Regulation of clavam metabolite production in Streptomyces clavuligerus

Kwong, Thomas

Unknown Date

No description available.

clavam

clavulanic acid

streptomyces clavuligerus

two component system

transcriptional regulators

phosphorylation

paralogous genes

La sécrétion de la protéine Tau : nouveau mécanisme de propagation de la pathologie de Tau dans la maladie d'Alzheimer

Plouffe, Vanessa

12 1900

Tau est une protéine associée aux microtubules enrichie dans l’axone. Dans la maladie d’Alzheimer, Tau devient anormalement hyperphosphorylée, s’accumule dans le compartiment somato-dendritique et s’agrège pour former des enchevêtrements neurofibrillaires (NFTs). Ces NFTs se propagent dans le cerveau dans un ordre bien précis. Ils apparaissent d’abord dans le cortex transenthorinal pour ensuite se propager là où ces neurones projettent, c’est-à-dire au cortex entorhinal. Les NFTs s’étendent ensuite à l’hippocampe puis à différentes régions du cortex et néocortex. De plus, des études récentes ont démontré que la protéine Tau peut être sécrétée par des lignées neuronales et que lorsqu’on injecte des agrégats de Tau dans un cerveau de souris, ceux-ci peuvent pénétrer dans les neurones et induire la pathologie de Tau dans le cerveau. Ces observations ont mené à l’hypothèse que la protéine Tau pathologique pourrait être sécrétée par les neurones, pour ensuite être endocytée par les cellules avoisinantes et ainsi propager la maladie. L’objectif de la présente étude était donc de prouver la sécrétion de la protéine Tau par les neurones et d’identifier par quelle voie elle est secrétée. Nos résultats ont permis de démontrer que la protéine Tau est sécrétée par des neurones corticaux de souris de type sauvage ainsi que dans un modèle de surexpression dans des cellules HeLa et PC12. Nos résultats indiquent que la sécrétion de Tau se ferait par les autophagosomes. Finalement, nous avons démontré que la protéine Tau sécrétée est déphosphorylée et clivée par rapport à la protéine Tau intracellulaire non sécrétée. / Tau, a microtubule-associated protein, is enriched in the axon. In Alzheimer’s disease, Tau becomes hyperphosphorylated, redistributes to the somato-dendritic compartment and forms aggregates called neurofibrillary tangles (NFTs). The NFTs propagates in a predictable manner in particular neuronal networks. Indeed, they appear in the trans-entorhinal region and then propagate to the entorhinal cortex where the trans-entorhinal cortex projects. Then, the NFTs propagate to the hippocampus and to different regions of the cortex and neocortex. Recent studies have reported that Tau can be secreted by neuronal cell lines. Besides, when aggregates of Tau protein were injected in mouse brain, they could enter neurons and induced Tau pathology. Based on those observations, it was speculated that Tau could be secreted by neurons and then captured by neighbouring cells to propagate Tau pathology in the brain. The goal of the present study was to prove that Tau can be secreted by neurons and to find the secretory pathway involved in Tau secretion. Moreover, the phosphorylation state of Tau protein was examined and compared to intracellular non-secreted Tau. Our results showed that Tau is secreted by cortical neurons isolated from wild-type mice and by HeLa and PC12 cells overexpressing human Tau. Our results also indicated that autophagosomes would be involved in Tau secretion. Finally, we found that secreted Tau was dephosphorylated and cleaved compared to the non-secreted intracellular Tau.

Tau

Alzheimer

Sécrétion

Phosphorylation

Autophagie

Exosomes

Tauopathies

Secretion

Autophagy

Mechanisms of vitamin D receptor and retinoid X receptor mediated hormone resistance and cell differentiation in normal and cancer cells

Macoritto, Michael.

January 2007

Vitamin D is a precursor to a steroid hormone, 1,25 dihydroxyvitamin D (1,25(OH)2D). After its discovery and the characterization of its receptor, the vitamin D receptor (VDR), it was initially thought only to be involved in calcium homeostasis, but further research revealed an important role for vitamin D in the regulation of cell growth and differentiation of such cells as osteoblasts and bone marrow adipocytes. 1,25(OH)2D has also been shown to be a strong inhibitor and pro-differentiator of keratinocytes. The anti-proliferative and pro-differentiative properties of this hormone have led to studies where 1,25(OH)2D anticancer properties were assessed and initial findings that showed a requirement of other factors beyond VDR to induce 1,25(OH)2D signaling led to the identification of the retinoid X receptor, a common heterodimeric partner for several hormone receptors. The focus of thesis was to further elucidate the structure-function relationship of both the vitamin D receptor and the retinoid X receptor. Additionally, contributions to work directed towards further identifying the effects of vitamin D on osteoblast differentiation and survival. Interactions of 1,25(OH) 2D3 with its cognate receptor, identifying a key amino acid (Tryptophan 286) required for ligand contact and transcriptional activation, are described in Chapter 2. Mechanisms of vitamin D action on mesenchymal stem cell differentiation, promotion of osteoblast induction and maturation, and inhibition of adipocyte differentiation, are eluicidated in Chapter 3. Chapter 4 illustrates the effects of RAS/RAF/Mitogen-activated protein kinase mediated RXRalpha phosphorylation on the three-dimensional structure of the RXR/nuclear receptor partner heterodimers. Furthermore, this chapter reveals the inhibitory effect of the phosphorylation of a critical amino acid (serine 260) on the interaction of the AF-2 domain of the RXR with several coactivators, resulting in a decrease in the signaling potential of multiple steroid hormone receptors. The findings of this thesis further the knowledge of several areas of vitamin D biology, including both the canonical areas of bone formation, and the non-canonical area of vitamin D and cancer.

