Genetic and Toxigenic Variability Within Population Isolated from Maize in Two Diverse Environments in Kenya

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2018 Feb 14

PMID 29434580

Citations 34

Authors

Sheila Okoth

Marthe De Boevre

Arnau Vidal

Jose Diana Di Mavungu

Sofie Landschoot

Martina Kyallo

Joyce Njuguna

Jagger Harvey

Sarah De Saeger

Affiliations

Soon will be listed here.

Abstract

is the main producer of carcinogenic aflatoxins in agricultural commodities such as maize. This fungus occurs naturally on crops, and produces aflatoxins when environmental conditions are favorable. The aim of this study is to analyse the genetic variability among 109 isolates previously recovered from maize sampled from a known aflatoxin-hotspot (Eastern region, Kenya) and the major maize-growing area in the Rift Valley (Kenya), and to determine their toxigenic potential. DNA analyses of internal transcribed spacer (ITS) regions of ribosomal DNA, partial β-tubulin gene (benA) and calmodulin gene (CaM) sequences were used. The strains were further analyzed for the presence of four aflatoxin-biosynthesis genes in relation to their capability to produce aflatoxins and other metabolites, targeting the regulatory gene aflR and the structural genes aflP, aflD, and aflQ. In addition, the metabolic profile of the fungal strains was unraveled using state-of-the-art LC-MS/MS instrumentation. The three gene-sequence data grouped the isolates into two major clades, and . was most prevalent in Eastern Kenya, while was common in both regions. was represented by a single isolate collected from Rift Valley. Diversity existed within the population, which formed several subclades. An inconsistency in identification of some isolates using the three markers was observed. The calmodulin gene sequences showed wider variation of polymorphisms. The aflatoxin production pattern was not consistent with the presence of aflatoxigenic genes, suggesting an inability of the primers to always detect the genes or presence of genetic mutations. Significant variation was observed in toxin profiles of the isolates. This is the first time that a profound metabolic profiling of isolates was done in Kenya. Positive associations were evident for some metabolites, while for others no associations were found and for a few metabolite-pairs negative associations were seen. Additionally, the growth medium influenced the mycotoxin metabolite production. These results confirm the wide variation that exists among the group and the need for more insight in clustering the group.

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