Development of Pichia pastoris as a ruminal escape vehicle

Strauss, Colin Earl, University of Lethbridge. Faculty of Arts and Science

January 2000

The yeast expression system Pichia pastoris was investigated as an encapsulation technology capable of serving as a rumen escape vehicle. Cellularly encapsulated protein is protected from the ruminal environment so long as the cell membrane, which surrounds and isolates the intracellular protein is physically intact. Intracellular expression of Green Fluorescent Protein (GFP) allows for the monitoring of cellular integrity as necessary for the protection of encapsulated protein from ruminal proteases. Upon cellular lysis GFP is exposed to extracellular proteases which result in both the proteolytic degradation of the protein-based GFP chromophore and its associated fluorescence. Visualization of rumen fluid under epifluorescent microscopy revealed a high level of background autofluorescence owing to the fluorescent plant particles, microbes, and fluorescent compounds therein. Visualization of GFP in rumen fluid can be optimized through GFP variant selection, filter set design, and light source selection based on bulb emission spectra. Incubation of intracellular GFP expressing P. pastoris in batch culture ruminal in vitro simulations demonstrated that 93%, 97%, and 25% of the P. pastoris inoculum maintained cellular integrity in clarified rumen fluid, bacterial fraction of rumen fluid, and whole rumen fluid, respectively, when incubated over 36 to 48 h. Continuous fermentation in vitro rumen simulations (Rusitec) demonstrated a P. pastoris escape rate of 19% when added daily to fully adapted Rusitec vessels having a dilution rate of 0.75d-1. Abomasal in vitro simulations demonstrated that 84% of the P. pastoris inoculum was lysed within 12 h, as necessary for the release of encapsulated protein. P.pastoris may be an effective post-fuminal delivery vehicle, provided that similar results are obtained in vivo. / xiv, 120 leaves : ill. ; 28 cm.

Pichia pastoris

Yeast fungi -- Biotechnology

Dissertations, Academic

Rumen -- Microbiology

Regulation of the Cdc25 mitotic inducer following replication arrest and DNA damage

Frazer, Corey Thomas

20 June 2011

Dephosphorylation of the Cdc2 kinase by the Cdc25 tyrosine phosphatase is the universally conserved trigger for mitotic entry. Cdc25 is also the point of convergence for checkpoint signaling pathways which monitor the genome for damaged DNA and incomplete replication. In addition, Cdc25 is inhibited by a MAP kinase cascade in the event of osmotic, oxidative and/or heat stress. These pathways inhibit cell cycle progression by phosphorylating Cdc25 resulting in its association with 14-3-3 and nuclear export. Although Cdc25 can be observed leaving the nucleus following inhibitory signals it is controversial whether phosphorylation, 14-3-3 binding or export itself is required for checkpoint proficiency. In fission yeast, Cdc25 is phosphorylated in vitro on 12 serine and threonine residues by the effector kinase of the DNA replication checkpoint, Cds1. Nine of these residues reside in the N-terminal regulatory region, while three are found in the extreme C-terminus of the protein. We show here that phosphorylation the nine N-terminal residues, nor any of the 12 in vitro sites, are required for enforcement of the DNA replication checkpoint. In lieu of Cdc25 phosphorylation the phosphatase is rapidly degraded and mitotic entry prevented by the action of the Mik1 kinase, targeting Cdc2. Thus, multiple mechanisms exist for preventing mitotic entry when S-phase progression is inhibited. The three C-terminal in vitro phosphorylation sites have not previously been examined in fission yeast. However, homology exists between the S. pombe protein and the Cdc25 orthologues in humans, Xenopus and Drosophila in this region. We report here that in S. pombe these sites are required to prevent mitotic entry following replication arrest in the absence of Mik1, and in the maintenance, but not establishment, of arrest following DNA damage. Our previous work showed that Cdc25 nuclear import requires the Sal3 importin-β but at the time we were unable to show a direct interaction between these two proteins. The final chapter of this thesis proves physical interaction by co-immunoprecipitation. Cdc25 mutants lacking all twelve putative Cds1 sites show nuclear localization during mitosis in a sal3- background, effectively reversing the cell cycle regulated pattern of accumulation of the phosphatase. / Thesis (Ph.D, Biology) -- Queen's University, 2011-06-20 12:16:15.71

Cdc25

Fission yeast

DNA damage checkpoint

DNA replication checkpoint

THE ROLE OF SCHIZOSACCHAROMYCES POMBE SER/THR KINASE IN GROWTH, STRESS RESPONSE AND NUTRIENT DEPRIVATION

Freitag, Silja I.