Receptors, Calcitriol -- genetics.

Retinoid X Receptors -- genetics.

Ligands.

Hormones -- metabolism.

Bone and Bones -- metabolism.

Osteogenesis.

Phosphorylation.

Investigating the Role of Hsp27 in Drosophila : Genetic and Phospho - mutant Analysis

Furbee, Emily Christine

01 August 2014

HSP27, the Drosophila homolog of mammalian HspB1, is a nuclear sHsp that is both stress induced and developmentally regulated with a conserved cyto-protective function. It is multiply phosphorylated in vivo through an unconfirmed mechanism at unidentified residues. The effect of phosphorylation on its localization, oligomerization, and function is also not well understood. Here we report a genetic investigation into the role of Hsp27 in Drosophila development, and a preliminary investigation into the effect of phosphorylation on HSP27 localization and function in Drosophila S2 cells. Through a proteomic screen, a pro-apoptotic role for Hsp27 in embryonic developmentally regulated programmed cell death was suggested and supported by RNAi experiments, but not replicated using Hsp27null mutant stocks. These stocks were complicated by the intriguing appearance of multiple background mutations. Specific developmental defects in transgenic lines overexpressing phospho-mutant isoforms were then investigated. These too were subject to multiple independent incidences of background genetic mutation, which we believe may be related to Hsp27 mis-expression. We also studied the endogenous expression and localization pattern of HSP27 in stressed and unstressed Drosophila S2 cells. We found evidence that wild-type protein localization is influenced by stress. Finally, we took a first step toward understanding how phosphorylation might regulate HSP27 localization by examining the effect of targeted mutations of serine residues (S58, S71, and S75) on the localization pattern of exogenous HSP27. By characterizing the expression of endogenous and overexpressed HSP27 in Drosophila cells, we provide a foundation for future investigation into the regulated localization and function of HSP27 that can be extended to address the regulatory mechanisms that govern the protective capacities and oligomeric properties of phosphorylated HSP27 in Drosophila.

small heat shock proteins

drosophilia

programmed cell death

hsp27

phosphorylation of hsp27

ROLE OF REPLICATION PROTEIN A (RPA) AND PROLIFERATING CELL NUCLEAR ANTIGEN (PCNA) IN DNA MISMATCH REPAIR

Guo, Shuangli

01 January 2005

PCNA and RPA are required for DNA mismatch repair (MMR), but their rolesin the pathway are not fully understood. Using an affinity pull-down approach, weshow that (1) increased PCNA binding to DNA heteroduplexes is associated withthe appearance and accumulation of excision products; and (2) RPAphosphorylation occurs when DNA polymerase ?? binds to the DNA substrate. Wetherefore hypothesize that PCNA plays an important role in mismatch-provokedexcision and that RPA phosphorylation plays an important role in DNA resynthesis.To determine the role of PCNA in MMR, mismatch-provoked and nick-directedexcision was assayed in a cell-free system in the presence of the PCNA inhibitor,p21CIP1/WAF. We show that whereas PCNA is essential for 3' directed excision, it isdispensable for the 5' directed reaction, suggesting a differential role for PCNA inMMR. We further find that the PCNA-dependent pathway is the only pathway for3' directed excision, but there are at least two pathways for 5' directed excision,one of which is a PCNA-independent 5' excision pathway. To determine if RPAphosphorylation facilitates DNA resynthesis, a gap-filling assay was developedusing both a cell-free system and a purified system, and we demonstrate that RPAphosphorylation stimulates DNA polymerase ??-catalyzed resynthesis in bothsystems. Kinetic studies indicate that phosphorylated RPA has a lower affinity forDNA compared with un-phosphorylated RPA. Therefore, the stimulation ofresynthesis by phosphorylated RPA is likely due to the fact that phosphorylationpromotes the release of RPA from DNA, thereby making DNA template availablefor resynthesis.

