Vegetative compatibility and phenotypic characterization as a means of determining genetic diversity of Aspergillus flavus isolates

Toxigenic Aspergillus species produce mycotoxins that are carcinogenic, hepatotoxic and teratogenic immunosuppressing agents in both human and animals. Kenya frequently experiences outbreaks of aflatoxicosis with the worst occurring in 2010, which resulted in 215 deaths. We examined the possible reasons for these frequent aflatoxicosis outbreaks in Kenya by studying Aspergillus flavus diversity, phenotypes and mycotoxin profiles across various agricultural regions. Using diagonal transect random sampling, maize kernels were collected from Makueni, Homa Bay, Nandi, and Kisumu counties. Out of 37 isolates, nitrate non-utilizing auxotrophs complementation test revealed 20 vegetative compatibility groups. We designated these groups by the prefix “KVCG”, where “K” represented Kenya and consequently assigned numbers 1–20 based on our findings. KVCG14 and KVCG15 had highest distribution frequency (n = 13; 10.8 %). The distribution of the L-, S- and S-/L-morphotypes across the regions were 57 % (n = 21); 7 % (n = 3) and 36 % (n = 13), respectively. Furthermore, a unique isolate (KSM015) was identified that had characteristics of S-morphotype, but produced both aflatoxins B and G. Coconut agar medium (CAM) assay, TLC and HPLC analyses confirmed the presence or absence of aflatoxins in selected toxigenic and atoxigenic isolates. Diversity index (H′) analyses ranged from 0.11 (Nandi samples) to 0.32 (Kisumu samples). Heterokaryon compatibility ranged from 33 % (for the Makueni samples, n = 3) to 67 % (Nandi samples, n = 6). To our knowledge, this is the first reported findings for A. flavus diversity and distribution in Nandi, Homa Bay and Kisumu counties and may assist current and future researchers in the selection of biocontrol strategies to mitigate aflatoxin contamination as has been researched in Makueni and neighbouring counties.     

Aspergillus Colonization and Aflatoxin Contamination of Maize and Sesame Kernels in Two Agro‐ecological Zones in Senegal

Aflatoxin contamination of major food crops is a serious problem in Senegal. Maize and sesame samples were collected during a survey in five districts located in two agro‐ecological zones in Senegal to determine levels of aflatoxin contamination and the distribution and toxigenicity potential of members of Aspergillus section Flavi. Maize samples from the Guinea Savannah zone (SG) exhibited lower aflatoxin content and colony‐forming units (cfu) than those collected from the Sudan Savannah (SS) zone. In maize, aflatoxin concentration and cfu of A. flavus varied with cultivars, shelling practices and storage methods. The maize variety ‘Jaune de Bambey’ had high aflatoxin levels in both agro‐ecological zones. Aflatoxin content in machine‐shelled maize (120 ng/g) was more than 10‐fold higher than that in manually shelled (8 ng/g) or unshelled maize. Aflatoxin content (between 0.1 and 1.2 ng/g) and cfu values (between 13 and 42 000 cfu/g) of sesame were low, suggesting a low susceptibility to A. flavus. In both agro‐ecological zones, and in all storage systems, aflatoxin contamination was lower in sesame than in maize. In this study, only three species of Aspergillus section Flavi (A. flavus, A. tamarii and the unnamed taxon S_BG) were observed with the frequency of toxigenic strains remaining below 50% in maize from the SG zone compared with 51% of isolates from samples collected in Sedhiou district in SS zone. The proportion of toxigenic strains isolated from sesame was variable. For both crops, L‐strains were the most prevalent in the two agro‐ecological zones. Some of the atoxigenic strains collected could be valuable microbial resources for the biological control of aflatoxin in Senegal.     

Immunoassay identification ofAspergillus flavus using monoclonal antibodies raised to the whole cell extracts

Five separate monoclonal antibodies were produced against whole cell extracts ofAspergillus flavus and ELISA procedures used to characterise the reactivity of the antibodies to various fungal extracts. All five antibodies were specific to the aflatoxin producing fungi,A, flavus andA. parasiticus, and indicated no cross reactivity with otherAspergillus species, genera of several fungi or with other components which may be found in food samples whereA. flavus may be found.     

