Skip to main content
Download PDF
Download ePub

Distribution of indigenous strains of atoxigenic and toxigenic Aspergillus flavus and Aspergillus parasiticus in maize and peanuts agro-ecological zones of Kenya

Agriculture & Food Security volume 4, Article number: 14 (2015) Cite this article

Abstract

Background

Grains of important food and export crops in Africa are susceptible to contamination by toxin-producing moulds. Aflatoxins are mycotoxins associated with liver damage and cancer in humans and animals. These toxic substances are produced by fungi (such as Aspergillus flavus and Aspergillus parasiticus) in food and feed exposed to poor conditions during crop cultivation, storage or processing of harvest. The presence of aflatoxins in especially maize and peanuts in Kenya is of great concern. Recent developments in the application of atoxigenic strains of these fungi as biological control agents against toxigenic strains could be a solution to the problem. The objective of this study was to isolate, identify and characterize atoxigenic and toxigenic strains of A. flavus and A. parasiticus in Kenya, and investigate possible application of atoxigenic strains in control of aflatoxin levels in maize and peanuts. Fungal communities in soils of maize and peanut fields were examined to determine the distributions of aflatoxin-producing Aspergillus species and to identify endemic atoxigenic strains. 220 isolates belonging to A. flavus and A. parasiticus were collected randomly from soils of maize and peanuts fields in seven agro-ecological zones and characterized using morphological and physiological examination.

Results

Aspergillus section Flavi was detected in all the 57 soil samples collected in Kenya. Members of Aspergillus section Flavi L strain was the most common (54 %), followed by S-strains (35 %). Among Aspergillus, A. flavus was the most predominant (63.2 %), followed by A. parasiticus (27.7 %), A. tamari (5.5 %) and A. nomius (2.7 %). The mean CFU of the Aspergillus colonies per gram of soil was highly variable among the districts, ranging from 3.0 × 103 to 1.72 × 106 (p < 0.05). The mean pH across the collection sites also varied according to the respective agroecological zones (pH 5.5–6.8) which is within the optimal pH requirement for the members of section Flavi. There was no significant variation in temperature across the sampling sites (p > 0.05). The results also showed that A. flavus was detected in all the zones examined.

Conclusions

Each of the regions had atoxigenic strains of potential value which can be employed as biological control agents in the management of aflatoxicoses.

Background

The genus Aspergillus, a member of the phylum Ascomycota, includes over 185 known species. Members of Aspergillus section Flavi are characterized by their ability to produce flavine-derived secondary metabolites which include the aflatoxins. Aflatoxins are mycotoxins associated with hepatotoxicity, mutagenicity and carcinogenicity in humans and animals [1, 2]. Species capable of producing aflatoxins include Aspergillus flavus, Aspergillus parasiticus, and several less common taxa such as Aspergillus nomius, Aspergillus tamarii, A. pseudotamarii, A. minisclerotigenes and A. bombycis [3, 4]. Other Aspergillus outside of the section Flavi are also known to produce aflatoxins and species with this ability have been shown to be more diverse than previously thought [5].

Grains of important food and export crops in Africa, such as maize and peanuts, are susceptible to contamination with different toxin-producing moulds. Of particular importance are aflatoxins that pose serious health risks to humans and animals. In Kenya, the toll on human health from periodic outbreaks that record case fatality rates of 39 % [6] remain common. In addition, food grains contaminated with aflatoxin-producing fungi also lose their quality based on nutritional value, taste, smell, appearance, and are no longer suitable for consumption or sale. The major challenge is that the contaminated cereals such as maize may appear just like normal grains without any outward physical signs of fungal infection [7].

The earliest reported case of aflatoxicosis in Kenya was in 1977, where several dogs and poultry died in Nairobi, Coast and Rift Valley Provinces after feeding on poorly stored grains, while in 1978, samples of human and dog food (flour) were found to be contaminated with [8]. In 1984, twelve people died in Machakos district of Kenya after consuming aflatoxin contaminated maize, while in 1995, about 172 samples of maize analyzed were found to have aflatoxin. In 2004, there was an outbreak of acute aflatoxicosis in Kenya, one of the most severe episodes of human aflatoxin poisoning in history. A total of 317 cases were reported by July 2004, with a case fatality rate of 39 % [9, 10]. This epidemic resulted from ingestion of contaminated maize [11]. Other outbreaks occurred in 1981, 2001, 2004, 2005, 2006, 2007 and 2008 resulting in sickness, death and destruction of contaminated maize [8, 9, 1113]. Maize from the affected areas contained as much as 4400 ng g−1 aflatoxin B1, which is 440 times greater than the 10 ng g−1 tolerance level set by the Kenya Bureau of Standards. Most of the aflatoxin poisoning outbreaks occurred in remote villages and, therefore, the number of people affected could have been higher than reported [11]. The aflatoxin contamination in maize has been associated with drought combined with high temperatures as well as insect injury [14].

