Biodegradation of Naphthalene Using Biosurfactant Producing Fusarium proliferatum WC416 Isolated from Refinery Effluent.

Naphthalene is one of the priority pollutants in the environment which can effectively managed through bioremediation approach. Here fungal remediation of PAHs may be cost-effective technology. In present research study, biodegradation of naphthalene at varying concentrations in laboratory scale was investigated using Fusarium proliferatum WC416 isolated from refinery effluent. Degradation of naphthalene was computed by high-performance liquid chromatography (HPLC) and gas chromatography -mass spectroscopy (GC-MS). The results show that Fusarium proliferatum WC416 has effectively degraded the naphthalene to salicylamide and salicylic acid. The highest degradation achieved was 83% for the concentration of 100 ppm followed 74% and 63% for the concentration of 250 ppm and 500 ppm respectively. The intermediates confirmed by GC-MS were salicylic acid (m/z identification 138) and salicylamide (m/z identification 137). During the study, fungal growth, COD, pH, and surface tension have been monitored, which show the continuous variation that indicates progressive biodegradation of naphthalene. The qualitative assessment of extracellular enzymes shows positive activity for lipase, manganese peroxidase, and laccase. The present study also assessed the biosurfactant production by fungus which was characterized as sophorolipid in nature. The study suggests that Fusarium proliferatum WC416 would be an efficient degrader of naphthalene for environmental clean-up.

Fumonisins in African Countries.

Maize and other cereals are the commodities most contaminated with fumonisins. The maize acreage is increasing in Africa, and the maize harvest provides important foods for humans and feeds for domestic animals throughout the continent. In North Africa, high levels of fumonisins have been reported from Algeria and Morocco, while low levels have been detected in the rather few fumonisin analyses reported from Tunisia and Egypt. The West African countries Burkina Faso, Cameroon, Ghana, and Nigeria all report high levels of fumonisin contamination of maize, while the few maize samples analysed in Togo contain low levels. In Eastern Africa, high levels of fumonisin contamination have been reported from the Democratic Republic of Congo, Ethiopia, Kenya, Tanzania, and Uganda. The samples analysed from Rwanda contained low levels of fumonisins. Analysis of maize from the Southern African countries Malawi, Namibia, South Africa, Zambia, and Zimbabwe revealed high fumonisin levels, while low levels of fumonisins were detected in the few analyses of maize from Botswana and Mozambique.

Fusarium Consortium Populations Associated with Asparagus Crop in Spain and Their Role on Field Decline Syndrome.

Asparagus Decline Syndrome (ADS) is one of the main phytosanitary problems of asparagus crop worldwide. Diseased plants and soil samples from 41 fields from three main production areas of Spain were surveyed. Eight Fusarium species belonging to seven species complexes were identified in soils: F. oxysporum, F. proliferatum, F. redolens, F. solanisensu stricto, F. equiseti, F. culmorum, F. compactum and F. acuminatum. Fusarium oxysporum was the most prevalent species. Statistical correlation (R2 = 88%) was established between F. oxysporum inoculum density and the average temperature of the warmest month. A relationship was also established between three crop factors (average temperature, crop age and F. oxysporum inoculum density) and field disease indices. Significant differences were observed between the distribution of F. oxysporum propagules in white and green asparagus fields. Thirteen Fusarium species belonging to seven species complexes were identified from roots of diseased plants, being F. oxysporum the most prevalent. F. proliferatum, F. oxysporum and F. redolens showed pathogenicity to asparagus and were the main species associated to ADS. Fusarium oxysporum was the species with the highest genetic diversity displaying 14 sequence-based haplotypes with no geographic differentiation. This work contributes to understanding the Fusarium complex associated to ADS for developing accurate integrated disease management strategies.

First report of Fusarium proliferatum causing Sheath Rot Disease of Rice in Eastern India.

