Global ETD Search

1	Structural Studies of the S-Adenosylmethionine-Dependent Methyltransferases Peng, Yi January 2009 (has links) No description available. Biochemistry
2	Structural and functional validation of S-adenosylmethionine decarboxylase as a novel drug target in the malaria parasite, Plasmodium falciparum Coertzen, Dina January 2014 (has links) Malaria is considered the most prevailing human parasitic disease. Despite various chemotherapeutic interventions being available, the parasite responsible for the most lethal form of malaria, Plasmodium falciparum, is continuously developing resistance towards drugs targeted against it. This, therefore, necessitates the need for validation of new antimalarial development. Polyamine biosynthetic enzymes, particularly S-adenosylmethionine-L-decarboxylase (PfAdoMetDC), has been identified as a suitable drug target for protozoan parasitic diseases due to its essential role in cell proliferation. Furthermore, in Plasmodium polyamine biosynthesis, PfAdoMetDC is organised into a unique bifunctional complex with ornithine decarboxylase (PfAdoMetDC/ODC) covalently linked by a hinge region, distinguishing this enzyme as unique a drug target. However, inhibitors targeting this pathway have not been successful in clinical assessment, creating the need for further research in identifying novel inhibitors. This study focused on the structural and functional characterisation of protein-specific properties of the AdoMetDC domain in P. falciparum parasites, as well as identifying novel inhibitors targeting this enzyme as a potential antimalarial therapeutic intervention. In order to develop novel inhibitors specifically targeting PfAdoMetDC through a structure-based drug discovery approach, the three-dimensional structure is required. However, due to a lack of structural and functional characterisation, determination of the crystal structure has been challenging. Heterologous expression of monofunctional PfAdoMetDC was achieved from a wild-type construct of the PfAdoMetDC domain including the covalently linked hinge region. In chapter 2, deletion of a large non-homologous, low-complexity parasite-specific insert (A3) in monofunctional PfAdoMetDC resulted in an increased yield, purity and sample homogeneity, whilst maintaining protein functionality and structural integrity. However, truncation of the proposed non-essential hinge region resulted in low-level expression of insoluble protein aggregates and a complete loss of protein activity, indicating that the hinge region is essential for monofunctional PfAdoMetDC. However, in the absence of the three-dimensional PfAdoMetDC crystal structure, novel derivatives of a well-known AdoMetDC inhibitor, MDL73811, were tested for their activity against heterologous PfAdoMetDC, as well as their potency against P. falciparum parasites, in chapter 3. The compound Genz-644131 was identified as a lead inhibitor of PfAdoMetDC, however, the poor membrane permeability of the compound resulted in low in vitro activity. Drug permeability of Genz-644131 into P. falciparum infected erythrocytes and its potency was significantly improved by its encapsulation into a novel immunoliposome based drug delivery system. The results presented here provide essential information for development of a unique strategy in obtaining suffiecient levels of fully active recombinant PfAdoMetDC of sufficient purity for crystallisation studies and subsequent structure-based drug design efforts. The combination of Genz-644131 with the novel drug delivery system, which markedly improved its potency against PfAdoMetDC may proof to be a viable antimalarial chemotherapeutic strategy for future investigations. / Thesis (PhD)--University of Pretoria, 2014. / tm2015 / Biochemistry / PhD / Unrestricted UCTD S-adenosylmethionine decarboxylase Plasmodium falciparum Parasite Specific Inserts Polyamines
3	Functional consequences of the inhibition of Malaria S-adenosylmethionine decarboxylase as a key regulator of polyamine and methionine metabolism Smit, Salome 22 June 2011 (has links) Malaria presents a global health risk that is becoming increasingly difficult to treat due to increased resistance of both the parasite and mosquito to all known drugs. Identification of novel drug targets are therefore essential in the fight against malaria. Polyamines are small flexible polycations that are represented by three basic polyamines. The interaction of polyamines with various macromolecules may lead to stabilisation of DNA, regulation of transcription, replication, and also have an important role in cellular differentiation, proliferation, growth and division. Therefore, disruption of polyamine biosynthesis