Aspergillus flavus and the closely related subspecies A. parasiticus have a world-wide distribution and normally occur as saprophytes in soil and on many kinds of decaying organic matter. They readily infest several important crops such as corn, cottonseeds, peanuts and tree nuts. They are widely distributed with greater quantities of the fungus occurring in warm climates [4, 15].

Gene flow within A. flavus is primarily limited by a vegetative compatibility system [16, 17] that delineates the species into numerous genetic groups called Vegetative Compatibility Groups (VCGs). A. flavus VCGs clonal lineages [18] that exist in complex communities are composed of many VCGs. VCGs vary in many characteristics; including aflatoxin-producing ability. Populations of A. flavus in an individual agricultural field contain isolates of many VCGs [4, 19]. VCGs with aflatoxin-producing potential are known to vary less among isolates within a VCG than among isolates from different VCGs [18]. Communities resident in different fields, areas, and regions may vary widely in average aflatoxin-producing ability [2022]. Isolates and VCGs that do not produce aflatoxin, called atoxigenic, are common within A. flavus communities [2023]. Surveys of A. flavus isolates from various geographic regions have revealed differences in the proportions of isolates that produce low, medium, and high amounts of aflatoxins [5, 24, 25]. For instance, in Argentina [26] and Iran [27] less than 30 % of the A. flavus isolates were capable of producing aflatoxin whereas in Nigeria the number was much higher, exceeding 50 % [28]. In the southern USA most A. flavus isolates produce aflatoxin [24, 25]. In the USA, there are currently several atoxigenic strains of A. flavus used to reduce crop contamination.

Biological control strategies directed at utilizing non-aflatoxin (atoxigenic) strains to limit aflatoxin contamination on crops have been pursued for almost two decades [29]. These strategies seek to give atoxigenic strains a competitive edge and exclude their aflatoxin-producing relatives, therefore decreasing the potential for contamination in crops and the environment. Successful strategies have been accomplished by using native non-aflatoxin-producing strains such as A. flavus [30].

In this study, we sought to identify the natural occurence of different strains/species of Aspergillus and to identify the ecological prevalence of both aflatoxin-producing and non-producing strains. Identification of the proportion of non-aflatoxin-producing strains in natural environments is an important step towards estimating their applicability in the biological control of the more medically and economically important toxigenic strains in Kenya.

Methods

Field survey locations

Field surveys were done in 6 agro-ecological zones (AEZ) in Kenya where maize and peanut crops are widely cultivated. The study covered 5 districts Makueni (1.8°S, 37.62°E), Makindu (−1°17′31.437″, 36°49′19.005″N/E), Kwale (3°3′4°45′, 38°31′39°31′), Kibwezi (−2°25′00″S, 37°58′00″E) and Msambweni (4°29′29.8″S, 39°28′33.7″E) (currently counties) selected due to their historical association with frequent and serious outbreaks of aflatoxin contamination of farm produce. To assess fungal populations, soil samples were collected from 57 fields arbitrarily chosen within the different districts and agroecological zones on the condition that fields were radially separated by at least 5–20 km from each other. A field was equivalent to a small-holder subsistence farm.

Sample collection and preparation

Soil samples were collected and processed as described by Dorner et al. [31]. From each field, three to five scoops were randomly taken using a sterile trowel from the top 4–6 cm of soil. Samples were transported in sterile containers to the Kenyatta University laboratory where they were sorted, pooled per field, oven-dried at 40 °C for 5 days, and stored in sealed plastic bags at room temperature (22–26 °C) until use. Aliquots of soil for pH measurements were suspended in distilled H2O (20 % soil, wt/vol).

Isolation and quantification of fungal species

For fungal isolation, soil samples were retrieved from storage, dried in a forced air oven (48–50 °C for 48 h), pulverized in plastic bags to remove clods and homogenized by hand-mixing.

Aspergillus section Flavi were isolated and quantified by the dilution plate technique on Modified Rose Bengal Agar (MRBA), [32]. In sterile 7 ml capacity polystyrene tubes, 1 g of soil was suspended in 3 ml of sterile water, mixed for 20 min on a rotary shaker, and plated on MRBA at appropriate dilutions. Dilution was to allow colony densities of less than 10 per plate. Plates were incubated in the dark for 3 days at 31 °C. Colonies of Aspergillus section Flavi were then identified by colony morphology. About 5–10 isolates per soil sample were transferred to 5/2 agar (5 % V-8 juice and 2 % agar, pH 5.2) and grown for 5 more days, unilluminated at 31 °C. Isolates were then classified on the basis of colony characteristics and conidial morphology at ×400 magnification. Aspergillus section Flavi colonies were identified by their characteristic growth pattern, retention of Rose Bengal within mycelia, and production of characteristic conidiophores after 3 days on MRBA. Isolates with abundant small sclerotia (average diameter <400 mm) were preliminarily classified as strain SBG [5] while isolates with smooth conidia and large sclerotia (average diameter over 400 mm) were classified as the L strains of A. flavus [33]. A. tamarii, A. nomious and A. parasiticus were initially identified by colony and spore morphology [3]. All preliminary identifications were confirmed by color reaction on AFPA (A. flavus and A. parasiticus agar) [34]. Quantities of Aspergillus section Flavi in soils were calculated as colony-forming units (CFU) per gram of soil. Several 3 mm plugs of sporulating culture were transferred to 4-dram vials containing 5 ml of sterile distilled H2O. These conidial suspensions were maintained at 4 °C for further analysis.

