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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

Utilization of yeast pheromones and hydrophobin-based surface engineering for novel whole-cell sensor applications

Hennig, Stefan 07 April 2017 (has links) (PDF)
Whole-cell sensors represent an emerging branch in biosensor development since they obviate the need for enzyme/antibody purification and provide the unique opportunity to assess global parameters such as genotoxicity and bioavailability. Yeast species such as Saccharomyces cerevisiae are ideal hosts for whole-cell sensor applications. However, current approaches almost exclusively rely on analyte-induced expression of fluorescent proteins or luciferases that imply issues with light scattering and/or require the supply of additional substrates. In this study, the yeast α-factor mating pheromone, a peptide pheromone involved in cell-cell communication in Saccharomyces cerevisiae, was utilized to create the whole-cell sensor read-out signal, in particular by employing engineered sensor cells that couple the response to a user-defined environmental signal to α-factor secretion. Two novel immunoassays - relying on hydrophobin-based surface engineering - were developed to quantify the α-factor. Hydrophobins are amphiphilic fungal proteins that self-assemble into robust monolayers at hydrophobic surfaces. Two recombinant hydrophobins, either lacking (EAS) or exposing the α-factor pheromone (EAS-α) upon self-assembly, were used to functionalize polystyrene supports. In a first approach (competitive immunoassay), pheromone-specific antibodies initially bound to the functionalized surface (due to the α-factor exposed by the hydrophobin layer) were competitively detached by soluble α-factor. In a second approach, the antibodies were first premixed with pheromone-containing samples and subsequently applied to functionalized surfaces, allowing for the attachment of antibodies that still carried available binding sites (inverse immunoassay). Both immunoassays enabled quantitative assessment of the yeast pheromone in a unique but partially overlapping dynamic range and allowed for facile tuning of the assay sensitivity by adjustment of the EAS-α content of the hydrophobin layer. With a limit of detection of 0.1 nM α-factor, the inverse immunoassay proved to be the most sensitive pheromone quantification assay currently available. Due to the high stability of hydrophobin monolayers, functionalized surfaces could be reused for multiple consecutive measurements. Favorably, both immunoassays proved to be largely robust against the changes in the sample matrix composition, allowing for pheromone quantification in complex sample matrices such as yeast culture supernatants. Hence, these immunoassays could also be applied to study the pheromone secretion of wild-type and engineered Saccharomyces cerevisiae strains. Additionally, a proof-of-concept whole-cell sensor for thiamine was developed by combining the hydrophobin-based immunoassays with engineered sensor cells of Schizosaccharomyces pombe modulating the secretion of the α-factor pheromone in response to thiamine. Since this read-out strategy encompasses intrinsic signal amplification and enables flexible choice of the transducer element, it could contribute to the development of miniaturized, portable whole-cell sensors for on-site application.
2

Hydrophobin-Based Surface Engineering for Sensitive and Robust Quantification of Yeast Pheromones

Hennig, Stefan, Rödel, Gerhard, Ostermann, Kai 16 January 2017 (has links) (PDF)
Detection and quantification of small peptides, such as yeast pheromones, are often challenging. We developed a highly sensitive and robust affinity-assay for the quantification of the α-factor pheromone of Saccharomyces cerevisiae based on recombinant hydrophobins. These small, amphipathic proteins self-assemble into highly stable monolayers at hydrophilic-hydrophobic interfaces. Upon functionalization of solid supports with a combination of hydrophobins either lacking or exposing the α-factor, pheromone-specific antibodies were bound to the surface. Increasing concentrations of the pheromone competitively detached the antibodies, thus allowing for quantification of the pheromone. By adjusting the percentage of pheromone-exposing hydrophobins, the sensitivity of the assay could be precisely predefined. The assay proved to be highly robust against changes in sample matrix composition. Due to the high stability of hydrophobin layers, the functionalized surfaces could be repeatedly used without affecting the sensitivity. Furthermore, by using an inverse setup, the sensitivity was increased by three orders of magnitude, yielding a novel kind of biosensor for the yeast pheromone with the lowest limit of detection reported so far. This assay was applied to study the pheromone secretion of diverse yeast strains including a whole-cell biosensor strain of Schizosaccharomyces pombe modulating α-factor secretion in response to an environmental signal.
3

