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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Cellulose Biosynthesis in Oomycetes

Fugelstad, Johanna January 2008 (has links)
<p>Oomycetes have long been considered as a separate class within the kingdom Fungi, but they are in fact closer to brown algae. They are currently classified in the Stramenopile eukaryotic kingdom, which includes heterokont algae and water molds. The major cell wall polysaccharides in Oomycetes are b-(1à3) and b-(1à6)-glucans, as well as cellulose, which has never been reported in any fungal species. Chitin - the major cell wall polysaccharide in fungi - occurs in minor amounts in the walls of some Oomycetes. Some Oomycete species are pathogens of great economical importance. For example, species of the genus <em>Phytophthora </em>are well studied plant pathogens that cause considerable economical losses in agriculture. Saprolegniosis, a fish disease caused by species from the genus <em>Saprolegnia</em>, is a major problem in the aquaculture industry and represents a threat to populations of salmonids in natural habitats. Currently, there are no chemicals available that are at the same time efficient Oomycete inhibitors, environmentally friendly and safe for human consumption of treated fishes. The biosynthesis of cellulose in Oomycetes is poorly understood, even though this biochemical pathway represents a potential target for new Oomycete inhibitors. In this work, cellulose biosynthesis was investigated in two selected Oomycetes, the plant pathogen <em>Phytophthora infestans</em> and the fish pathogen <em>Saprolegnia monoica</em>.</p><p> </p><p>A new Oomycete <em>CesA</em> gene family was identified. It contains four homologues designated as <em>CesA1, CesA2, CesA3</em> and <em>CesA4</em>. The gene products of <em>CesA1, 2</em> and <em>4 </em>contain Pleckstrin Homology domains located at the N-terminus. This represents a novel feature, unique to the Oomycete <em>CesA </em>genes. <em>CesA3</em> is the dominantly expressed <em>CesA </em>homologue in the mycelium of both <em>S. monoica</em> and <em>P. infestans</em>, while <em>CesA1</em> and<em> CesA2</em> are up-regulated in virulent life stages of <em>P. infestans</em>. <em>CesA4</em> was expressed only in minute amounts in all investigated types of cells. Gene silencing by RNA interference of the whole <em>CesA</em> gene family in <em>P. infestans</em> lead to decreased amounts of cellulose in the cell wall. The inhibitors of cellulose synthesis DCB and Congo Red had an up-regulating effect on <em>SmCesA</em> gene expression, which was accompanied by an increased b-glucan synthase activity <em>in vitro</em>. In addition, these inhibitors slowed down the growth of the mycelium from <em>S. monoica</em>. Zoospores from <em>P. infestans</em> treated with DCB were unable to infect potato leaves and showed aberrant cell wall morphologies similar to those obtained by silencing the <em>CesA</em> gene family.</p><p>Altogether these results show that at least some of the <em>CesA1-4</em> genes are involved in cellulose biosynthesis and that the synthesis of cellulose is crucial for infection of potato by <em>P. infestans</em>.</p><p> </p>
2

Cellulose Biosynthesis in Oomycetes

Fugelstad, Johanna January 2008 (has links)
Oomycetes have long been considered as a separate class within the kingdom Fungi, but they are in fact closer to brown algae. They are currently classified in the Stramenopile eukaryotic kingdom, which includes heterokont algae and water molds. The major cell wall polysaccharides in Oomycetes are b-(1à3) and b-(1à6)-glucans, as well as cellulose, which has never been reported in any fungal species. Chitin - the major cell wall polysaccharide in fungi - occurs in minor amounts in the walls of some Oomycetes. Some Oomycete species are pathogens of great economical importance. For example, species of the genus Phytophthora are well studied plant pathogens that cause considerable economical losses in agriculture. Saprolegniosis, a fish disease caused by species from the genus Saprolegnia, is a major problem in the aquaculture industry and represents a threat to populations of salmonids in natural habitats. Currently, there are no chemicals available that are at the same time efficient Oomycete inhibitors, environmentally friendly and safe for human consumption of treated fishes. The biosynthesis of cellulose in Oomycetes is poorly understood, even though this biochemical pathway represents a potential target for new Oomycete inhibitors. In this work, cellulose biosynthesis was investigated in two selected Oomycetes, the plant pathogen Phytophthora infestans and the fish pathogen Saprolegnia monoica. A new Oomycete CesA gene family was identified. It contains four homologues designated as CesA1, CesA2, CesA3 and CesA4. The gene products of CesA1, 2 and 4 contain Pleckstrin Homology domains located at the N-terminus. This represents a novel feature, unique to the Oomycete CesA genes. CesA3 is the dominantly expressed CesA homologue in the mycelium of both S. monoica and P. infestans, while CesA1 and CesA2 are up-regulated in virulent life stages of P. infestans. CesA4 was expressed only in minute amounts in all investigated types of cells. Gene silencing by RNA interference of the whole CesA gene family in P. infestans lead to decreased amounts of cellulose in the cell wall. The inhibitors of cellulose synthesis DCB and Congo Red had an up-regulating effect on SmCesA gene expression, which was accompanied by an increased b-glucan synthase activity in vitro. In addition, these inhibitors slowed down the growth of the mycelium from S. monoica. Zoospores from P. infestans treated with DCB were unable to infect potato leaves and showed aberrant cell wall morphologies similar to those obtained by silencing the CesA gene family. Altogether these results show that at least some of the CesA1-4 genes are involved in cellulose biosynthesis and that the synthesis of cellulose is crucial for infection of potato by P. infestans. / QC 20101110
3