Aflatoxin-production by the fungal isolates

To determine the relative frequency of toxigenic and atoxigenic strains of Aspergillus section Flavi strain distribution across the country, isolates were randomly selected from each of the collection sites in order to determine their aflatoxin-production capability and also to establish the strains that produce the greatest quantities of aflatoxins and the frequency of occurrence of non-aflatoxin producers in Kenya. A total of 57 isolates (both L and S strains) were fermented in Adye and Matales medium with 22.4 mM urea as the sole nitrogen source and adjusted to pH 4.7 prior to autoclaving [5]. Vials (15 ml containing 5 ml A&M) were seeded with approximately 2 × 103 conidia suspended in 100 ml water. After incubation at 32 °C in the dark for 5 days, the pH of the medium was measured, 3 ml acetone was added, and the contents mixed by inversion. Vials were allowed to set for 1 h to allow lysis of fungal cells and extraction of aflatoxins from mycelia and conidia. Subsequently, the mycelia was collected on Whatman No. 4 filter paper, dried in a forced air oven (48 °C, 3 days), and weighed to quantify fungal biomass. The filtrate was diluted appropriately, spotted alongside standards of aflatoxin B1, B2, G1 and G2 (BORATEC limited, Kenya), and separated on thin layer chromatography (TLC) plates (silica gel 60, 20 mm) with the development solvent being a mix of diethyl ether, methanol and water in a 96:3:1 ratio. Aflatoxin was quantified in situ on the TLC plates with a scanning densitometer (model cs-930, Shimadzu Scientific Instruments, Inc., Tokyo). Extracts that initially did not show detectable aflatoxins were diluted with an equal volume of water and extracted with 3 ml methylene chloride to concentrate any latent aflatoxin. Aflatoxins were partitioned into the methylene chloride fraction, from which they can be retrieved by drying and the residues dissolved in 100 ml of methylene chloride. The solution was then subjected to TLC as already described.

Data analysis

Analyses were done with SPSS version 15.0 for Windows (release 15.0.0, Vista Hotfix Applied) and Microsoft Excel 2007. Pearson correlation coefficients were generated to assess relationships of ecological and biological variables with α = 0.05 and 0.01 for a 2-tailed t test. Analysis of variance was performed on all data with the general linear model (GLM), suitable for unbalanced data. The analyses for percentage values, CFU g−1, and aflatoxin concentrations were preformed with data transformed, using the arcsine of the square roots, the natural logarithms (ln), and the logs (count +1), respectively. Sampling sites and the agroecological zones were treated as class variables.

Results

Distribution of Aspergillus section Flavi in Kenya

Aspergillus section Flavi was detected in all the soil samples from 57 fields situated within the AEZs studied. A total of 220 section Flavi colonies were successfully transferred from MRBA to 5/2 agar and subsequently identified by macroscopic, microscopic and growth characteristics in AFPA medium. Out of all the Aspergillus section Flavi isolates, A. flavus was predominant (63.8 % of section Flavi), followed by A. parasiticus (28 %), A. tamarii (5.6 %) and about 2.3 % of the isolates assigned to A. nomius (a recently discovered strain among the Section Flavi) as shown in Table 1.

Table 1 Proportions of Aspergillus section Flavi of fields in five districts, soil pH, and colony-forming units per gram of soil in Kenya across the sampled agroecological zones
Full size table

The most common group (forming 85 % of the Aspergillus section Flavi isolated from the seven AEZs) were identified as L- strain with an average of 60.6 % in all the districts. The S- strains had a mean incidence of 39.4 %. Kwale district had the highest incidence of L strains (73 %) and the least of S-strain, while the reverse was true in Kibwezi district (L-strain being 48.5 % and S-strains being 51.5 %), (Table 1; Fig. 1).

Fig. 1
figure 1

Microscopic features of Aspergillus spp Conidial features (×400)

Full size image

The mean colony-forming units (CFU/g of soil) of the Aspergillus were extremely variable among the districts, ranging from 3.0 × 103 to 2.6 × 106. The CFU counts were significantly different between the districts. However, the CFU counts were not significantly different within the agroecological zones (p > 0.05), (Table 2).

Table 2 Pearson’s correlation coefficients of relationships among the quantity of Aspergillus section Flavi population in soil (CFU g−1), soil pH, AEZ and the isolates
Full size table

There was a significant positive correlation (0.594, p = 0.009) between pH and the proportion of S strains in the sampled colonies. On the other hand, the correlation of pH and the percentage of L strains was negative (−0.594, p = 0.005). The proportions of L and S strains in the CFU yield was negatively correlated (Table 2).