presents a unique drug target worth exploiting. Polyamine biosynthesis in P. falciparum is regulated by a unique bifunctional S-adenosylmethionine decarboxylase/ornithine decarboxylase (AdoMetDC/ODC) complex, which is unique to P. falciparum and differs completely from human polyamine biosyntehsis. The inhibition of AdoMetDC induces spermidine and subsequent spermine depletion within the parasite that ultimately results in cell cycle arrest. A functional genomics approach was used within this study to identify a global response of the parasite due to the inhibition of AdoMetDC with the irreversible inhibitor, MDL73811. The proteomics approach was optimised for conditions specific to our laboratory with regard to protein extraction, Plasmodial protein quantification, spot detection and finally protein identification by mass spectrometry (MS). This methodology resulted in reliable spot detection and achieved a 95% success rate in MS/MS identification of protein spots. Application of this methodology to the analyses of the Plasmodial ring and trophozoite proteomes ultimately resulted in the identification of 125 protein spots from the Plasmodial ring and trophozoite stages, which also confirmed stage specific protein production. Various protein isoforms were present which may be of significant biological importance within the Plasmodial parasite during development in the intraerythrocytic developmental cycle. Subsequent application of the 2-DE methodology to the proteome of AdoMetDC inhibited parasites resulted in the identification of 61 unique Plasmodial protein groups that were differentially affected by the inhibition of AdoMetDC in 2 time points. The transcriptome of AdoMetDC inhibited parasites were also investigated at 3 time points. Investigation into the transcriptome revealed the differential regulation of 549 transcripts, which included the differential regulation of polyamine specific transcripts. Inhibition of AdoMetDC provided a unique polyamine specific transcriptomic signature profile that demonstrated unique interactions between AdoMetDC inhibition and folate biosynthesis, redox metabolism and cytoskeleton biogenesis. The results presented provide evidence that the parasite responds to AdoMetDC inhibition by the regulation of the transcriptome and proteome in an attempt to alleviate the effects of AdoMetDC inhibition. Further analyses of the metabolome also provided evidence for the tight regulation of the AdoMet cycle. Overall, this study demonstrated important functional consequences as a result of AdoMetDC inhibition. / Thesis (PhD)--University of Pretoria, 2010. / Biochemistry / unrestricted Methionine metabolism Malaria S-adenosylmethionine decarboxylase Mosquito Parasite UCTD
4	Identification of Factors Involved in the Regulation of the <i>Bacillus subtilis metK</i> Gene Allen, George M. January 2016 (has links) No description available. Microbiology Riboswitch S-adenosylmethionine regulated mRNA stability S box riboswitch
5	EFFECT OF NICOTINE ON LUNG S-ADENOSYLMETHIONINE AND PNEUMOCYSTIS PNEUMONIA DEVELOPMENT Moncada Benavides, Camilo Andres January 2012 (has links) Infection with "Pneumocystis" causes a ≥ 99% depletion of plasma S-adenosylmethionine (AdoMet) levels in both "Pneumocystis" pneumonia (PcP) animal models and patients. AdoMet is a critical cellular metabolic intermediate, with a pivotal role as methyl donor in a myriad of biochemical processes and necessary for the synthesis of the essential polyamines spermidine and spermine. In the target tissue of "Pneumocystis", the lung, levels of AdoMet were previously shown to be depleted experimentally using nicotine. Here we show that chronic administration of nicotine in an animal model of PcP resulted in decreased lung AdoMet content. Since "Pneumocystis" is dependent on this metabolite, PcP burden was also relived. We hypothesized that the underlying mechanism behind nicotine-induced AdoMet depletion was an increased consumption of AdoMet through the polyamine pathway where the increased activity of N-1-spermidine/spermine acetyl transferase raises the catabolic / anabolic cycling of polyamines, a process that utilizes AdoMet. In a critical test of our hypothesis, we found that blockage of polyamine metabolism via inhibition of the polyamine biosynthetic enzyme ornithine decarboxylase (ODC) hinders the effect of nicotine on lung AdoMet levels. Further support is provided by metabolite analyses showing nicotine to cause a strong diversion of AdoMet toward polyamine synthesis and away from methylation reactions; these shifts are also reversed by inhibition of ODC. Because the nicotine effect on "Pneumocystis" is so striking, we considered the