24 January 2012

Continuous sensation and reaction to environmental fluctuations is especially critical to the survival of unicellular organisms. Stress response mechanisms are essential for cells during the vegetative and sexual life cycles and quiescence. The Schizosaccharomyces pombe mitotic activator and stress response serine/threonine kinase Ssp1 acts independent of the major fission yeast Spc1 MAP kinase stress response cascade. Ssp1 is required at high temperatures in the presence of other stressors, ensures long-term viability in quiescent cells and allows efficient cell division in low-glucose conditions. Ssp1 is cytoplasmic but briefly localizes to the cell membrane after exposure to extracellular stress. It plays a role in actin depolymerization and is required for the change of growth polarity after cell division. After identifying 14-3-3 proteins Rad24 and Rad25 as putative Ssp1 binding partners, we confirmed the interaction with co-immunoprecipitation. Association of Ssp1 with Rad24 diminishes after 15 minutes of hyperosmotic stress, however Rad25 binding is retained. Loss of the rad24 gene product rescues both ssp1- mitotic delay at elevated temperatures and sensitivity to 0. 6M KCl. Conversely, overexpression of rad24 exacerbates ssp1 stress sensitivity and mitotic delay. Diffuse actin polarity and spheroid morphology in rad24- cells improves in an ssp1- background. Ssp1 localization to the cell membrane is negatively regulated by Rad24. Ssp1 does not co-localize with Arp3C (actin-related protein 3 homologue C) after osmotic stress, but instead appears to form a ring around the cell, suggesting localization to fission scars. Ssp1 is basally phosphorylated and hyperphosphorylated after glucose deprivation. Ssp1 is shuttled in and out of the nucleus and accumulates in the nucleus in an exportin Cmr1 dependent manner. Ssp1-GFP levels are constant in all stages of the vegetative cell cycle and Ssp1-GFP is present in both the sexual life cycle and quiescence. C-terminal and N-terminal truncation of ssp1 alters its subcellular localization. The C-terminal region is the site of hyperphosphorylation following glucose deprivation and is also necessary for membrane localization following osmotic stress. / Thesis (Ph.D, Biology) -- Queen's University, 2012-01-24 09:49:58.225

Exploring the role of the thioredoxin system, peroxiredoxins and glutaredoxins in aluminum and cadmium tolerance in yeast and Arabidopsis thaliana

Lopez Santiago, Diana Laura

Unknown Date

No description available.

aluminum

antioxidant

yeast

Arabidopsis

cadmium

thioredoxin reductase

signaling

Analyses of trans-acting factors that regulate RNA interference in Schizosaccharomyces pombe

Park, Jungsook

Unknown Date

No description available.

RAN interference

TGS, PTGS, Rdp1, Cut7

Fission yeast

Regulation of the thioredoxin system in Saccharomyces cerevisiae.

Padayachee, Letrisha.

January 2013

The thioredoxin system consisting of thioredoxin (Trx), thioredoxin reductase and NADPH plays a significant role in a large number of redox-dependent processes such as DNA synthesis and anti-oxidant defense. Elevated levels of this system have been associated with a number of diseases including cancer and HIV. Understanding the regulation of this network from a systems perspective is therefore essential. However, contradictory descriptions of thioredoxin as both an enzyme and redox couple have stifled the adoption of systems biology approaches within the field. Using kinetic modeling, this discrepancy was resolved by proposing that saturation of Trx activity could be due to the saturation of the Trx redox cycle which consequently allowed development of the first computational models of the thioredoxin system in Jurkat T-cells and Escherichia coli. While these models successfully described the network properties of the thioredoxin system in these organisms, further confirmatory studies were required before this modeling approach could be generally accepted. The aim of this study was to utilize computational and molecular methods to confirm or reject this proposed mechanism for thioredoxin activity. To determine if there is any difference in the kinetic models obtained when thioredoxin was modeled as an enzyme or as a redox couple, representative core models were developed. The data showed that when modeling Trx as a redox couple, the system was able to achieve steady state, there was a re-distribution of Trx into its oxidized form and, thioredoxin reductase affected the rates within the system. On the other hand, when Trx was modeled as an enzyme, the system could not reach a steady state, Trx remained in the reduced form and thioredoxin reductase concentration had no effect on the rates within the system. As these properties could be directly tested invitro, we sought to directly confirm which model was correct. The thioredoxin system from Saccharomyces cerevisiae was cloned, expressed and purified and substrate saturation curves were generated using insulin as a model substrate. The data showed that the system reached steady state and with increasing concentrations of insulin, the system saturated with a progressive re-distribution of the thioredoxin moiety into its oxidized form. Further, increasing the thioredoxin reductase concentration increased the flux through the system. Collectively, the results obtained through invitro analyses provided unambiguous support for the thioredoxin redox couple model. These results will enable the construction of a complete computational model of the yeast thioredoxin system and provide a basis for the analysis of this network in a number of pathologies. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2013.