The mean soil pH among the districts sampled ranged from 6.12 in Kwale (weakly acidic) to 7.19 (weakly alkaline) in Kibwezi district (Table 1).

Incidences of toxigenic and atoxigenic strains of aspergillus section Flavi in Kenyan districts

A total of 57 isolates, each representing the collection sites were randomly examined for their aflatoxin-production potential. Out of all the isolates, 45.9 % were positive for different aflatoxins and were categorized as toxigenic. On the other hand, 54.1 % showed no detectable aflatoxins in their TLC profiles (Fig. 2), hence they were classified as atoxigenic strains. Msambweni district had the lowest atoxigenic/toxigenic strain ratio (41.7:58.3 %) while Makindu district had the highest atoxigenic/toxigenic strain ratio (75:25 %) (Table 3; Fig. 1).

Fig. 2
figure 2

An example of TLC profiles of Toxigenic and atoxigenic strains

Full size image
Table 3 Incidence of atoxigenic and toxigenic strains surveyed in all the 57 sites within the districts in Kenya
Full size table

Aflatoxin production by toxigenic strains and quantification

Aflatoxin-producing aspergilli were isolated from all the districts surveyed (Table 3). As expected, A. flavus and A. tamari produced only B aflatoxins while A. parasiticus produced both B and G subtypes. Aflatoxin-producing potential varied widely among isolates from the same districts, and agroecological zones (Table 3). Only two isolates of A. tamarii produced detectable aflatoxin (B). Aspergillus nomius isolates did not show any toxigenic potential.

The majority of aflatoxin producers were the L type members of section Flavi. However, the highest concentrations of aflatoxins were detected among the S type strains ranging from 2.25 × 105 to 4.65 × 106 ng g−1. Mean aflatoxin production varied significantly among the districts with the least being Kibwezi (4.0 × 103 ng g−1) and the highest being Kwale (4.65 × 106 ng g−1) (Tables 3, 4). The B aflatoxins were the most common metabolite (70.5 % as compared to the BG aflatoxins, 29.5 %) (Table 3).

Table 4 Aflatoxin production and quantification among isolates
Full size table

Discussion

Aspergillus section Flavi were detected in all 57 soil samples collected from various agroecological zones of maize and peanut growing areas in Kenya. This widespread distribution and prevalence conforms to previous findings of similar studies in Israel, Thailand, North America and West Africa [19, 28, 35]. Several members of the section Flavi including A. niger, A. fumigatus, A. clavatus, A. ochraceus, A. terreus and A. versicolor have been shown to be major mycotoxin-producing contaminants in various agricultural produce in Kenya. Our study supports a high incidence of Aspergillus section Flavi with A. flavus being the most predominant (63.2 %), A. flavus could indeed be linked to B1 aflatoxicosis contamination that has been shown to be prevalent as was determined by Probst et al. [9]. Members of A. parasiticus were less prevalent but nevertheless produced high concentrations of both B and G aflatoxins (Tables 3, 4). They, therefore, contributed significantly to the aflatoxicosis potential of resident fungal communities, a situation similar to that observed in West Africa by Donner et al. [28]. While all species produced B aflatoxin in different quantities, only A. parasiticus produced G aflatoxins among all groups studied in Kenya.

The negative correlation of pH and proportions of L strains could be an indication of the poorer adaptation of these strains to higher pH optima compared to the S strains. However, the adaptations of the two strains is not mutually exclusive as each of the two strains occur in different proportions within all the pH ranges observed. In addition, the range of soil pH variation across the examined regions was narrow, ranging from weak acidic to weak alkaline. The higher incidence of S strains in more alkaline soils has previously been observed in North American soils among isolates of A. parasiticus, A. tamarii and A. flavus [24]. However, in Nigeria [28], a negative correlation was observed. The effect of pH has been shown to play a lesser role in A. flavus population dynamics, with climate being cited as a more important determinant [35]. Therefore, other shared factors within the study areas such as temperature maxima of 40 °C, average humidity, semi aridity and transitional savannah ecosystems provide a range of biophysical conditions conducive for elevated levels of aflatoxin-producing fungi.

The aflatoxin-producing potential of Aspergillus communities is higher when S strain is present, as L strain isolates produce on average only 33 % of the toxin yield from S strain isolates [24]. In West Africa, S strain isolates produce greater quantities of aflatoxins than L strain isolates. This corroborates the finding of this study, in which the S strains produced the highest concentration of aflatoxins in Kenya. All the isolates of A. flavus (both L and S strains) did not produce the G aflatoxins but produced the B toxins. The percentage of A. flavus L-strain isolates that produced aflatoxins varied with geography and climate (Fig. 3).

Fig. 3
figure 3

Incidence of toxigenic and atoxigenic isolates of aspergillus section Flavi from soil samples of maize and pea nut growing areas in Kenya. S-strain L-strain

Full size image

Aflatoxin-producing fungi vary widely in many characteristics, including virulence for crops and aflatoxin-producing capacity [33]. Aspergillus flavus and A. parasiticus are most commonly implicated as causal agents of aflatoxin contamination. Aspergillus flavus has two morphotypes, the typical or L strain (sclerotia of >400 µm in diameter) and the S strain (sclerotia of <400 µm in diameter) [33, 36]. S-strain isolates produce more aflatoxins than L-strain isolates, on average. Many L-strain isolates produce no aflatoxins (“atoxigenic”) [24].