Hydrophobin-Based Surface Engineering for Sensitive and Robust Quantification of Yeast Pheromones

Hennig, Stefan, Rödel, Gerhard, Ostermann, Kai 16 January 2017 (has links)
Detection and quantification of small peptides, such as yeast pheromones, are often challenging. We developed a highly sensitive and robust affinity-assay for the quantification of the α-factor pheromone of Saccharomyces cerevisiae based on recombinant hydrophobins. These small, amphipathic proteins self-assemble into highly stable monolayers at hydrophilic-hydrophobic interfaces. Upon functionalization of solid supports with a combination of hydrophobins either lacking or exposing the α-factor, pheromone-specific antibodies were bound to the surface. Increasing concentrations of the pheromone competitively detached the antibodies, thus allowing for quantification of the pheromone. By adjusting the percentage of pheromone-exposing hydrophobins, the sensitivity of the assay could be precisely predefined. The assay proved to be highly robust against changes in sample matrix composition. Due to the high stability of hydrophobin layers, the functionalized surfaces could be repeatedly used without affecting the sensitivity. Furthermore, by using an inverse setup, the sensitivity was increased by three orders of magnitude, yielding a novel kind of biosensor for the yeast pheromone with the lowest limit of detection reported so far. This assay was applied to study the pheromone secretion of diverse yeast strains including a whole-cell biosensor strain of Schizosaccharomyces pombe modulating α-factor secretion in response to an environmental signal.
4

Utilization of yeast pheromones and hydrophobin-based surface engineering for novel whole-cell sensor applications

Hennig, Stefan 03 April 2017 (has links)
Whole-cell sensors represent an emerging branch in biosensor development since they obviate the need for enzyme/antibody purification and provide the unique opportunity to assess global parameters such as genotoxicity and bioavailability. Yeast species such as Saccharomyces cerevisiae are ideal hosts for whole-cell sensor applications. However, current approaches almost exclusively rely on analyte-induced expression of fluorescent proteins or luciferases that imply issues with light scattering and/or require the supply of additional substrates. In this study, the yeast α-factor mating pheromone, a peptide pheromone involved in cell-cell communication in Saccharomyces cerevisiae, was utilized to create the whole-cell sensor read-out signal, in particular by employing engineered sensor cells that couple the response to a user-defined environmental signal to α-factor secretion. Two novel immunoassays - relying on hydrophobin-based surface engineering - were developed to quantify the α-factor. Hydrophobins are amphiphilic fungal proteins that self-assemble into robust monolayers at hydrophobic surfaces. Two recombinant hydrophobins, either lacking (EAS) or exposing the α-factor pheromone (EAS-α) upon self-assembly, were used to functionalize polystyrene supports. In a first approach (competitive immunoassay), pheromone-specific antibodies initially bound to the functionalized surface (due to the α-factor exposed by the hydrophobin layer) were competitively detached by soluble α-factor. In a second approach, the antibodies were first premixed with pheromone-containing samples and subsequently applied to functionalized surfaces, allowing for the attachment of antibodies that still carried available binding sites (inverse immunoassay). Both immunoassays enabled quantitative assessment of the yeast pheromone in a unique but partially overlapping dynamic range and allowed for facile tuning of the assay sensitivity by adjustment of the EAS-α content of the hydrophobin layer. With a limit of detection of 0.1 nM α-factor, the inverse immunoassay proved to be the most sensitive pheromone quantification assay currently available. Due to the high stability of hydrophobin monolayers, functionalized surfaces could be reused for multiple consecutive measurements. Favorably, both immunoassays proved to be largely robust against the changes in the sample matrix composition, allowing for pheromone quantification in complex sample matrices such as yeast culture supernatants. Hence, these immunoassays could also be applied to study the pheromone secretion of wild-type and engineered Saccharomyces cerevisiae strains. Additionally, a proof-of-concept whole-cell sensor for thiamine was developed by combining the hydrophobin-based immunoassays with engineered sensor cells of Schizosaccharomyces pombe modulating the secretion of the α-factor pheromone in response to thiamine. Since this read-out strategy encompasses intrinsic signal amplification and enables flexible choice of the transducer element, it could contribute to the development of miniaturized, portable whole-cell sensors for on-site application.

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