Distribution of active ingredients of a commercial aflatoxin biocontrol product in naturally occurring fungal communities across Kenya

Human populations in Kenya are repeatedly exposed to dangerous aflatoxin levels through consumption of contaminated crops. Biocontrol with atoxigenic Aspergillus flavus is an effective method for preventing aflatoxin in crops. Although four atoxigenic A. flavus isolates (C6E, E63I, R7H and R7K) recovered from maize produced in Kenya are registered as active ingredients for a biocontrol product (Aflasafe KE01) directed at preventing contamination, natural distributions of these four genotypes prior to initiation of commercial use have not been reported. Distributions of the active ingredients of KE01 based on haplotypes at 17 SSR loci are reported. Incidences of the active ingredients and closely related haplotypes were determined in soil collected from 629 maize fields in consecutive long and short rains seasons of 2012. The four KE01 haplotypes were among the top ten most frequent. Haplotype H-1467 of active ingredient R7K was the most frequent and widespread haplotype in both seasons and was detected in the most soils (3.8%). The four KE01 haplotypes each belonged to large clonal groups containing 27–46 unique haplotypes distributed across multiple areas and in 21% of soils. Each of the KE01 haplotypes belonged to a distinct vegetative compatibility group (VCG), and all A. flavus with haplotypes matching a KE01 active ingredient belonged to the same VCG as the matching active ingredient as did all A. flavus haplotypes differing at only one SSR locus. Persistence of the KE01 active ingredients in Kenyan agroecosystems is demonstrated by detection of identical SSR haplotypes six years after initial isolation. The data provide baselines for assessing long-term influences of biocontrol applications in highly vulnerable production areas of Kenya.     

Understanding the genetics of regulation of aflatoxin production and Aspergillus flavus development

Aflatoxins are polyketide-derived, toxic, and carcinogenic secondary metabolites produced primarily by two fungal species, Aspergillus flavus and A. parasiticus, on crops such as corn, peanuts, cottonseed, and treenuts. Regulatory guidelines issued by the U.S. Food and Drug Administration (FDA) prevent sale of commodities if contamination by these toxins exceeds certain levels. The biosynthesis of these toxins has been extensively studied. About 15 stable precursors have been identified. The genes involved in encoding the proteins required for the oxidative and regulatory steps in the biosynthesis are clustered in a 70 kb portion of chromosome 3 in the A. flavus genome. With the characterization of the gene cluster, new insights into the cellular processes that govern the genes involved in aflatoxin biosynthesis have been revealed, but the signaling processes that turn on aflatoxin biosynthesis during fungal contamination of crops are still not well understood. New molecular technologies, such as gene microarray analyses, quantitative polymerase chain reaction (PCR), and chromatin immunoprecipitation are being used to understand how physiological stress, environmental and soil conditions, receptivity of the plant, and fungal virulence lead to episodic outbreaks of aflatoxin contamination in certain commercially important crops. With this fundamental understanding, we will be better able to design improved non-aflatoxigenic biocompetitive Aspergillus strains and develop inhibitors of aflatoxin production (native to affected crops or otherwise) amenable to agricultural application for enhancing host-resistance against fungal invasion or toxin production. Comparisons of aflatoxin-producing species with other fungal species that retain some of the genes required for aflatoxin formation is expected to provide insight into the evolution of the aflatoxin gene cluster, and its role in fungal physiology. Therefore, information on how and why the fungus makes the toxin will be valuable for developing an effective and lasting strategy for control of aflatoxin contamination.     