All members of A. flavus lack the ability to synthesize G aflatoxins due to a 0.8–1.5 kb deletion in the 28-gene aflatoxin biosynthesis cluster [18]. In contrast to cases in the United States, studies conducted in West Africa found out that an unnamed taxon (sometimes called strain SBG) is commonly implicated in contamination events [5]. Strain SBG is morphologically similar to the S strain of A. flavus, but DNA-based phylogenies reveal strain SBG to be a distinct species ancestral to both A. flavus and A. parasiticus [37, 38].

Aflatoxin levels unacceptable for human consumption may occur even in areas with relatively low frequencies of aflatoxin producers. In the current study, 59.3 % of aflatoxin-producing L-strain isolates produced more than 10 × 105 ng g−1 (14.3 ppb) aflatoxin B1. This combined with high incidences allows the L-strain to be the largest contributor to the average aflatoxin-producing ability of fungal communities in the five districts (Fig. 1; Table 4) and a potentially important causal agent of contamination in Kenya. Similar results were observed in Nigeria [28]. This is in contrast, with earlier studies conducted in Kenya where the S-strain was observed to be the primary cause of maize aflatoxin contamination [9]. The current study shows that S-strain is present in low frequency or absent in certain sites.

Incidences of atoxigenic strains of section Flavi varied widely among districts and agroecological zones (Table 1). The non-aflatoxin-producing strains are common in crop environments [21, 23, 24]. The atoxigenic strains of A. flavus and/or A. parasiticus have been employed as biopesticides directed at minimizing crop contamination with aflatoxins [4, 39]. Successful and effective biocontrol strategies necessitates that high ratios of atoxigenic to toxigenic strains be exhibited [40]. In the current study, high incidences of atoxigenic strains of section Flavi members were found in Kibwezi and Makueni districts both in lower midland zones (LM3, LM4 and LM5). These native populations provide potential biological control agents to manage the toxigenic strains.

Aflatoxin contamination of crops can be minimized by early harvest, prevention of insect damage and proper storage [41]. However, despite the careful management, unacceptable aflatoxin levels may occur from unpreventable insect damage to the developing crop or from exposure of the mature crop to moisture either prior to harvest or during storage in modules, handling, transportation or even use [33].

For many diseases, traditional chemical control methods are neither always economical nor are they effective, and fumigation as well as other chemical control methods may have unwanted health, safety and environmental risks in Kenya and many other developing countries. The antifungal abilities of some beneficial microbes have been known since the 1930s, and there have been extensive efforts to use them for plant disease control since then. However, they are only now being used commercially [33].

Aflatoxins cannot be readily removed from contaminated foods by detoxification. Therefore, there is interest in developing a biological control method that can increase crop safety by decreasing toxin content and this depends on the competitive displacement of toxigenic isolates using atoxigenic isolates of the same species. It has also been reported that aflatoxin production is inhibited by lactic acid bacteria, Bacillus subtilis and many moulds. This inhibition may result from many factors including competition for space and nutrients. In general, competition for nutrients required for aflatoxin production but not for growth and production of anti-aflatoxigenic metabolites by co-existing micro-organisms [42].

Currently, atoxigenic A. flavus L-strain isolates are used to competitively exclude aflatoxin producers during crop infection and thereby limit contamination in U.S. agriculture [4]. Such atoxigenic strains are highly effective against the S strain [4]. Adaptation and deployment of similar technologies in Africa could provide a promising strategy for prevention of future aflatoxicoses in East Africa while enhancing export possibilities for maize and peanuts [43].

Aspergillus section Flavi was resident in all sampled maize fields and quantities of section Flavi were higher on average in Kenya and compares to the ones in West Africa [35]. The incidences of the section Flavi in Kenyan soils demonstrates the fungal growth on crop-associated with organic matter. Corncobs, peanut pods and other crop debris harbor section Flavi for at least 3 years after harvest [44].

This study has reported high level of atoxigenic species of Aspergillus section Flavi. In vitro analysis showed that there is a growth competition between atoxigenic and toxigenic spp of Aspergillus section Flavi. The existing methods of biological control of aflatoxicosis by use of the atoxigenic strains can therefore be tested and adapted to Kenyan agriculture. The study has also established that the production of aflatoxins by these species depends on the prevailing physiological conditions such as temperature and moisture. Poor management practices such as poor storage, late harvesting, among others are predisposing conditions for the proliferation of the fungi, so there is need for education on the best practices so as to minimize on contamination. Furthermore, morphological analysis of Aspergillus section Flavi is limited with mechanisms of getting the true identity of the fungal species. There is need to adopt rapid and sensitive molecular techniques to support the morphological identifications. Finally, there is need to screen all the farm produce for possible aflatoxin contamination to reduce economic burdens related to the menace. We, therefore, hope this study will be taken into consideration by regulatory authorities in Kenya and beyond.

