Your search keyword '"Nielsen DM"' showing total 3 results

1. Localization, morphology and transcriptional profile of Aspergillus flavus during seed colonization.

Author

Dolezal AL, Obrian GR, Nielsen DM, Woloshuk CP, Boston RS, and Payne GA

Subjects

Aspergillus flavus pathogenicity, Chromosomes, Fungal genetics, Colony Count, Microbial, DNA, Fungal isolation & purification, Electrophoresis, Agar Gel, Endosperm microbiology, Genes, Fungal genetics, Humans, Seeds cytology, Transcription Factors metabolism, Zea mays cytology, Aspergillus flavus genetics, Aspergillus flavus growth & development, Gene Expression Profiling, Gene Expression Regulation, Fungal, Seeds microbiology, Transcription, Genetic, Zea mays microbiology

Abstract

Aspergillus flavus is an opportunistic fungal pathogen that infects maize kernels pre-harvest, creating major human health concerns and causing substantial agricultural losses. Improved control strategies are needed, yet progress is hampered by the limited understanding of the mechanisms of infection. A series of studies were designed to investigate the localization, morphology and transcriptional profile of A. flavus during internal seed colonization. Results from these studies indicate that A. flavus is capable of infecting all tissues of the immature kernel by 96 h after infection. Mycelia were observed in and around the point of inoculation in the endosperm and were found growing down to the germ. At the endosperm-germ interface, hyphae appeared to differentiate and form a biofilm-like structure that surrounded the germ. The exact nature of this structure remains unclear, but is discussed. A custom-designed A. flavus Affymetrix GeneChip® microarray was used to monitor genome-wide transcription during pathogenicity. A total of 5061 genes were designated as being differentially expressed. Genes encoding secreted enzymes, transcription factors and secondary metabolite gene clusters were up-regulated and considered to be potential effector molecules responsible for disease in the kernel. Information gained from this study will aid in the development of strategies aimed at preventing or slowing down A. flavus colonization of the maize kernel., (© 2013 BSPP AND JOHN WILEY & SONS LTD.)

Published

2013

2. Gene expression profile and response to maize kernels by Aspergillus flavus.

Author

Reese BN, Payne GA, Nielsen DM, and Woloshuk CP

Subjects

6-Phytase genetics, Aspergillus flavus growth & development, Aspergillus flavus pathogenicity, Down-Regulation, Gene Expression Profiling methods, Oligonucleotide Array Sequence Analysis methods, Reverse Transcriptase Polymerase Chain Reaction, Seeds microbiology, Sequence Deletion, Transformation, Genetic, Up-Regulation, Virulence, Zea mays growth & development, 6-Phytase metabolism, Aflatoxins biosynthesis, Aspergillus flavus enzymology, Aspergillus flavus genetics, Gene Expression Regulation, Fungal genetics, Zea mays microbiology

Abstract

Aspergillus flavus causes an ear rot of maize, often resulting in the production of aflatoxin, a potent liver toxin and carcinogen that impacts the health of humans and animals. Many aspects of kernel infection and aflatoxin biosynthesis have been studied but the precise effects of the kernel environment on A. flavus are poorly understood. The goal of this research was to study the fungal response to the kernel environment during colonization. Gene transcription in A. flavus was analyzed by microarrays after growth on kernels of the four developmental stages: blister (R2), milk (R3), dough (R4), and dent (R5). Five days after inoculation, total RNA was isolated from kernels and hybridized to Affymetrix Gene Chip arrays containing probes representing 12,834 A. flavus genes. Statistical comparisons of the expression profile data revealed significant differences that included unique sets of upregulated genes in each kernel stage and six patterns of expression over the four stages. Among the genes expressed in colonized dent kernels were a phytase gene and six putative genes involved in zinc acquisition. Disruption of the phytase gene phy1 resulted in reduced growth on medium containing phytate as the sole source of phosphate. Furthermore, growth of the mutant (Δphy1) was 20% of the wild-type strain when wound inoculated into maize ears. In contrast, no difference was detected in the amount of aflatoxin produced relative to fungal growth, indicating that phy1 does not affect aflatoxin production. The study revealed the genome-wide effects of immature maize kernels on A. flavus and suggest that phytase has a role in pathogenesis.

Published

2011

3. The effect of temperature on Natural Antisense Transcript (NAT) expression in Aspergillus flavus.

Author

Smith CA, Robertson D, Yates B, Nielsen DM, Brown D, Dean RA, and Payne GA

Subjects

Aspergillus flavus metabolism, Expressed Sequence Tags, Fungal Proteins genetics, Fungal Proteins metabolism, Genome, Fungal, RNA Precursors metabolism, Transcription, Genetic genetics, Aspergillus flavus genetics, Gene Expression Regulation, Fungal, RNA, Antisense metabolism, Temperature

Abstract

Naturally occurring Antisense Transcripts (NATs) compose an emerging group of regulatory RNAs. These regulatory elements appear in all organisms examined, but little is known about global expression of NATs in fungi. Analysis of currently available EST sequences suggests that 352 cis NATs are present in Aspergillus flavus. An Affymetrix GeneChip microarray containing probes for these cis NATs, as well as all predicted genes in A. flavus, allowed a whole genome expression analysis of these elements in response to two ecologically important temperatures for the fungus. RNA expression analysis showed that 32 NATs and 2,709 genes were differentially expressed between 37 degrees C, the optimum temperature for growth, and 28 degrees C, the conducive temperature for the biosynthesis of aflatoxin (AF) and many other secondary metabolites. These NATs correspond to sense genes with diverse functions including transcription initiation, carbohydrate processing and binding, temperature sensitive morphogenesis, and secondary metabolism. This is the first report of a whole genome transcriptional analysis of NAT expression in a fungus.

Published

2008