Pesticide behavior in paddy fields and development of azole-resistant Aspergillus fumigatus: Should we be concerned?

Tricyclazole as a common fungicide wildly used to control rice blast disease in the Asian country may induce azole resistance in Aspergillus fumigatus isolates. The main reason of the acquired azole resistance is probably environmental exposure through wide fungicide use in agriculture. The present study was conducted with the aim of investigating the current status of the azole-resistant A. fumigatus obtained from the paddy fields with exposure to tricyclazole. A total of 108 soil samples were collected from four different locations of paddy fields in Mazandaran Province, Iran. Pure fungal colonies were initially identified based on the conventional tools, and then reconfirmed by using DNA sequencing of the partial ß-tubulin gene. In addition, the in vitro antifungal susceptibility was determined using the Clinical and Laboratory Standards Institute document (CLSI) M38-A2. The identification of the mutations in the CYP51A gene was accomplished by the implementation of the polymerase chain reaction amplification assay on the selected isolates. Overall, 31 of 108 (28.7%) isolates were identified as A. fumigatus, four (3.7%) of which were recognized as azole-resistant with MICs of itraconazole ≥8µg/ml and voriconazole ≥4µg/ml. Only two out of the four azole-resistant A. fumigatus isolates harboured TR34/L98H variant and the other two isolates were identified as azole-resistant without any CYP51A gene mutations. However, other point mutations (TR46/Y121F/T289A) were not detected in the CYP51A gene. The high molecular structure similarity between environmental and medical triazoles may result in the selection of resistance mechanisms. Nonetheless, one might conclude that tricyclazole with different molecular structures against medical azoles induces azole-resistance in A. fumigatus isolates. The behavior of such pesticides as tricyclazole in the rice paddy fields would have an effective role in the development of azole-resistance that requires detailed information.

Identification of Staphylococcus aureus virulence genes in a murine model of bacteraemia using signature-tagged mutagenesis.

Signature-tagged mutagenesis with transposon Tn917 was used to identify genes of Staphylococcus aureus required for virulence in a murine model of bacteraemia. Screening 1248 mutant strains in pools of 96 resulted in the provisional identification of 50 mutants attenuated in virulence. Subsequent individual analysis of many of these mutants confirmed that they are attenuated in virulence. DNA sequence analysis of regions flanking their transposon insertion points revealed that approximately half of them represent genes with unknown function, while most of the remainder are involved in nutrient biosynthesis and cell surface metabolism. Three mutants were found with transposon insertions in different positions in femA, and one mutant had an insertion in femB. Both femA and femB are involved in the formation of cell wall peptidoglycan pentaglycine cross-bridges. A further mutation occurred in a previously unknown gene that shares significant similarity to femB. Mutations were also obtained in recA and lsp (encoding the S. aureus prolipoprotein signal peptidase). On the basis of sequence similarities to proteins of known function, the products of other genes are probably involved in the synthesis of diaminopimelic acid (a component of peptidoglycan), maintenance of surface adhesins and cell surface membrane transport, showing that many components of the S. aureus cell surface are critical for the survival and replication of this pathogen in blood.

Characterisation and expression of a stage-regulated gene of Leishmania major.

This paper describes the isolation and characterisation of the meta 1 gene from Leishmania major, that is expressed predominantly in infective metacyclic parasites. The termini of the major 2-kb transcript derived from this gene have been mapped and polypyrimidine sequences implicated in RNA processing located in the flanking regions. The meta 1 gene is conserved in both Old and New World Leishmania species and codes for a putative protein of 112 amino acids. Antibodies raised against a recombinant protein expressed from this open reading frame recognise an 11.5-kDa protein in metacyclic cell lysates and this molecule localises to the region of the flagellar pocket by indirect immunofluorescence.