Conclusion

In conclusion, we report an ubiquitous presence of the members of the Aspergillus section Flavi within maize and peanut growing fields in Kenya. The diversity is characterized by a significant presence of atoxigenic A. flavus and A. parasiticus. Such atoxigenic variants have been previously applied in the biological suppression of natural populations of toxigenic strains and thereby minimizing aflatoxin contamination in peanuts [40], corn [45] and cotton [4]. The existing methods of biological control of aflatoxicosis by use of atoxigenic strains can therefore be tested and adapted to Kenyan agriculture. Control of natural populations of aflatoxin-producing fungi will lead to overall reduction of aflatoxicosis in farm produce as reported to be common in the regions studied [7, 9].

Abbreviations

CFU:

colony-forming units

AEZ:

agroecological zones

TLC:

thin layer chromatography

AFPA:

Aspergillus flavus and Aspergillus parasiticus agar

MRBA:

Modified Rose Bengal Agar

VCGs:

Vegetative Compatibility Groups

References

  1. Hesseltine CW. A millennium of fungi, food, and fermentation. Mycologia. 1965;57:149–97.

    Article  CAS  PubMed  Google Scholar 

  2. Ainsworth GC, Austwick PKC. Fungal diseases of animals. 2nd ed. Slough: Commonwealth Agricultural Bureau; 1973.

    Google Scholar 

  3. Klich MA, Pitt JI. Differentiation of Aspergillus flavus from A. parasiticus and other closely related species. Trans Br Mycol Soc. 1988;91:99–108.

    Article  Google Scholar 

  4. Cotty PJ. Influence of field application of an atoxigenic strain of Aspergillus flavus on the populations of A. flavus infecting cotton bolls and on the aflatoxin content of cottonseed. Phytopathology. 1994;84:1270–7.

    Article  Google Scholar 

  5. Cotty PJ, Cardwell KF. Divergence of West African and North American Communities of Aspergillus Section Flavi. Appl Environ Microbiol. 1999;65:2264–6.

    PubMed Central  CAS  PubMed  Google Scholar 

  6. Centre for Disease Control. Outbreak of aflatoxin poisoning: Eastern and Central Provinces, Kenya. Weekly Reports. September 2004.

  7. Muthomi JW, Njenga LN, Gathumbi JK, Chemining’wa GN, et al. The occurrence of aflatoxins in maize and distribution of mycotoxin-producing fungi in Eastern Kenya. Plant Pathol J. 2009;8:113–9.

    Article  CAS  Google Scholar 

  8. Ministry of Agriculture (MOA) The role of post harvest in the control of aflatoxins in cereals and pulses. Ministry of Agriculture Headquarters, Nairobi 2008.

  9. Probst C, Njapau H, Cotty PJ. Outbreak of an acute aflatoxicosis in Kenya in 2004: identification of the causal agent. Appl Environ Microbiol. 2007;73:2762–4.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  10. Nyikal J, Misore A, Nzioka C, Njuguna C, Muchiri E, Njau J, Maingi S, Njoroge J, Mutiso J, Onteri J, Langat A, Kilei IK, Nyamongo J, Ogana G, Muture B, Tukei P, Onyango C, Ochieng W, Tetteh C, Likimani S, Nguku P, Galgalo T, Kibet S, Manya A, Dahiye A, Mwihia J, Mugoya I, Onsongo J, Ngindu A, DeCock KM, Lindblade K, Slutsker L, Amornkul P, Rosen D, Feiken D, Thomas T, Mensah P, Eseko N, Nejjar A, Onsongo M, Kesell F, Njapau H, Park DL, Lewis L, Luber G, Rogers H, Backer L, Rubin C, Gieseker KE, Azziz-Baumgartner E, Chege W, Bowen A. Outbreak of aflatoxin poisoning—Eastern and Central Provinces, Kenya, January–July 2004. Morb Mortal Wkly Rep. 2004;53:790–3.

    Google Scholar 

  11. Lewis L, Onsongo M, Njapau H, Schurz Rogers H, Luber G, Kieszak S. Aflatoxin contamination of commercial maize products during an outbreak of acute aflatoxicosis in eastern and central Kenya. Environ Health Perspect. 2005;113:1763–7.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  12. Bennett JW, Klich M. Mycotoxins. Clin Microbiol Rev. 2003;16:497–516.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  13. Kenya Plant Health Inspectorate Service (KEPHIS). Mycotoxins and Food Safety. KEPHIS Headquarters, Nairobi, Kenya 2006.

  14. Betran FJ, Isakeit T. Aflatoxin accumulation in maize hybrids of different maturities. Agron J. 2003;96:565–70.

    Article  Google Scholar 

  15. Boyd ML, Cotty P. Characterization of Aspergillus section Flavi communities from natural habitats in the Sonoran Desert. Inoculum. 1998;49:11.