Aspergillus flavus infection and aflatoxin contamination in sorghum seeds and their biological management

In order to establish the current scenario of aflatoxigenic fungal infection and aflatoxin contamination in sorghum seeds across India, 58 seed samples were collected from different agro-climatic regions. Among these, 67.2% samples were infected with Aspergillus spp. and 28% were found contaminated with aflatoxins ranging from 0.0 to 130?μg?kg^?1. Greenhouse studies revealed no correlation between incidence of Aspergillus flavus and aflatoxin content, and its effect on seed quality parameters. Among the 37 A. flavus strains isolated, six were non-aflatoxigenic when analysed through cultural, TLC and ic-ELISA. Seed treatment with biocontrol agents (antagonistic Rhizobacteria and Trichoderma) suppressed the growth of A. flavus under laboratory and significantly enhanced seed quality variables under greenhouse conditions to a various extent. Field trials with selected biocontrol agents showed that talcum powder formulations of Pseudomonas putida Has-1/c, Bacillus spp. 3/a, Trichoderma asperellum M5 and T. asperellum T2 improved seedling emergence, % nutrient accumulation in plants, increased plant biomass and 1000 seed weight. Seeds harvested from treated plants showed significant increase in seed quality variables under laboratory and greenhouse conditions in comparison with control, but there was no significant difference in A. flavus infection and aflatoxin was completely absent in all treatments.     

Fungal and aflatoxin contamination of medicinal herbs

Since the consumption of aromatic and medicinal herbs has been increasing in the last years, the Argentinian Health Authorities are concerned to control the quality and security of them. Fungal and aflatoxin contamination are two parameters to be taken into account, to ensure the harmlessness of the phytomedicinal products. In 81 different samples, grouped in end products (EP), raw material (RM) and at harvest (SH), fungal flora (enumeration and identification) as well as naturalAspergillus flavus and aflatoxin occurrence were investigated. In all samples fungal counts fulfilled the international general recommendation limits (maximum 10⁵ cfu/g). Predominant flora was made up by xerophilic species ofAspergillus(100%), byPeniciIlium (< 50%) and in less percentage byFusarium (5.6%). Among the Aspergilli, A.flavus was present in all the three groups of samples. Using a TLC method, 47% of A. flavus isolates were toxinogenic, producing aflatoxin B₁ and B₂. In herbs, 4.7% of RM samples were naturally contaminated with aflatoxins B₁ and B₂. Considering the carcinogenic activity of aflatoxins it is essential to regulate them in the raw material (vegetal drug).     

Advances in molecular detection of Aspergillus: an update

Filamentous cosmopolitan fungi of the genus Aspergillus can be harmful in two ways, directly they can be opportunistic pathogens causing aspergillosis and indirectly due to aflatoxin production on food products which can lead to aflatoxicosis. Therefore, a number of methods have been proposed so far for detection of the fungi with lowest possible concentration at the earliest. Molecular methods such as PCR and/or in combination with certain techniques have been found to be useful for Aspergillus detection. We discuss here various technologies that have emerged in recent years and can possibly be used for the molecular detection of Aspergillus in an efficient way. These methods like RSIC, C-probe, and inversion probe with pyrosequencing or direct ss/dsDNA detection have been used for the identification of fungal or bacterial pathogens and thus formulate a ‘gold standard’ for Aspergillus detection.     

Growth of spoilage mould and aflatoxin B1 production in naturally contaminated or artificially inoculated maize as influenced by moisture content under ambient tropical condition

Maize (cv. TSZB) samples were re-moistened to different moisture contents (m.c.s) of 13, 15, 17, 20, 25, 30 or 35% and stored with the natural microflora or sterilized before artificial inoculation with either single or mixed moulds (Aspergillus flavus, A. niger, Penicilium purpurogenum and Fusarium moniliforme) and evaluated for initiation time for moulding, fungal populations and aflatoxin B₁ production. Whereas the fungal populations of naturally contaminated maize of 13% m.c. decreased significantly with storage, 17 and 20% m.c. maize increased with the latter showing maximum of about log₁₀ 7 colony forming units (cfu g⁻¹). Of the samples (13, 15, 17 or 20% m.c. maize), only those of ≥20% m.c. showed hazardous levels (>20 ppb) of aflatoxin B₁ production. The 20% m.c. sample also showed a significant positive correlation (r = 0.92) between m.c. and fungal load but those of lower m.c.s exhibited poor correlations, probably reflecting the absence of changes in the m.c.s of the 13, 15 and 17% m.c. maize. Aflatoxin B₁ content of 25% m.c. maize increased with increase in inoculum concentration of A. flavus. Mixed mould inoculation of maize samples resulted in a reduction in aflatoxin concentration with co-cultures of A. flavus and P. purpurogenum showing the lowest production, while that inoculated with A. flavus alone (control) exhibiting the maximum production. Initiation time for moulding was most rapid in ≥20% m.c. maize irrespective of inoculum type, with A. flavus being the most invasive in singly inoculated samples. However, A flavus was most competitive in 20–30% m.c. maize inoculated with mixed moulds, while F. moniliformewas most competitive in the 35% m.c. maize.     