Functional characterization of cellulose and chitin synthase genes in Oomycetes / Funktionell karaktärisering av cellulosa- och kitinsyntasgener i oomyceter

Fugelstad, Johanna January 2011 (has links)
Some species of Oomycetes are well studied pathogens that cause considerable economical losses in the agriculture and aquaculture industries. Currently, there are no chemicals available that are environmentally friendly and at the same time efficient Oomycete inhibitors. The cell wall of Oomycetes consists of b-(1à3) and b-(1à6)-glucans, cellulose and in some species minute amounts of chitin. The biosynthesis of cellulose and chitin in Oomycetes is poorly understood. However, cell wall synthesis represents a potential target for new Oomycete inhibitors. In this work, cellulose and chitin synthase genes and gene products were analyzed in the plant pathogen Phytophthora infestans and in the fish pathogen Saprolegnia monoica.   A new Oomycete CesA gene family was identified, containing four subclasses of genes designated as CesA1 to 4. The gene products of CesA1, 2 and 4 contain pleckstrin homology (PH) domains located at the N-terminus, which is unique to the Oomycete CesAs. Our results show that the SmCesA2 PH domain binds to phosphoinositides, F-actin and microtubules in vitro and can co-localize with F-actin in vivo. Functional characterization of the CesA genes by gene silencing in P. infestans led to decreased cellulose content in the cell wall. The cellulose synthase inhibitors DCB and Congo Red inhibited the growth of the mycelium of S. monoica and had an up-regulating effect on SmCesA gene expression. Zoospores from P. infestans treated with DCB were unable to infect potato leaves. In addition, two full-length chitin synthase genes (Chs) were analyzed from S. monoica.  Expression of SmChs2 in yeast yielded an active recombinant protein. The biochemical characterization of the in vitro product of SmChs2 confirmed that the protein is responsible for chitin formation. The chitin synthase inhibitor nikkomycin Z inhibited the SmChs2 both in vivo and in vitro.   Altogether these results show that at least some of the CesA1-4 genes are involved in cellulose biosynthesis and that synthesis of cellulose is crucial for infection of potato by P. infestans. The PH domain is involved in the interaction of CesA with the cytoskeleton. In addition, we firmly demonstrate that the SmChs2 gene encodes a catalytically active chitin synthase. / QC 20110531
4

Characterization of specific domains of the cellulose and chitin synthases from pathogenic oomycetes

Brown, Christian January 2015 (has links)
Some oomycetes species are severe pathogens of fish or crops. As such, they are responsible for important losses in the aquaculture industry as well as in agriculture. Saprolegnia parasitica is a major concern in aquaculture as there is currently no method available for controlling the diseases caused by this microorganism. The cell wall is an extracellular matrix composed essentially of polysaccharides, whose integrity is required for oomycete viability. Thus, the enzymes involved in the biosynthesis of cell wall components, such as cellulose and chitin synthases, represent ideal targets for disease control. However, the biochemical properties of these enzymes are poorly understood, which limits our capacity to develop specific inhibitors that can be used for blocking the growth of pathogenic oomycetes. In our work, we have used Saprolegnia monoica as a model species for oomycetes to characterize two types of domains that occur specifically in oomycete carbohydrate synthases: the Pleckstrin Homology (PH) domain of a cellulose synthase and the so-called ‘Microtubule Interacting and Trafficking’ (MIT) domain of chitin synthases. In addition, the chitin synthase activity of the oomycete phytopathogen Aphanomyces euteiches was characterized in vitro using biochemical approaches. The results from our in vitro investigations revealed that the PH domain of the oomycete cellulose synthase binds to phosphoinositides, microtubules and F-actin. In addition, cell biology approaches were used to demonstrate that the PH domain co-localize with F-actin in vivo. The structure of the MIT domain of chitin synthase (CHS) 1 was solved by NMR. In vitro binding assays performed on recombinant MIT domains from CHS 1 and CHS 2 demonstrated that both proteins strongly interact with phosphatidic acid in vitro. These results were further supported by in silico data where biomimetic membranes composed of different phospholipids were designed for interaction studies. The use of a yeast-two-hybrid approach suggested that the MIT domain of CHS 2 interacts with the delta subunit of Adaptor Protein 3, which is involved in protein trafficking. These data support a role of the MIT domains in the cellular targeting of CHS proteins. Our biochemical data on the characterization of the chitin synthase activity of A. euteiches suggest the existence of two distinct enzymes responsible for the formation of water soluble and insoluble chitosaccharides, which is consistent with the existence of two putative CHS genes in the genome of this species. Altogether our data support a role of the PH domain of cellulose synthase and MIT domains of CHS in membrane trafficking and cellular location. / <p>QC 20151014</p>

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