    Google Scholar 

  16. Papa KE. Heterokaryon incompatibility in Aspergillus flavus. Mycologia. 1986;78:98–101.

    Article  Google Scholar 

  17. Bayman P, Cotty PJ. Vegetative compatibility and genetic diversity in the Aspergillus flavus population of a single field. Can J Bot. 1991;69:1707–11.

    Article  Google Scholar 

  18. Ehrlich KC, Cotty PJ. An isolate of Aspergillus flavus used to reduce aflatoxin contamination in cottonseed has a defective polyketide synthase gene. Appl Microbiol Biotechnol. 2004;65:473–8.

    Article  CAS  PubMed  Google Scholar 

  19. Ehrlich KC, Kobbeman K, Montalbano BG, Cotty PJ. Aflatoxin-producing Aspergillus species from Thailand. Int J Food Microbiol. 2007;114:153–9.

    Article  CAS  PubMed  Google Scholar 

  20. Schroeder HW, Boller RA. Aflatoxin production of species and strains of the Aspergillus flavus group isolated from field crops. Appl Microbiol. 1973;25:885–9.

    PubMed Central  CAS  PubMed  Google Scholar 

  21. Lisker N, Michaeli R, Frank ZR. Mycotoxigenic potential of Aspergillus flavus strains isolated from groundnuts growing in Israel. Mycopathologia. 1993;122:177–83.

    Article  CAS  PubMed  Google Scholar 

  22. Cotty PJ, Howell DR, Bock C, Tellez A. Aflatoxin contamination of commercially grown transgenic Bt cottonseed. In Proc. Beltwide Cotton Prod. Res. Conf. National Cotton Council of America, Memphis, TN; 1997. p. 108–110.

  23. Joffe AZ. Aflatoxin produced by 1,626 isolates of Aspergillus flavus from groundnut kernels and soils in Israel. Nature. 1969;221:492.

  24. Cotty PJ. Aflatoxin-producing potential of communities of Aspergillus section Flavi from cotton producing areas in the United States. Mycol Res. 1997;101:698–704.

    Article  Google Scholar 

  25. Horn BW, Dorner JW. Regional differences in production of aflatoxin B1 and cyclopiazonic acid by soil isolates of Aspergillus flavus along a transect within the United States. Appl Environ Microbiol. 1999;65:1444–9.

    PubMed Central  CAS  PubMed  Google Scholar 

  26. Vaamonde G, Patriarca A, Pinto VF, Comerio R, Degrossi C. Variability of aflatoxin and cyclopiazonic acid production by Aspergillus section flavi from different substrates in Argentina. Int J Food Microbiol. 2003;88:79–84.

    Article  CAS  PubMed  Google Scholar 

  27. Razzaghi-Abyaneh M, Shams-Ghahfarokhi M, Allameh A, Kazeroon-Shiri A, Ranjbar-Bahadori S, Mirzahoseini H, Rezaee M-B. A survey on distribution of Aspergillus section Flavi in corn field soils in Iran: population patterns based on aflatoxins, cyclopiazonic acid and sclerotia production. Mycopathologia. 2006;161:183–92.

    Article  CAS  PubMed  Google Scholar 

  28. Donner M, Atehnkeng J, Sikora RA, Bandyopadhyay R, Cotty PJ. Distribution of Aspergillus section Flavi in soils of maize fields in three agroecological zones of Nigeria. Soil Biol Biochem. 2009;41:37–44.

    Article  CAS  Google Scholar 

  29. Dorner JW. Biological control of aflatoxin contamination of crops. Toxin Rev. 2004;23:425–50.

    Article  CAS  Google Scholar 

  30. Cotty PJ, Mellon JE. Ecology of aflatoxin producing fungi and biocontrol of aflatoxin contamination. Mycotoxin Res. 2006;22:110–7.

    Article  CAS  PubMed  Google Scholar 

  31. Dorner JW, Cole RJ, Connick WJ, Daigle DJ, McGuire MR, Shasha BS. Evaluation of biological control formulations to reduce aflatoxin contamination in peanuts. Biol Control. 2003;26:318–24.

    Article  Google Scholar 

  32. Cotty PJ. Comparison of four media for the isolation of Aspergillus flavus group fungi. Mycopathologia. 1994;125:157–62.

    Article  CAS  PubMed  Google Scholar 

  33. Cotty PJ, Lee LS. Aflatoxin contamination of cottonseed: comparison of pink bollworm damaged and undamaged bolls. Trop Sci. 1989;29:273–277.

  34. Pitt JI, Hocking AD, Glenn DR. An improved medium for the detection of Aspergillus flavus and A. parasiticus. J Appl Bacteriol. 1983;54:109–14.

    Article  CAS  PubMed  Google Scholar 

  35. Cardwell KF, Cotty PJ. Distribution of Aspergillus section Flavi among field soils from the four agroecological zones of the Republic of Benin, West Africa. Plant Dis. 2002;86:434–9.