黄曲霉功能基因组学研究

黄曲霉（Aspergillus flavus）是一种常见的腐生真菌和条件致病菌,其次生代谢产物黄曲霉毒素（Aflatoxin,AFT）具有高度的致癌性和致畸性,严重危及人类和动物健康。近年来,功能基因组学研究发展迅速,在真菌生长发育、挖掘真菌次级代谢产物以及研究包括黄曲霉毒素在内的真菌毒素等方面得到了广泛的应用。功能基因组学在研究黄曲霉与宿主之间的相互作用以及黄曲霉与其他曲霉之间的相互作用方面具有巨大的潜力。然而,黄曲霉功能基因组学受到细胞壁难以破除、耐药性高、筛选标记少、缺陷型菌株构建费力耗时等因素的影响而发展缓慢。概述了黄曲霉的选择标记、遗传转化方法和黄曲霉毒素以及环匹阿尼酸（cyclopiazonic acid, CPA）生物合成的研究进展,并讨论了在提高黄曲霉基因操作效率方面的潜在策略。例如,构建缺乏非同源末端连接（NHEJ）途径的菌株、Cre-loxP重组系统、CRISPR-Cas9等方法,为深入开展黄曲霉遗传学研究提供参考。     

Environmental distribution and genetic diversity of vegetative compatibility groups determine biocontrol strategies to mitigate aflatoxin contamination of maize by Aspergillus flavus

Maize infected by aflatoxin‐producing Aspergillus flavus may become contaminated with aflatoxins, and as a result, threaten human health, food security and farmers' income in developing countries where maize is a staple. Environmental distribution and genetic diversity of A. flavus can influence the effectiveness of atoxigenic isolates in mitigating aflatoxin contamination. However, such information has not been used to facilitate selection and deployment of atoxigenic isolates. A total of 35 isolates of A. flavus isolated from maize samples collected from three agro‐ecological zones of Nigeria were used in this study. Ecophysiological characteristics, distribution and genetic diversity of the isolates were determined to identify vegetative compatibility groups (VCGs). The generated data were used to inform selection and deployment of native atoxigenic isolates to mitigate aflatoxin contamination in maize. In co‐inoculation with toxigenic isolates, atoxigenic isolates reduced aflatoxin contamination in grain by > 96%. A total of 25 VCGs were inferred from the collected isolates based on complementation tests involving nitrate non‐utilizing (nit^?) mutants. To determine genetic diversity and distribution of VCGs across agro‐ecological zones, 832 nit^? mutants from 52 locations in 11 administrative districts were paired with one self‐complementary nitrate auxotroph tester‐pair for each VCG. Atoxigenic VCGs accounted for 81.1% of the 153 positive complementations recorded. Genetic diversity of VCGs was highest in the derived savannah agro‐ecological zone (H = 2.61) compared with the southern Guinea savannah (H = 1.90) and northern Guinea savannah (H = 0.94) zones. Genetic richness (H = 2.60) and evenness (E₅ = 0.96) of VCGs were high across all agro‐ecological zones. Ten VCGs (40%) had members restricted to the original location of isolation, whereas 15 VCGs (60%) had members located between the original source of isolation and a distance > 400 km away. The present study identified widely distributed VCGs in Nigeria such as AV0222, AV3279, AV3304 and AV16127, whose atoxigenic members can be deployed for a region‐wide biocontrol of toxigenic isolates to reduce aflatoxin contamination in maize.     

