Your search keyword '"Malin A. Olson"' showing total 4 results

1. Control of venom-induced tissue injury in copperhead snakebite patients: a post hoc sub-group analysis of a clinical trial comparing F(ab’)2 to Fab antivenom

Author

Daniel E. Keyler, Richard C. Dart, Charles J. Gerardo, and Malin Rapp-Olson

Subjects

Agkistrodon, biology, Post hoc, business.industry, Antivenom, Copperhead, Venom, General Medicine, Toxicology, biology.organism_classification, complex mixtures, Clinical trial, Anesthesia, comic_books, Medicine, business, comic_books.character

Abstract

Fab antivenom (FabAV) halts progression of tissue injury and improves recovery in copperhead snakebite. It is unknown if F(ab’)2AV does as well. The objective of this study was to compare control o...

Published

2021

2. Control of venom-induced tissue injury in copperhead snakebite patients: a post hoc sub-group analysis of a clinical trial comparing F(ab')

Author

Charles J, Gerardo, Daniel E, Keyler, Malin, Rapp-Olson, and Richard C, Dart

Subjects

Male, Immunoglobulin Fab Fragments, Antivenins, Crotalid Venoms, Animals, Humans, Snake Bites, Female, Agkistrodon, Middle Aged

Abstract

Fab antivenom (FabAV) halts progression of tissue injury and improves recovery in copperhead snakebite. It is unknown if F(ab')We performed a post hoc analysis of copperhead envenomated patients in a clinical trial comparing F(ab')Twenty-one (13 F(ab')This exploratory analysis suggests that the available measures of the control of venom-induced tissue injury are similar between antivenom subgroups.

Published

2021

3. Fragmentation of an aflatoxin-like gene cluster in a forest pathogen

Author

Pranav Chettri, Murray P. Cox, Rosie E. Bradshaw, Austen R. D. Ganley, Kenneth C. Ehrlich, Antonis Rokas, Geromy G. Moore, Malin A. Olson, Ignazio Carbone, Pierre J. G. M. de Wit, and Jason C. Slot

Subjects

dothistroma-septosporum, Physiology, functional-analysis, aspergillus-parasiticus, Genes, Fungal, Population, biosynthetic-pathway, Anthraquinones, Plant Science, Biology, Synteny, Linkage Disequilibrium, Trees, Evolution, Molecular, Aflatoxins, Ascomycota, Phylogenetics, Gene cluster, evolution, medicine, phylogenetic analyses, education, horizontal transfer, Phylogeny, Recombination, Genetic, Comparative genomics, Genetics, education.field_of_study, secondary metabolism, Models, Genetic, EPS-2, recombination events, filamentous fungi, Biosynthetic Pathways, Laboratorium voor Phytopathologie, medicine.drug_formulation_ingredient, Dothistroma septosporum, Genetic Loci, Multigene Family, Laboratory of Phytopathology, Horizontal gene transfer, Host adaptation

Abstract

Summary Plant pathogens use a complex arsenal of weapons, such as toxic secondary metabolites, to invade and destroy their hosts. Knowledge of how secondary metabolite pathways evolved is central to understanding the evolution of host specificity. The secondary metabolite dothistromin is structurally similar to aflatoxins and is produced by the fungal pine pathogen Dothistroma septosporum. Our study focused on dothistromin genes, which are widely dispersed across one chromosome, to determine whether this unusual distributed arrangement evolved from an ancestral cluster. We combined comparative genomics and population genetics approaches to elucidate the origins of the dispersed arrangement of dothistromin genes over a broad evolutionary timescale at the phylum, class and species levels. Orthologs of dothistromin genes were found in two major classes of fungi. Their organization is consistent with clustering of core pathway genes in a common ancestor, but with intermediate cluster fragmentation states in the Dothideomycetes fungi. Recombination hotspots in a D. septosporum population matched sites of gene acquisition and cluster fragmentation at higher evolutionary levels. The results suggest that fragmentation of a larger ancestral cluster gave rise to the arrangement seen in D. septosporum. We propose that cluster fragmentation may facilitate metabolic retooling and subsequent host adaptation of plant pathogens.

Published

2013

4. Dothistromin genes at multiple separate loci are regulated by AflR

Author

Rosie E. Bradshaw, Pranav Chettri, Malin A. Olson, Scott A. Griffiths, Kenneth C. Ehrlich, Murray P. Cox, Jeffrey W. Cary, Jérôme Collemare, and Pierre J. G. M. de Wit

Subjects

aspergillus-parasiticus, Mutant, forest pathogen, Anthraquinones, Biology, Microbiology, Regulon, Gene Knockout Techniques, Ascomycota, Gene Expression Regulation, Fungal, Gene cluster, Gene Order, expression, Genetics, medicine, needle blight, Gene, Chromosome 12, pathway genes, Regulator gene, Regulation of gene expression, secondary metabolism, EPS-2, filamentous fungi, Chromosome, cluster protein, Laboratorium voor Phytopathologie, medicine.drug_formulation_ingredient, Dothistroma septosporum, Laboratory of Phytopathology, pini, Metabolic Networks and Pathways, Transcription Factors, aflatoxin biosynthesis

Abstract

In fungi, genes involved in the production of secondary metabolites are generally clustered at one location. There are some exceptions, such as genes required for synthesis of dothistromin, a toxin that is a chemical analog of the aflatoxin precursor versicolorin A and made by the pine needle pathogen Dothistroma septosporum. The availability of the D. septosporum genome sequence enabled identification of putative dothistromin genes, including an ortholog of the aflatoxin regulatory gene AflR, and revealed that most of the genes are spread over six separate regions (loci) on chromosome 12 (1.3 Mb). Here we show that levels of expression of the widely dispersed genes in D. septosporum are not correlated with gene location with respect to their distance from a telomere, but that AflR regulates them. The production of dothistromin by D. septosporum in which the AflR gene was knocked out (ΔDsAflR) was drastically reduced, but still detectable. This is in contrast to orthologous ΔAflR mutants in Aspergillus species that lack any aflatoxin production. Expression patterns in ΔDsAflR mutants helped to predict the complete set of genes involved in dothistromin production. This included a short-chain aryl alcohol dehydrogenase (NorB), which is located on chromosome 11 rather than chromosome 12, but was 24-fold down regulated in ΔDsAflR. An orthologous set of dothistromin genes, organized in a similar fragmented cluster arrangement to that seen in D. septosporum, was found in the closely related tomato pathogen Cladosporium fulvum even though this species does not produce dothistromin. In C. fulvum, pseudogenization of key biosynthetic genes explains the lack of dothistromin production. The fragmented arrangement of dothistromin genes provides an example of coordinated control of a dispersed set of secondary metabolite genes; it also provides an example where loss of dothistromin production might have allowed adaptation to a new pathogenic lifestyle.

Published

2013