    Article  Google Scholar 

  36. Horn BW. Ecology and population biology of aflatoxigenic fungi in soil. Toxin Rev. 2003;22:351–79.

    Article  Google Scholar 

  37. Egel DS, Cotty PJ, Elias KS. Relationships among isolates of Aspergillus sect. Flavi that vary in aflatoxin production. Phytopathology. 1994;84:906–12.

    Article  CAS  Google Scholar 

  38. Ehrlich KC, Yu J, Cotty PJ. Aflatoxin biosynthesis gene clusters and flanking regions. J Appl Microbiol. 2005;99:518–27.

    Article  CAS  PubMed  Google Scholar 

  39. Dorner JW, Cole RJ, Blankenship PD. Effect of inoculum rate of biological control agents on preharvest aflatoxin contamination of peanuts. Biol Control. 1998;12:171–6.

    Article  Google Scholar 

  40. Dorner JW, Cole RJ, Blankenship PD. Use of a biocompetitive agent to control preharvest aflatoxin in drought stressed peanuts. J Food Prot. 1992;55:888–92.

    CAS  Google Scholar 

  41. Cotty PJ. Effect of harvest date on aflatoxin contamination of cottonseed. Plant Dis. 1991;75:312–4.

    Article  CAS  Google Scholar 

  42. Munimbazi C, Bullerman LB. Inhibition of aflatoxin production of Aspergillus parasiticus NRRL 2999 by Bacillus pumilus. Mycopathologia. 1998;140:163–9.

    Article  CAS  Google Scholar 

  43. Bankole SA, Adebanjo A. Mycotoxins in food in West Africa: current situation and possibilities of controlling it. African J Biotechnol. 2004;2:254–63.

    Google Scholar 

  44. Jaime-Garcia R, Cotty PJ. Aspergillus flavus in soils and corncobs in south Texas: implications for management of aflatoxins in corn-cotton rotations. Plant Dis. 2004;88:1366–71.

    Article  Google Scholar 

  45. Brown RL, Cotty PJ, Cleveland TE. Reduction in aflatoxin content of maize by atoxigenic strains of Aspergillus flavus. J Food Prot. 1991;54:623–6.

    CAS  Google Scholar 

Download references

Authors’ contributions

OOD carried out TLC analysis and drafted the manuscript. FMK participated in statistical analysis and manuscript drafting. MMG participated in the design of the study. NNJ and participated in sample collection and processing. FO was involved in fungal culturing. YOM participated in sample processing and fungal culture analysis. KUE conceived the study, was involved in design and coordination. All authors read and approved the final manuscript.

Acknowledgements

This study was funded by the German Academic exchange Service (DAAD) and in part by Association of African Universities (AAU), Kenyatta University.

Compliance with ethical guidelines

Competing interests The authors declare that they have no competing interests.

Author information

Author notes

    Authors and Affiliations

    1. Department of Biochemistry and Biotechnology, Kenyatta University, Nairobi, Kenya

      Daniel O. Okun, Fathiya M. Khamis & Joseph J. Ngeranwa

    2. Department of Biochemistry, South Eastern University College (a Constituent College of the University of Nairobi), Kitui, Kenya

      Geoffrey M. Muluvi

    3. Embu University College, Embu, Kenya

      Eucharia U. Kenya

    4. International Center for Insect Physiology and Ecology, Kasarani, Nairobi, Kenya

      Fathiya M. Khamis & Fidelis O. Ombura

    5. Kenya Wild Life Services, Lang’ata, Nairobi, Kenya

      Moses O. Yongo

    Authors
    1. Daniel O. Okun
      View author publications

      You can also search for this author in PubMed Google Scholar

    2. Fathiya M. Khamis
      View author publications

      You can also search for this author in PubMed Google Scholar

    3. Geoffrey M. Muluvi
      View author publications

      You can also search for this author in PubMed Google Scholar

    4. Joseph J. Ngeranwa
      View author publications

      You can also search for this author in PubMed Google Scholar

    5. Fidelis O. Ombura
      View author publications

      You can also search for this author in PubMed Google Scholar

    6. Moses O. Yongo
      View author publications

      You can also search for this author in PubMed Google Scholar

    7. Eucharia U. Kenya
      View author publications

      You can also search for this author in PubMed Google Scholar

    Corresponding author

    Correspondence to Daniel O. Okun.

    Additional information

    All authors contributed equally.

    Rights and permissions

    Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

    Reprints and permissions

    About this article

    Check for updates. Verify currency and authenticity via CrossMark

    Cite this article

    Okun, D.O., Khamis, F.M., Muluvi, G.M. et al. Distribution of indigenous strains of atoxigenic and toxigenic Aspergillus flavus and Aspergillus parasiticus in maize and peanuts agro-ecological zones of Kenya. Agric & Food Secur 4, 14 (2015). https://doi.org/10.1186/s40066-015-0033-5

    Download citation

    • Received:

    • Accepted:

    • Published:

    • DOI: https://doi.org/10.1186/s40066-015-0033-5

    Keywords

    Agriculture & Food Security

    ISSN: 2048-7010