Systems biology.

Proteins--Research.

Yeast extract.

Theses--Genetics.

Analysis of Saccharomyces cerevisiae genetic background and mitochondrial DNA polymerase variants on maintenance of the mitochondrial genome.

Young, Matthew J.

10 September 2008

The contribution of yeast strain background, specifically auxotrophic markers, to stability and fidelity of mtDNA replication was investigated. In summary, the ade2, his3delta200, and hap1 mutations have complex effects on mitochondrial functions, the severity of which appears to depend on other components in the genetic background of the strain. These results are important as many commonly used laboratory strains are related to the respiratory hampered S288c strain and are used for studies of orthologous human mutations associated with various mitochondrial diseases. These observations have added to our understanding of fungal mtDNA replication and have informed the mitochondrial community of problematic strains that need to be considered when using this model organism. The function of the yeast mitochondrial DNA polymerase (Mip1p) carboxyl-terminal extension (CTE) was investigated both in vivo and in vitro by genetically engineering various truncations of the CTE. The respiratory competence of mip1delta175 and mip1delta205 cells, in which Mip1p lacks the C-terminal 175 and 205 residues respectively, are indistinguishable from that of wild-type. In contrast, strains harbouring Mip1pdelta351, Mip1pdelta279, Mip1pdelta241, and Mip1pdelta222 rapidly lose mtDNA. At a low frequency, mip1delta216 cells grow poorly on glycerol. Fluorescence microscopy and Southern blot analysis revealed lower levels of mtDNA in these cells, and rapid loss of mtDNA during fermentative growth. Therefore, only the polymerase-proximal segment of the Mip1p CTE is necessary for mitochondrial function. To determine more precisely the defects associated with polymerase truncation variants, these proteins were overexpressed in yeast and used in a novel non-radioactive mtDNA polymerase assay. The threonine-661 and alanine-661 variants, shown by others to be responsible for the increased mtDNA mutability of various laboratory yeast strains at increased temperature, were examined in combination with CTE-truncations. These experiments suggest that exonuclease function is not effected in the alanine-661 variant at 37 degrees Celsius whereas polymerase activity is, and this higher relative level of exonuclease activity could be a contributing factor to mtDNA instability in S288c-related strains. Lastly, isogenic CTE truncation variants all have less DNA polymerase activity than their parental wild-type. Based on these results, several possible roles for the function of the CTE in mtDNA replication are suggested.

mitochondria

yeast

mitochondrial DNA polymerase

S288c

phylogeny

Saccharomyces cerevisiae

Chromatin Reassembly following a DNA Double-Strand Break Repair: The Ctf18-complex and Ctf4 work in concert with H3K56 Acetylation

Seepany, Harshika

25 August 2011

The budding yeast, Saccharomyces cerevisiae, serves as an excellent model for identifying fundamental mechanisms of DNA repair. A Local Coherence Detection (LCD) algorithm that uses biclustering to assign genes to multiple functional sub-groups was applied on the chromosome E-MAP containing genetic interactions among genes involved in nuclear processes. Using this method, we found that Asf1 and Rtt109, genes that are together required for histone H3K56 acetylation, cluster together with Ctf4, Ctf18, Ctf8 and Dcc1, genes important for efficient sister chromatid cohesion. It is known that H3K56 acetylation is required for post-repair chromatin reassembly at sites of DNA double-strand breaks (DSBs). The cohesion genes were previously implicated in the repair of some DNA DSBs, but the nature of their involvement has not been reported. The experimental data in my thesis work suggest that Ctf4, Ctf8, Ctf18 and Dcc1 function in the post-repair chromatin reassembly pathway.

yeast

genetic interaction

DNA repair

acetylation

cohesion

histone

DNA repair

Network Centralities and the Retention of Genes Following Whole Genome Duplication in Saccharomyces cerevisiae

Imrie, Matthew J.