possibility of tissue specificity. Using laser capture microdissection (LCM), we collected samples of lung alveolar regions (site of infection) and respiratory epithelium for controls. We found nicotine to cause increased ODC activity in alveolar regions but not airway epithelium; we conclude that tissue specificity likely contributes to the effect of nicotine on "Pneumocystis" pneumonia. Our studies demonstrate the feasibility of pharmacological manipulation of the polyamine pathway in order to reduce AdoMet levels in the lung and prompted the assessment of compounds alternative to nicotine with the potential to achieve a comparable effect. In vitro evaluation of the polyamine analog DENSPM along with putrescine in type II alveolar cell lines, indicates that although such a combination has the potential to induce polyamine flux, an apparent competition for the same polyamine transport system impairs simultaneous uptake of both compounds at effective concentrations. In conclusion, we showed that chronic nicotine administration causes reduction of AdoMet levels in rat lung following 21 days of treatment, by a mechanism involving the induction of polyamine flux, which is responsible of increased AdoMet utilization for polyamine biosynthesis. According to LCM-based analysis, this effect seems to be confined to the alveolar regions of the lung. / Biochemistry Biochemistry Laser Capture Microdissection Lung Nicotine Pneumocystis Polyamines S-adenosylmethionine
6	Post-translational generation of Cá-formylglycine in Prokaryotic Sulfatsases by Radical SAM-Proteins / Posttranslationale Bildung von Cá-formylglycine in Prokaryotischen bakterieller Sulfatasen durch Radikal-SAM-Proteine Fang, Qinghua 22 January 2004 (has links) No description available. Mathematics and Computer Science Formylglycine Proteine Modifikation Radikal-SAM-Proteine Sulfatasen S-adenosylmethionine 570 Biowissenschaften Biologie Formylglycine protein modification radical-SAM-protein sulfatase S-adenosylmethionine 42 WA
7	INVESTIGATING KEY POST-PKS ENZYMES FROM GILVOCARCIN BIOSYNTHETIC PATHWAY Tibrewal, Nidhi 01 January 2013 (has links) Gilvocarcin V (GV) belongs to the angucycline class of antibiotics that possesses remarkable anticancer and antibacterial activities with low toxicity. Gilvocarcin exhibits its light induced anticancer activity by mediating crosslinking between DNA and histone H3. When photo-activated by near-UV light, the C8 vinyl group forms a [2+2] cycloadduct with thymine residues of double stranded DNA. D-fucofuranose is considered essential for histone H3 interactions. However, the poor water solubility has rendered it difficult to develop gilvocarcin as a drug. We aim to design novel gilvocarcin analogues with improved pharmaceutical properties through chemo-enzymatic synthesis and mutasynthesis. Previous studies have characterized many biosynthetic genes encoding the gilvocarcin biosynthetic skeleton. Despite these previous findings the exact functions of many other key genes are yet to be fully understood. Prior gene inactivation and cross-feeding experiments have revealed that the first isolable tetracyclic aromatic product undergoes a series of steps involving C–C bond cleavage followed by two O-methylations, a penultimate C-glycosylation and final lactone formation in order to fully develop the gilvocarcin structure. To provide a deeper understanding of these complex biochemical transformations, three specific aims were devised: 1) synthesis of the proposed intermediate and in vitro enzyme reactions revealed GilMT and GilM’s roles in gilvocaric biosynthesis; 2) utilizing in vitro studies the enzyme responsible for the C–C bond cleavage and its substrate were determined; 3) a small series of structural analogues of the intermediate from the gilvocarcin pathway was generated via chemical synthesis and fed to the mixture of the enzymes, GilMT and GilM. These reaction mixtures were then analyzed to establish the diversity of substrates tolerated by the enzymes. Gilvocarcin S-adenosylmethionine O-methyltransferase Baeyer-Villiger monooxygenases Medicinal and Pharmaceutical Chemistry