N-carboxymethylchitosan inhibition of aflatoxin production: Role of zinc

Aqueous Solutions of N-carboxymethylchitosan (NCMC) suppressed both growth and aflatoxin production byAspergillus flavus andA. parasiticus in submerged culture (Adye and Mateles A&M). Test media were amended with various concentrations of zinc (15, 30, 45, 60 uM), and NCMC solution (0.62 uM). After 8 days incubation NCMC-treated cultures showed marked reduction of aflatoxin production and fungal growth. Enhanced levels of zinc did not overcome the NCMC-mediated inhibition of fungal growth or aflatoxin production.     

Global population structure and adaptive evolution of aflatoxin‐producing fungi

Aflatoxins produced by several species in Aspergillus section Flavi are a significant problem in agriculture and a continuous threat to human health. To provide insights into the biology and global population structure of species in section Flavi, a total of 1,304 isolates were sampled across six species (A. flavus, A. parasiticus, A. nomius, A. caelatus, A. tamarii, and A. alliaceus) from single fields in major peanut‐growing regions in Georgia (USA), Australia, Argentina, India, and Benin (Africa). We inferred maximum‐likelihood phylogenies for six loci, both combined and separately, including two aflatoxin cluster regions (aflM/alfN and aflW/aflX) and four noncluster regions (amdS, trpC, mfs and MAT), to examine population structure and history. We also employed principal component and STRUCTURE analysis to identify genetic clusters and their associations with six different categories (geography, species, precipitation, temperature, aflatoxin chemotype profile, and mating type). Overall, seven distinct genetic clusters were inferred, some of which were more strongly structured by G chemotype diversity than geography. Populations of A. flavus S in Benin were genetically distinct from all other section Flavi species for the loci examined, which suggests genetic isolation. Evidence of trans‐speciation within two noncluster regions, whereby A. flavus S_BG strains from Australia share haplotypes with either A. flavus or A. parasiticus, was observed. Finally, while clay soil and precipitation may influence species richness in Aspergillus section Flavi, other region‐specific environmental and genetic parameters must also be considered.     

Environmental and developmental factors influencing aflatoxin production by <Emphasis Type="Italic">Aspergillus flavus</Emphasis> and <Emphasis Type="Italic">Aspergillus parasiticus</Emphasis>

Aflatoxins are carcinogenic mycotoxins formed by a number of fungi in the genus Aspergillus. The major fungi responsible for aflatoxin formation in crop seeds in the field and in storage are Aspergillus flavus and A. parasiticus. This review emphasizes developmental, environmental, biological, and chemical factors that influence aflatoxin formation by A. flavus and A. parasiticus.     

Aflatoxin-producing Aspergillus species from saffron field soils in the South Khorasan province of Iran

The aim of the present study was to isolate and identify Aspergillus species associated with saffron plants in the city of Birjand (South Khorasan Province, Iran) as well as to assess their aflatoxin B1 production. Sampling was performed during 2013–2014 crop season. Aspergillus species were isolated and purified using general and specific culture media. Growth rates and macroscopic and microscopic characteristics of the isolates were determined using yeast extract, Czapek yeast extract, malt extract and creatine sucrose agar media at 25 and 37 °C. DNA was extracted by the modified CTAB method and beta-tubulin, calmodulin and internal transcribed spacer genes were amplified and sequenced. Phylogenetic position of the isolates was determined against other Aspergillus species. Thin layer chromatography was used to investigate the production of aflatoxin B1 by Aspergillus isolates. Based on the morphological characteristics, shape and colour of the colonies, and sequencing results, the isolates belonged to Aspergillus terreus, A. flavus, A. flavipes and A. niger species. Only A. flavus isolates were aflatoxin B1 producers. We concluded that the soil of the studied saffron fields contained several species of Aspergillus, with A. flavus significantly affecting crop production through contamination of the crop by aflatoxin.     

