Corn (Zea mays L.) is an important crop in the Black Sea region of Turkey (Anonymous 2007). It was introduced into Turkey from the Americas in the 1600s and was included in traditional farming systems. In Turkey, about 590,000 ha of corn are planted every year, which yield an estimated 300,000 t of grain annually (Anonymous 2008). Ear rots caused by a number of fungi not only decrease yields but they also have the potential to contaminate grain with mycotoxins that can adversely affect human and animal health (Kedera et al. 1999; Macdonald and Chapman 1997; Njuguna et al. 1990; Ross et al. 1990). The prevalence and density of Fusarium verticillioides (Sacc.) Nirenberg in field samples was 49.25% for the Bolu province and 62.67% for the Zonguldak province of the West Black Sea region of Turkey in 1992 (Aktas et al. 1994). Since the International Agency for Research on Cancer (IARC) declared fumonisins as a 2B carcinogen, legal limits in corn have recently been defined by the European Union as 2.0 mg kg^-1 in grain, 1.0 mg kg^-1 in corn meal and flour, 0.4 mg kg^-1 in corn-based products for human consumption, and 0.2 mg kg^-1 in baby food.

The production of mycotoxins in corn is often influenced by moisture, temperature and nutrient factors unfavourable to growing corn (Miller et al. 1993). Fumonisins are common contaminants of corn-based food and feed in the United States, China, Europe, South America and Africa (Fandohan et al. 2003; Shephard et al. 1996; Sydenham et al. 1994; Visconti and Doko 1994). Fumonisins inhibit the biosynthesis of sphingolipids and can cause a variety of diseases in animals that eat contaminated feed (Desjardins et al. 1998). Consumption of corn contaminated with high levels of fumonisins causes esophageal cancer in humans in parts of the world where corn is a staple food (Munkvold and Desjardins 1997). Fifteen Fusarium species have been reported to produce fumonisins (Marasas 2001). Eight of these species are in the section Liseola of Fusarium, including F. verticillioides (Syn = F. moniliforme) mating population A, MP-A; F. sacchari (E.J. Butler & Hafiz Khan) W. Gams, MP-B; F. fujikuroi Nirenberg, MP-C; F. proliferatum (T. Matsush.) Nirenberg ex Gerlach 7 Nirenberg, MP-D; F. subglutinans (Wollenweb. & Reinking) P.E. Nelson, T.A. Tousson & Marasas, MP-E; and F. subglutinanssensu lato isolated from teosinte seed. These are all part of the Gibberella fujikuroi (Sawada) Wollenw. (teleomorphs) species complex. Fusarium verticillioides is a common pathogen on corn causing root, stalk and ear rots worldwide (Munkvold and Desjardins 1997). Fusarium proliferatum is similar to F. verticillioides in many respects, but the chains of microconidia are usually shorter than those of F. verticillioides and are often formed in pairs from polyphialides, resulting in a characteristic ”V” shape (Burgess et al. 1994). Fusarium subglutinans is common in the cooler areas of subtropical regions of eastern Australia and in temperate areas. It is also associated with stalk rot and cob rot of corn and can be seed-borne (Burgess et al. 1994; Francis and Burgess 1975).

The most important producers of fumonisins are F. verticillioides and F. proliferatum because of their overall high levels of production, wide geographical distribution, frequent occurrence on corn, and association with known animal mycotoxicoses (Ross et al. 1992). The highest yield of FB₁ to be reported for a Fusarium species was obtained from a Spanish corn isolate of F. proliferatum cultured on whole corn. This isolate also produced the highest published yield of FB₂. Some isolates of F. subglutinans, F. thapsinum Klittich, J.F. Leslie, P.E. Nelson & Marasas, F. anthophilum (A. Braun) Wollenw., F. globosum Rheeder, Marasas & P.E. Nelson, F. dlamini Marasas, F. napiforme Marasas, P.E. Nelson & Rabie, F. oxysporum var. redolens (Wollenw.) W.L. Gordon, and F. polyphialidicum Marasas, P.E. Nelson, Toussoun & P.S. van Wyk were also found to produce FB₁ in the same study (Rheeder et al. 2002).

Oruc et al. (2006) analyzed 26 corn samples by competitive ELISA and found that fumonisin levels ranged from 0.80 to 356.8 mg kg^-1 in corn from Turkey and from 4 to 263 mg kg^-1 in imported corn. In Turkey, very little research has been done on the occurrence of fumonisin in maize. In a study conducted by Omurtag (2001), detected levels of FB₁ in the country were between 0.25 and 2.66 mg kg^-1 in 25.6% of the 82 samples analyzed, but FB₂ was detected only in a single corn meal sample at 0.55 ppm. Arici et al. (2004) reported that fumonisin contamination ranged from 0.8 to 273 mg kg^-1 in low-processed products and from 0.3 to 76.8 mg kg^-1 in processed products out of a total of 92 corn-based food products in Turkey. There is a great need for additional investigation in Turkey, at least in the Black Sea region where corn production and consumption are predominant. The objectives of this project were: (i) to determine the infection levels and distribution of Fusarium spp. in field samples of corn in the Samsun province; and (ii) to investigate natural levels and incidence of FB attributable to various isolates of F. verticillioides, F. proliferatum and F. subglutinans in grain from farmers’ fields in the Samsun province.