Phosphorylation in State Transition : Less cause more effect / Fosforylering och "state transitions" : mindre orsak, mer verkan

Damkjaer, Jakob

January 2011

Study of the Arabidopsis thaliana knockout mutant lacking Lhcb3 (koLhcb3) have revealed a close similarity to the wild type plants. Growth rate, NPQ, qP, Φ(PSII), circular dichroism spectra, pigment composition and content of LCHII trimers have been found to be unaffected by this mutation. The proteomic analysis shows only some minor increases in the amount of Lhcb1 and Lhcb2. PAM fluorometry revealed a significant increase in the rate of the state 1 to state 2 state transition in the koLhcb3. None the less, the extent of state transition is identical to wild type. Alterations in the PSII-LHCII supercomplex structure have been demonstrated as well. The M-trimer was found to be rotated ~21° CCW. This altered binding of the LHCII M-trimer is likely the cause of the altered affinity resulting in the increased rate of state transition. Proteomic analysis of the phosphorylation of LHCII revealed a significant increase in state 1 and 2 LHCII phosphorylation relative to wild type. Investigation whether phosphorylation or the altered LHCII binding is the cause of the accelerated rate of state transition have not been conclusive so far. A Lhcb6 depleted mutant (koLhcb6) showed a significant alteration of the PSII-LHCII supercomplex structure and photosynthetic acclimation processes. The LHCII M-trimer is depleted in the PSII-LHCII supercomplexes causing the state transition process to be “stuck” in state 2 and the mutants ability to preform NPQ is inhibited as well. The Lhcb6 protein was concluded to be essential for the binding of the LHCII M-trimer to the PSII core as well as energy transfer. The depletion of LHCII M-trimer was linked to the reduced ability to photoacclimate using NPQ as well.

Photosynthesis

Photoacclimation

State Transtion

LHCII Phosphorylation

Lhcb3

Lhcb6

Plant physiology

Växtfysiologi

Etude des fonctions mitotiques du domaine amino-terminal de CENP-A

Goutte-gattat, Damien

16 December 2011

Le variant d'histone CENP-A est le facteur responsable de la détermination épigéné- tique du centromère. Il permet le recrutement de nombreuses protéines centromériques, et constitue ainsi la brique fondatrice du kinétochore. Il possède un domaine amino-terminal non structuré dont la fonction précise reste encore à élucider, bien qu'il soit déjà établi chez certaines espèces que ce domaine est requis pour le bon fonctionnement du cen- tromère et conséquemment le bon déroulement de la mitose. Nous avons construit des lignées cellulaires humaines exprimant stablement diverses formes mutantes de CENP-A, qui nous ont permis de réaliser des expériences de pseudogénétique en supprimant l'ex- pression de la protéine CENP-A endogène. Nous observons une augmentation drastique du taux de défauts de ségrégation des chromosomes et de cellules plurinucléées dans des cellules exprimant uniquement le domaine globulaire de CENP-A, ce qui est en accord avec les données de la littérature et confirme l'importance du domaine amino-terminal. Un phénotype similaire est observé dans des cellules exprimant une protéine CENP-A entière mais dont le domaine amino-terminal n'est pas phosphorylable. Nos résultats montrent l'implication de la phosphorylation de la sérine de CENP-A dans le bon déroulement de la mitose, et suggèrent que la fonction mitotique du domaine amino-terminal est centrée sur cette seule phosphorylation.

Chromatine

Mitose

Variants d'histone

Phosphorylation

Involvement of the C-terminal Repeat (CTR) Domain in the Protein Interactions and Functions of Spt5

Kuo, Wei Hung William

26 June 2014

Transcription elongation by RNA polymerase II is regulated by an array of protein complexes. Among various elongation factors, Spt5 is conserved in the three kingdoms of life. I investigated functional interactions of its C-terminal repeats (CTR) domain with several elongation protein complexes in Saccharomyces cerevisiae. By using genetics and molecular biology methods, I established two major pathways in this thesis. The first describes how BUR kinase-mediated phosphorylation of CTR domain leads to co-transcriptional recruitment of the PAF complex to regulate histone modifications on active genes. The second describes how CTR phosphorylation facilitates recruitment of capping enzymes to enhance gene splicing. Finally, several Spt5-associated protein complexes were studied, and potential molecular mechanisms underlying these observations are proposed and discussed.