Contamination of Groundnut in South‐Western Nigeria by Aflatoxigenic Fungi and Aflatoxins in Relation to Processing

Groundnut is commonly consumed in its roasted form by many Nigerians. This study was therefore conducted to determine the levels of aflatoxin in roasted groundnut retailed in south‐western Nigeria with a view to assessing the fitness of the processed nut for human consumption. The effects of roasting and de‐coating as alternative methods for reducing the ‘aflatoxin scare’ in the nut were further assessed on aflatoxigenic fungal load and aflatoxin content of the nuts. Forty‐eight samples of retailed raw and roasted groundnut were collected and assessed by mycological and thin‐layer chromatographic analysis for changes in aflatoxigenic fungal population and aflatoxin concentration, respectively. Consequently, 480 isolates of the Aspergillus section Flavi group, A. flavus L strain (n = 410), A. tamarii (n = 56), A. parasiticus (n = 7) and A. parvisclerotigenus (n = 7), were recovered from all samples. Aflatoxigenic isolates of A. flavus L strain (58.8%) had a significantly (P < 0.05) higher incidence than the non‐aflatoxigenic isolates (41.2%). Aflatoxins were detected in 43 (89.6%) of the samples. Approximately 25% of all samples exceeded the 20 ng/g limit for aflatoxin B₁ (AFB₁) adopted by the National Agency for Food and Drug Administration and Control while 83 and 79% of all samples contained AFB₁ and total aflatoxins above the European Union limits of 2 and 4 ng/g, respectively. Aflatoxin concentrations in the raw and coated samples were as much as five times higher than those in the roasted and de‐coated nuts, respectively. However, no significant difference was recorded between aflatoxin levels in the coated and de‐coated samples. This study has shown that roasting of groundnut and testa removal (de‐coating) are effective processing interventions that can significantly lower aflatoxin quantities in the kernels, thus making it fit for human consumption.     

First record of Aspergillus oryzae (Eurotiales: Trichocomaceae) as an entomopathogenic fungus of the locust,Locusta migratoria (Orthoptera: Acrididae)

A novel entomopathogenic fungus of Locusta migratoria was identified as Aspergillus oryzae using a comparative sequence analysis of the internal transcribed spacer regions, aflatoxin B₁ detection and morphological analysis. The fungus isolated from a dead locust collected in northwestern China was found to be pathogenic to the insect. Phylogenetic experiments revealed a 99% similarity between the fungus and those of three species, A. oryzae, Aspergillus flavus and Aspergillus parvisclerotigenus which are in the same branch of the Flavi section of the genus Aspergillus. Tests to detect aflatoxin B₁ demonstrated that this fungus is a non-aflatoxin B₁ producer, unlike A. parvisclerotigenus. Furthermore, morphological comparison with A. oryzae and A. flavus revealed that Aspergillus sp. XJ-1 belongs to A. oryzae, and named as A. oryzae XJ-1. The results of bioassays against third-instar locusts showed that mortality was dose-dependent and its median lethal concentrations were 3.3 × 10⁸, 1.7 × 10⁷ and 7.2 × 10⁶ conidia/ml on the 10th-, 13th- and 15th-day post-inoculation. Therefore, the A. oryzae XJ-1 may have biocontrol potential against locusts.     

Isolation of Bacterial Antagonists of Aspergillus flavus from Almonds

Bacteria were isolated from California almond orchard samples to evaluate their potential antifungal activity against aflatoxin-producing Aspergillus flavus. Fungal populations from the same samples were examined to determine the incidence of aflatoxigenic Aspergillus species. Antagonistic activities of the isolated bacterial strains were screened against a nonaflatoxigenic nor mutant of A. flavus, which accumulates the pigmented aflatoxin precursor norsolorinic acid (NOR) under conditions conducive to aflatoxin production. Using solid and liquid media in coculture assays, 171 bacteria isolated from almond flowers, immature nut fruits, and mature nut fruits showed inhibition of A. flavus growth and/or inhibition of NOR accumulation. Bacterial isolates were further characterized for production of extracellular enzymes capable of hydrolyzing chitin or yeast cell walls. Molecular and physiological identification of the bacterial strains indicated that the predominant genera isolated were Bacillus, Pseudomonas, Ralstonia, and Burkholderia, as well as several plant-associated enteric and nonenteric bacteria. A set of 20 isolates was selected for further study based on their species identification, antifungal phenotypes, and extracellular enzyme production. Quantitative assays using these isolates in liquid coculture with a wild-type, aflatoxin-producing A. flavus strain showed that a number of strains completely inhibited fungal growth in three different media. These results indicate the potential for development of bacterial antagonists as biological control agents against aflatoxigenic aspergilli on almonds.