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Axial Ligand Mutant: H229ANguyen, Nhung Phuong 08 August 2008 (has links)
Many pathogenic bacteria use their iron acquisition mechanisms to live inside hosts. Streptococcus pyogenes is a pathogenic bacterium that uses streptococcal iron acquisition ABC transporter to obtain heme. SiaA (HtsA, spy1795), a lipoprotein located on the cell surface, serves as a heme binding protein. To understand the iron-uptake mechanism, histidine 229, one of the two proposed axial ligands in SiaA, was mutated to alanine. SiaA H229A was expressed in E. coli, lysed by French Press, and purified by fast protein liquid chromatography (FPLC). SDS-PAGE indicated that pure protein was isolated. Nickel affinity FPLC gave purer H229A when 0.5 M imidazole was added to the binding buffer. Overall, histidine 229 is likely to be an axial ligand in wild type SiaA, as shown by the fact the mutant readily lost heme as evidenced by UV-vis spectra.
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Assessment of High Purity Mesenchymal Stromal Cells Derived Extracellular Vesicles Presenting NRP1 Show Functional Suppression of Activated Immune CellsGobin, Jonathan 04 January 2022 (has links)
Background: The focus of this study was to investigate how producing human bone marrow (hBM) derived mesenchymal stromal cell (MSC) extracellular vehicles (EVs) in a high purity isolation system would affect their established characterization criteria and address the validity of these methods of EV production. Additionally, we set out to functionally characterize the hBM-MSC-EVs for their identified immunomodulatory ability while also assessing the presence of novel MSC-EV marker NRP1 identified by our group to further affirm its validity as a functional MSC-EV identity marker.
Methods: Each hBM-MSC-EV donor was cultured in a hollow-fiber bioreactor system in non-stimulating serum/xeno-free conditions for 25 days to produce EVs persistently under quiescent conditions to characterize the hBM-MSC-EVs in their native form. EVs were isolated by traditional PEG-based precipitation for preliminary characterization to monitor bioreactor production wherein they were characterized using multimodal tangential flow filtration coupled with fast protein liquid chromatograph (FPLC) size exclusion/high-affinity purifications to obtain the final highly purified EV sample. Additionally, functional analysis of their immunomodulatory ability, EVs and MSCs were incubated with activated peripheral blood mononuclear cells (PBMCs) as an in-vitro model to evaluate their potency.
Results: The hBM-MSC-EVs produced from the bioreactor system showed consistent characterization in accordance with the MISEV2018 establish criteria. We were also able to demonstrate their functional ability by observing statistically significantly immunomodulatory ability of activated PBMCs equivalent to native MSC ability. We were also able to validate the present of NRP1 on all hBM-MSC-EV samples produced confirming its validity as a MSC-EV marker.
Conclusion: The significance of the results obtained from this study confirms the production of MSC-EV using a bioreactor and high purity isolation for obtaining consistent MSC-EVs for downstream investigation. Additionally, we were able to demonstrate the significance of MSC-EVs on MSC signaling for immunomodulation by showing equivalent functional potency when tested in-vitro. These results contribute to further understanding the biological attributes of MSC-EVs and contribute to the validation of currently established characterization guidelines.
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Proteomics of the ovine cataractMuir, Matthew Stewart January 2008 (has links)
The lens of the eye needs to be completely transparent in order to allow all light entering the eye to reach the retina. This transparency is maintained by the highly ordered structure of the lens proteins the crystallins. Any disruption to the lens proteins can cause an opacity to develop which is known as cataract. During cortical cataract formation there is increased truncation of the lens crystallins. It is believed that overactivation of calcium-dependent cysteine proteases, the calpains, is responsible for the increased proteolysis of the crystallins seen during cataractogenesis. Within the ovine lens there are three calpains, calpain 1, 2 and the lens specific calpain Lp82. The aim of this thesis was to determine the changes in the lens proteins during ageing and cataractogenesis, and to establish the role of the calpains in these processes. Calpain 1 and 2 were purified from ovine lung and Lp82 was purified from lamb lenses using chromatography. Activity and presence of the calpains was determined by using the BODIPY-FL casein assay, gel electrophoresis, Western blot and casein zymography. Changes in the lens proteins, specifically the crystallins, were visualised using two-dimensional electrophoresis (2DE). Lenses from fetal, 6 month old and 8 year old sheep were collected, as well as stage 0, 1, 3 and 6 cataractous ovine lenses. The proteins from the lenses were separated into the water soluble and urea soluble fractions and analysed by 2DE. Mass spectrometry was used to determine the masses and therefore modifications of the crystallins. Finally, the individual crystallins were separated using gel filtration chromatography and incubated with the purified calpains in the presence of calcium. The extent of the proteolysis was visualised using 2DE and truncation sites determined by mass spectrometry. Purification of the calpains resulted in samples that were specific for each calpain and could be used in further experiments. 2DE analysis showed that there were changes to the crystallins during maturation of the lens. The α-crystallins become increasingly phosphorylated as the lens ages and a small amount becomes truncated. The β-crystallins were also modified during ageing by truncation and deamidation. When crystallins from cataractous lenses were compared using 2DE there were changes to both the α- and β-crystallins. The α-crystallins were found to be extensively truncated at their C-terminal tail. Four of the seven β-crystallins, βB1, βB3, βB2 and βA3, showed increased truncation of their N-terminal extensions during cataract formation. All three calpains truncated αA and αB-crystallin at their C-terminal ends after incubation. Calpain 2 and Lp82 each produced unique αA-crystallin truncations. All three calpains truncated βB1 and βA3 and calpain 2 also truncated βB3. When the truncations from the calpain incubations were compared to those seen during cataract formation, many of the truncations were found to be similar. Both the unique truncations from calpain 2 and Lp82 were found in cataractous lenses, with the Lp82 more obvious in the 2DE. The β-crystallin truncations found after incubation with the calpains were similar to those found during cataractogenesis. In conclusion this study documents the changes to the ovine lens during maturation and cataractogenesis and indicates a role for the calpain family in the increased proteolysis observed in the ovine cataract.
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