0307

0369

Involvement of the C-terminal Repeat (CTR) Domain in the Protein Interactions and Functions of Spt5

Kuo, Wei Hung William

26 June 2014

Transcription elongation by RNA polymerase II is regulated by an array of protein complexes. Among various elongation factors, Spt5 is conserved in the three kingdoms of life. I investigated functional interactions of its C-terminal repeats (CTR) domain with several elongation protein complexes in Saccharomyces cerevisiae. By using genetics and molecular biology methods, I established two major pathways in this thesis. The first describes how BUR kinase-mediated phosphorylation of CTR domain leads to co-transcriptional recruitment of the PAF complex to regulate histone modifications on active genes. The second describes how CTR phosphorylation facilitates recruitment of capping enzymes to enhance gene splicing. Finally, several Spt5-associated protein complexes were studied, and potential molecular mechanisms underlying these observations are proposed and discussed.

0307

0369

Design and data analysis of kinome microarrays

2014 May 1900

Catalyzed by protein kinases, phosphorylation is the most important post-translational modification in eukaryotes and is involved in the regulation of almost all cellular processes. Investigating phosphorylation events and how they change in response to different biological conditions is integral to understanding cellular signaling processes in general, as well as to defining the role of phosphorylation in health and disease. A recently-developed technology for studying phosphorylation events is the kinome microarray, which consists of several hundred "spots" arranged in a grid-like pattern on a glass slide. Each spot contains many peptides of a particular amino acid sequence chemically fixed to the slide, with different spots containing peptides with different sequences. Each peptide is a subsequence of a full protein, containing an amino acid residue that is known or suspected to undergo phosphorylation in vivo, as well as several surrounding residues. When a kinome microarray is exposed to cell lysate, the protein kinases in the lysate catalyze the phosphorylation of the peptides on the array. By measuring the degree to which the peptides comprising each spot are phosphorylated, insight can be gained into the upregulation or downregulation of signaling pathways in response to different biological treatments or conditions. There are two main computational challenges associated with kinome microarrays. The first is array design, which involves selecting the peptides to be included on a given array. The level of difficulty of this task depends largely on the number of phosphorylation sites that have been experimentally identified in the proteome of the organism being studied. For instance, thousands of phosphorylation sites are known for human and mouse, allowing considerable freedom to select peptides that are relevant to the problem being examined. In contrast, few sites are known for, say, honeybee and soybean. For such organisms, it is useful to expand the set of possible peptides by using computational techniques to predict probable phosphorylation sites. In this thesis, existing techniques for the computational prediction of phosphorylation sites are reviewed. In addition, two novel methods are described for predicting phosphorylation events in organisms with few known sites, with each method using a fundamentally different approach. The first technique, called PHOSFER, uses a random forest-based machine-learning strategy, while the second, called DAPPLE, takes advantage of sequence homology between known sites and the proteome of interest. Both methods are shown to allow quicker or more accurate predictions in organisms with few known sites than comparable previous techniques. Therefore, the use of kinome microarrays is no longer limited to the study of organisms having many known phosphorylation sites; rather, this technology can potentially be applied to any organism having a sequenced genome. It is shown that PHOSFER and DAPPLE are suitable for identifying phosphorylation sites in a wide variety of organisms, including cow, honeybee, and soybean. The second computational challenge is data analysis, which involves the normalization, clustering, statistical analysis, and visualization of data resulting from the arrays. While software designed for the analysis of DNA microarrays has also been used for kinome arrays, differences between the two technologies prompted the development of PIIKA, a software package specifically designed for the analysis of kinome microarray data. By comparing with methods used for DNA microarrays, it is shown that PIIKA improves the ability to identify biological pathways that are differentially regulated in a treatment condition compared to a control condition. Also described is an updated version, PIIKA 2, which contains improvements and new features in the areas of clustering, statistical analysis, and data visualization. Given the previous absence of dedicated tools for analyzing kinome microarray data, as well as their wealth of features, PIIKA and PIIKA 2 represent an important step in maximizing the scientific value of this technology. In addition to the above techniques, this thesis presents three studies involving biological applications of kinome microarray analysis. The first study demonstrates the existence of "kinotypes" - species- or individual-specific kinome profiles - which has implications for personalized medicine and for the use of model organisms in the study of human disease. The second study uses kinome analysis to characterize how the calf immune system responds to infection by the bacterium Mycobacterium avium subsp. paratuberculosis. Finally, the third study uses kinome arrays to study parasitism of honeybees by the mite Varroa destructor, which is thought to be a major cause of colony collapse disorder. In order to make the methods described above readily available, a website called the SAskatchewan PHosphorylation Internet REsource (SAPHIRE) has been developed. Located at the URL http://saphire.usask.ca, SAPHIRE allows researchers to easily make use of PHOSFER, DAPPLE, and PIIKA 2. These resources facilitate both the design and data analysis of kinome microarrays, making them an even more effective technique for studying cellular signaling.

Peptide arrays

Kinome arrays

Phosphorylation

Cellular signaling

Sequence homology

Machine learning

Clustering

Statistical methods