Results of the surveys conducted in 2005 and 2006 in a total of 140 fields from 11 districts of the Samsun province are presented in Table 1. Microscopic analysis showed that Fusarium was the predominant fungal genus in corn ears during the 2005 and 2006 pre-harvest seasons in the Samsun province.

The occurrence of Fusarium species differed significantly between the years 2005 and 2006 (P < 0.05). Fusarium verticillioides was the most commonly isolated fungus in 2005, while F. solani (Mart.) Sacc. was most commonly isolated during the 2006 pre-harvest season (Table 1). Fusarium verticillioides, F. proliferatum and F. subglutinans were found during both years, but were more frequent in 2005. Occurrence of those three species in 2005 was 42.9, 31.4 and 12.9%, respectively, and 17.1, 10.0 and 11.4% in 2006. The number of kernels contaminated with Fusarium species was 333 in 2005 and 184 in 2006 (Table 1). Fusarium oxysporum, F. equiseti (Corda) Sacc., F. sporotrichioides Sherb. and F. semitectum Berk. & Ravenal were detected only in 2006, while F. acuminatum Ellis & Everh. was found only in 2005 in one location. A total of 517 Fusarium isolates were obtained from the 2005 and 2006 samples. The number of isolates for each species was 233 F. verticillioides, 121 F. proliferatum, 72 F. subglutinans, 60 F. solani, 11 F. graminearum, 9 F. oxysporum, 3 F. culmorum, 2 F. poae (Peck), Wollenweb. in Lewis, 2 F. equiseti, 1 F. sporotrichioides, and 1 F. acuminatum for both years. Incidence of Fusarium spp. in field samples was 97.14% in 2005 and 78.57% in 2006 (Table 1). The 2-yr mean value was 87.85%.

Other non-Fusarium species were identified in 16.73% of the field samples in 2005 and 2006, including Penicillium spp. (5.76%), Mucor spp. (2.76%), Alternaria spp. (1.95%), Acremonium strictum W. Gams (1.45%), Alternaria alternata (Fr.:Fr.) Keissl. (1.38%), Rhizophus sp. (1.16%), Aspergillus niger Tiegh. (0.92%), Trichoderma harzianum Rifai (0.50%), Verticillium sp. (0.21%), Aspergillus flavus Link:Fr. (0.19%), Chaetomium globosum Kunze (0.19%), Epicoccum purpurascens Ehrenb. (0.14%), Cladosporium sp. (0.04%), and Nigrospora oryzae (Berk. & Broome) Petch (0.02 %).

Fusarium graminearum and F. culmorum were not found in 2005. They were found only in different locations of a single field in 2006. The concentration of deoxynivalenol in grain was non-detectable in samples infected by these two Fusarium species.

The occurrence of F. verticillioides and F. proliferatum decreased significantly from 2005 to 2006. All 66 samples naturally contaminated with F. verticillioides, F. proliferatum and F. subglutinans were found to be FB₁ positive, with levels ranging from 0.28 to 8.48 mg kg^-1 in 2005 and from 0.11 to 2.77 mg kg^-1 in 2006. None of them contained FB₂. The concentration of FB₁ in 63.6% of the samples was below 2 mg kg^-1, 28.8% of the samples contained from 2 to 5 mg kg^-1, while 7.6% of the samples contained more than 5 mg kg^-1 (Table 2). A positive and significant correlation was found between the FB₁ level in corn and the occurrence of F. verticillioides, F. proliferatum and F. subglutinans. However, there was no correlation between the level of infection with those three fungi and the concentration of FB₁ detected in the same sample (Table 2). Thirty isolates of F. verticillioides, 22 isolates of F. proliferatum and 9 isolates of F. subglutinans were obtained in 2005, while 12 isolates of F. verticillioides, 7 isolates of F. proliferatum and 8 isolates of F. subglutinans were obtained in 2006 in the Samsun province (Table 2).

A t-test on mean transformed (square root (toxin level + 1)) toxin levels showed a significant difference between 2005 and 2006 (Table 3). The amount of toxin produced by the three Fusarium spp. was significantly higher in 2005 compared with 2006. No differences between locations were registered among FB₁ levels.

Fusarium verticillioides, F. proliferatum and F. subglutinans were responsible for the formation of fumonisin at the time of harvest in corn fields of the Samsun province. All tested strains of those three fungi produced FB₁. The highest level of FB₁ was found in sample 41 (Vezirköprü-Aydogdu 1). This sample contained all three species. The mycotoxin committee of the American Association of Veterinary Diagnosticians recommends that concentrations greater than 4 mg kg^-1 should not be fed to horses and pigs (Riley et al. 1993). According to this advisory level, at least seven samples of corn from this study should be considered hazardous to feed horses and pigs.