01 May 2015

The yeast Saccharomyces cerevisiae genome is descendant from a whole genome duplication event approximately 150 million years ago. Following this duplication many genes were lost however, a certain class of genes, termed ohnologs, persist in duplicate. In this thesis we investigate network centrality as it relates to ohnolog re- tention with the goal of determining why only certain genes were retained. With this in mind, we compare physical and genetic interaction networks and genetic and pro- tein sequence data in order to reveal how network characteristics and post-duplication retention are related. We show that there are two subclasses of ohnologs, those that interact with their duplication sister and those that do not and that these two classes have distinct characteristics that provide insight into the evolutionary mechanisms that affected their retention following whole genome duplication. Namely, a very low ratio of non-synonymous mutations per non-synonymous site for ohnologs that retain an interaction with their duplicate. The opposite observation is seen for ohnologs that have lost their interaction with their duplicate. We interpret this in the fol- lowing way: ohnologs that have retained their interaction with their duplicate are functionally constrained to buffer for the other ohnolog. For this reason they are retained; ohnologs that have lost their interaction with their duplicate are retained because they are functionally divergent to the point of being individually essential. Additionally we investigate small scale duplications and show that, generally, the mechanism of duplication (smale scale or whole genomes) does not affect the distri- bution of network characteristics. Nor do these network characteristics correlate to the selective pressure observed by retained paralogous genes, including both ohnologs and small scale duplicates. In contrast, we show that the network characteristics of individual genes, particularly the magnitude of their physical and genetic network centralities, do influence their retention following whole genome duplication. / Graduate / mjrimrie@gmail.com

Yeast

Network Analysis

Saccharomyces cerevisiae

Centralities

Evolution

Whole Genome Duplication

Modelling and simulation of amino acid starvation responses in yeast Saccharomyces cerevisiae

You, Tao

January 2009

<i>Saccharomyces cerevisiae </i>is able to sense and respond to amino acid availability in the environment by reprogramming its gene expression.  Upon starvation for any amino acid, the yeast cell induces the biosynthesis of nearly all amino acids by upregulating the master transcription factor Gcn4, which is primarily controlled at the translational level.  Amino acid consumption is decreased by reducing general mRNA translation activity via <i>GCN2.  </i>The molecular mechanisms that mediate this response are known as the General Control Nonderepressible (GCN) response.  The aim of this thesis was to quantitatively understand the GCN response in <i>S. cerevisiae </i>by constructing a series of mathematical models, both deterministic and stochastic, based on published experimental results. Firstly, a deterministic model of general mRNA translation is described, which elaborates the translation initiation apparatus.  This model was used to predict the effects upon general translation activity of changing the abundance of specific initiation factors in isolation and collectively.  This model was also used to study the robustness of general mRNA translation and the trade-off between robustness and performance of this system. Secondly, a series of probabilistic and stochastic models of <i>GCN4 </i>mRNA translation based on Gillespie algorithm are described.  These probabilistic models successfully explained published results regarding the changes in <i>GCN4 </i>mRNA translation resulting from variation in uORF intercistronic distances.  The subsequent stochastic simulations suggested that histidine codon translation rates contribute significantly to the observed changes in ribosomal loading that occur on the <i>GCN4 </i>mRNA. Finally, a comprehensive deterministic model is described for the entire GCN system, integrating the above models.  This comprehensive model was able to predict the GCN responses to both natural and artificial amino acid starvation.  It successfully reproduced the phenotypes of some <i>GCN2 </i>and <i>GCN4 </i>mutants, and was also used to examine the fragility of GCN system when faced with severe artificial histidine starvation.  These predictions await experimental verification.

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