Sheath rot is one of the most devastating diseases of rice because of its ability to reduce the yield significantly in all rice cultivating areas of the world (Bigirimana et al., 2015). Sheath rot disease is associated with various pathogens such as Sarocladium oryza, Fusarium fujikuroi complex and Pseudomonas fuscovaginae (Bigirimana et al., 2015). Hence, this disease has become more complex in nature and added more seriousness. From September to December 2018, plants were observed with typical sheath rot symptoms in research farm of ICAR-National Rice Research Institute and ten farmer's fields of Cuttack district, Odisha, Eastern India. About 25 to 37% of sheath rot disease severity was recorded in the infected field. Diseased plants were observed with symptoms such as brownish or reddish brown irregular lesions, which were later, got enlarged with grayish centers. Further, rotting of the topmost leaf sheaths that surround the young panicle was observed. At the severe stages, the young panicle was partially emerged from sheath or completely rotted within the sheath. The white to pinkish powdery growth observed inside the infected sheath leading to chaffy and discolored grains. The sheath rot symptomatic plants were collected from the infected fields. To isolate the causal pathogen, infected sheath tissues were surface sterilized in 1% sodium hypochlorite for 2 min, rinsed three times in sterile distilled water, and placed on potato dextrose agar medium (PDA) (HiMedia). Plates were incubated at 27 ± 1° C for 3 d. Further, fungal pathogen colonies were sub-cultured and purified to perform the pathogenicity test. On PDA, the colonies produced abundant white aerial mycelium with violet to pink pigmentation and hyphae were hyaline with septation. Abundant single celled, oval shaped microcondia (5.5-9 × 1.5-2 µm) were produced, whereas macrocondia were not produced and the fungal pathogen was tentatively identified as Fusarium sp. In order to characterize the pathogen at molecular level, ITS, alpha elongation factor gene (EF1-α), RNA polymerase II largest-subunit gene (RPB2), calmodulin gene (cld) were amplified using the primer pair of ITS1/ITS4, EF1/EF2, 5F/7CR and CLPRO1/CLPRO2 respectively and PCR amplicons were subjected to sequencing (White et al. 1990; O'Donnell et al. 1998; Chang et al. 2015). Furthermore, a species-specific primer Fp3-F/Fp4-R was used to identify the pathogen (Jurado et al., 2006). The resulting sequences were confirmed by BLAST analysis and the FUSARIUM-ID database (http://isolate.fusariumdb.org). BLASTn search showed 100% similarity between the query sequence and ITS, EF1-α, RPB2, Calmodulin gene sequences of F. proliferatum available in the Genbank. The following GenBank accession numbers were obtained; MT394055 for ITS; MT439867 for EF1-α; MT790774 for calmodulin; MT940224 for RPB2 and MT801050 for species-specific to F. proliferatum. To confirm the pathogenicity under glass house conditions, fungus grown on sterilized chaffy grains were placed in between boot leaf sheath and panicle and covered with moist cotton (Saravanakumar et al., 2009). After 15 days post inoculation (dpi), rotting symptoms were observed and these were similar to that of field symptoms. Pathogen was constantly re-isolated from symptomatic tissue, satisfying Koch's postulates. Disease symptoms were not observed on un-inoculated plants. Morphological characters, pathogenicity test and molecular characterization have identified the pathogen as F. proliferatum. To the best of our knowledge, this is the first confirmed report of F. proliferatum causing sheath rot disease on rice from Eastern India.

Vacuolar Serine Protease Is a Major Allergen of Fusarium proliferatum and an IgE-Cross Reactive Pan-Fungal Allergen.

PURPOSE: Fusarium species are among prevalent airborne fungi and causative agents of human respiratory atopic disorders. We previously identified a 36.5-kDa F. proliferatum component recognized by IgE antibodies in 9 (53%) of the 17 F. proliferatum-sensitized atopic serum samples. The purpose of this study is to characterize the 36.5-kDa allergen of F. proliferatum. METHODS: Characterization of allergens and determination of IgE cross-reactivity were performed by cDNA cloning/expression and immunoblot inhibition studies. RESULTS: Based on the finding that the 36.5-kDa IgE-binding component reacted with the mouse monoclonal antibody FUM20 against fungal vacuolar serine protease allergens, the cDNA of F. proliferatum vacuolar serine protease (Fus p 9.0101) was subsequently cloned. Nine serum samples from respiratory atopic patients with IgE binding to the vacuolar serine protease allergen of Penicillium chrysogenum (Pen ch 18) also showed IgE-immunoblot reactivity to rFus p 9.0101. The purified rFus p 9.0101 can inhibit IgE and FUM20 binding to the 36.5-kDa component of F. proliferatum. Thus, a novel and important Fus p 9.0101 was identified. The rPen ch 18 can inhibit IgE binding to Fus p 9.0101. It indicates that IgE cross-reactivity between Fus p 9.0101 and Pen ch 18 also exists. Furthermore, neither rFus p 9.0101 K88A nor rPen ch 18 K89A mutants inhibited IgE binding to rFus p 9.0101. Lys88 was considered a critical core amino acid in IgE binding to r Fus p 9.0101 and a residue responsible for IgE cross-reactivity between Fus p 9.0101 and Pen ch 18 allergens. CONCLUSIONS: Results obtained from this study indicate that vacuolar serine protease may be a major allergen of F. proliferatum and an important IgE cross-reactive pan-fungal allergen, and provide important bases for clinical diagnosis of fungal allergy.