Other surveys carried out in many parts of the world have revealed that these are the fumonisin- producing Fusarium species most frequently isolated from corn in tropical and subtropical zones (Shephard et al. 1996). Fusarium verticillioides and F. proliferatum co-occur worldwide in corn (Leslie et al. 1990), probably because they have similar optimum growth conditions. In our study, both fungi were found together in 17 samples. However, it is also common to find one without the other, such as was the case in our study. Some publications indicate that F. subglutinans does not produce fumonisin, but it produces other important mycotoxins (Marasas et al. 1984). However, Rheeder et al. (2002) reported that F. subglutinans can produce FB₁ in corn kernels. In our study, F. subglutinans was found alone in 12 samples that contained FB₁ (0.87 to 4.15 mg kg^-1) (Table 2).

The role of humidity for fumonisin production in corn is clearly important. Variation in Fusarium spp. presence and fumonisin contamination from one season to another was observed in 2005 and 2006. Fusarium verticillioides, F. proliferatum and F. subglutinans incidence was higher in 2005 than in 2006. Fumonisin B₁ contamination was also higher in 2005 than in 2006. In our study, average rainfall during the survey period was higher in August 2005 (114.2 mm) than in August 2006 (0.0 mm). In a similar study, Heiniger et al. (2002) compared daily rainfall, temperature and RH records for three locations, and showed that the most striking environmental event related to fumonisin development was the precipitation recorded on August 12 and 13 at all locations. These rainfall events were accompanied by increases in RH and short-term decreases in temperature. Immediately prior to these rainfall events, temperatures had increased dramatically, reaching their highest point for the summer in early August.

Based on our research, rainfall in August 2005 totalled 114.2 mm, but there was no rain in August 2006. Average moisture was lower in August 2006 than in August 2005. These results may explain why both fumonisin production and the FB₁ level were higher in 2005 than in 2006. In August 2005, rainfall was three times superior to the 30-yr average of 37.5 mm. Gong et al. (2009) demonstrated that the high level of FB₁ contamination of corn in the Sichuan and Guangxi provinces was correlated with the meteorological data of these provinces, including moderate mean temperature and high relative humidity and rainfall. Gamanya and Sibanda (2001) also found levels of fumonisin in Zimbabwe to be higher in regions with high rainfall and moderate annual temperature than in those with low rainfall. Hennigen et al. (2000) found fumonisin contamination in Argentina to differ markedly over two consecutive growing seasons. Such yearly variation may, among other things, be attributable to differences in environmental conditions. Desjardins et al. (1998) also reported that the frequency of infected kernels was higher in their 1993 field tests than in their 1994 ones. This difference may have been due to unusually heavy rainfall causing poor growing conditions during the spring and summer of 1993. In contrast, ears harvested in 1994 generally were of good quality, with few visibly moldy, discoloured, or chalky kernels.

Most of the samples collected for this study did not show any disease symptoms; therefore, no correlation was found between FB₁ and visibly diseased kernels. However, Desjardins et al. (1998) reported that fumonisin levels were low (< 1µg g^-1) in symptomless kernels, and higher (138 µg g^-1) in symptomatic kernels. Bush et al. (2004) found that the analysis of both symptomless and symptomatic kernels revealed a relatively high concentration of fumonisin. In other studies, individual ears of maize confirmed prior observations of a poor correlation between fumonisin levels and the incidence of F. verticillioides in bulked maize ears collected from farmlands in South Africa (Rheeder et al. 1992,1995).

Fusarium graminearum and F. culmorum were found only in 2006, but F. culmorum was found in different locations of a single field. Environmental factors may have affected spore germination and fungal growth on corn kernels. It has been reported that F. graminearum needs a minimum water potential (a_w) of 0.94 to 0.95 at 25°C to germinate (Sung and Cook 1981), whereas at approximately the same temperature, ascospores of F. verticillioides are reported to germinate down to 0.88 a_w (Marin et al. 1999). The concentration of deoxynivalenol in F. graminearum- and F. culmorum-infected grain was not detectable by HPLC analysis.

The present study shows that F. verticillioides is the predominant fungus in corn field populations in the Samsun province of Turkey. All F. verticillioides, F. proliferatum and F. subglutinans isolates were investigated and all of them produced FB₁. None of them produced FB₂. Fumonisin B₁ production varied from 0.11 to 8.48 mg kg^-1 in naturally infected corn fields. Corn contamination with both Fusarium and FB₁ was found to be possible everywhere in the Samsun province, but was strongly dependent on the environmental and seasonal conditions observed during the study. No Fusarium contamination was found in some native white-type and popcorn-type corn cultivars during the 2005-2006 study period. Further investigation is needed in order to screen cultivars for resistance to Fusarium spp., FB₁ and FB₂, and to establish relationships between genotypes and environmental conditions. Additional studies are also needed to define fumonisin-producing Fusarium species and their molecular characterization in other parts of Turkey.