8	Effects of Long-Term Administration of Caffeine in a Mouse Model for Alzheimer’s Disease Schleif, William 12 September 2005 (has links) A recent epidemiological study suggested that higher caffeine intake reduces the risk of Alzheimer's disease (AD). Caffeine, a widely consumed stimulatory drug, is a non-selective adenosine receptor antagonist that has been shown to increase plasma adenosine levels in rodents. To determine any long-term protective effects of caffeine in a controlled longitudinal study, caffeine was added to the drinking water of APPsw transgenic (Tg) mice between 4 and 9 1/2 months of age, with behavioral testing done during the last 6 weeks of treatment. The average daily intake of caffeine per mouse (1.5 mg) was the human equivalent of 5 cups of coffee/day. Across multiple cognitive tasks of spatial learning/reference memory, working memory, and recognition/identification, Tg mice given caffeine (Tg+Caff) performed significantly better than Tg control mice and similar to non-transgenic controls. Discriminant Function Analysis involving multiple cognitive measures clearly showed the superior overall cognitive performance of Tg+Caff mice compared to Tg controls. Analysis of Aβ in the hippocampus by ELISA revealed Tg+Caff mice had significantly less soluble Aβ1-40 and insoluble Aβ1-42. In a follow-up study involving neurochemical analysis only, caffeine was added to the drinking water of 17 month old APPsw mice for 18 days. In this study, Tg+Caff mice also showed a significant reduction of insoluble Aβ1-42 in the hippocampus. In contrast to the reduced extracellular brain levels of adenosine in Tg controls, caffeine treatment normalized brain adenosine levels in Tg mice to that of non-transgenic controls. Analysis of amyloidogenic secretase activity revealed the reduction in Αβ is likely because of a reduction in gamma secretase activity as a result of increased SAM silencing of PS1 expression. This study suggest that a modest, long-term caffeine intake of approximately 500 mg per day (5 cups of coffee) may reduce considerably the risk of AD by decreasing amyloidogenesis. Amyloid S-adenosylmethionine PS1 Adenosine Transgenic mice American Studies Arts and Humanities
9	The effect of putative vesicular stomatitis virus methyltransferase mutants on transcription and replication Tower, Dallas Lauren, January 2005 (has links) Thesis (M.S.)--University of Florida, 2005. / Typescript. Title from title page of source document. Document formatted into pages; contains 57 pages. Includes Vita. Includes bibliographical references.
10	Biofilm formation and physiological heterogeneity of Listeria monocytogenes Lee, Yue-Jia 09 August 2019 (has links) A contributing factor in recurrent Listeria monocytogenes (L. monocytogenes) food contamination is that this bacterium produces biofilms on surfaces to persist in food-processing environments. Quorum sensing (QS) is a cell-to-cell communication system utilized by bacteria within biofilms to collaborate and adapt to environmental stresses. However, the details of how the QS-dependent network contributes to bioﬁlm development of L. monocytogenes have yet to be well understood. By comparing the transfer rates of planktonic and biofilm (sessile) L. monocytogenes from stainless steel blades to bologna slices, we found that sessile bacteria had reduced transferability onto a single slice but caused the increase in the number of contaminated slices. This suggests that physiological adaptions derived during biofilm development affect bacterial dissemination. Given the contribution of proteins and environmental temperatures to the extracellular polymeric substances (EPS) synthesis and biofilm integrity, we evaluated the exoproteomes of biofilms formed at 25 and 37°C using 2D-gel electrophoresis and LC-MS/MS. We found exoproteases Lmo0186, Cwh, and Spl exclusively in biofilms formed at 25°C and their greater expression in the gene level at 25°C. By using the zymography and crystal-violet-staining assay with a protease inhibitor, we observed a greater proteolytic activity at lower temperatures and showed that the attenuated proteolytic activity of proteases is positively correlated with increased biofilmorming ability at 25°C. Considering the transcriptional role of QS systems during biofilm development, we investigated how the accessory gene regulator (Agr)-based and metabolite S-Adenosylmethionine (SAM)-involved QS systems modulate nutrient availability and EPS synthesis. The results revealed that the SAM signal interacts with the Agr QS at the transcriptional level during biofilm development, whereas SAM and Agr QS regulate distinct EPS synthesis pathways. Additionally, this interaction is dependent on bacterial life modes (planktonic and sessile). Overall, we conclude that L. monocytogenes manipulates the synthesis of EPS with the coregulation of metabolism and QS for biofilm formation and the production of exoproteases for biofilm dispersion. These precise regulations on EPS enable L. monocytogenes to prolong its survival and promote its dissemination in environments. exoproteome extracellular polymeric substances food processing plants quorum sensing S-adenosylmethionine sessile life mode

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