPGs, respectively. Received: 10 August 2000 / Accepted: 30 October 2000     

Fusarium spp. are Responsible for Shoot Canker of Kumquat in China

Shoot and branch canker and tree decline of kumquat (Fortunella margarita cv. Guban) were recorded in Yangshuo County, Guilin City, in the Guangxi Zhuang Autonomous Region of China during 2008–2011. Fusarium oxysporum and a new Fusarium species within the Gibberella fujikuroi complex (Fusarium sp. GLB1) were isolated repeatedly from the infected shoots and branches. Species identifications were verified by their high translation elongation factor 1‐alpha (TEF1) sequence similarity with those of the species epitypes. Koch's postulates were fulfilled on kumquat (cv. Guban) and mandarin establishing pathogenicity. To our knowledge, this is the first report of Fusarium shoot canker disease caused by F. oxysporum and Fusarium sp. on kumquat.     

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.