Measuring the Adapted Low Temperature Resilience of Cold Shock Proteins - using Single Molecule Force Spectroscopy and Nuclear Magnetic Resonance

Cold Shock Proteins (CSPs) are produced when organisms experience cold-shock, a sudden drop to roughly 7-10 °C below the optimum temperature, and are thought to aid the melting of non-functional RNA secondary structures. For this function CSPs are required to stay exible at temperatures determined b...

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Main Author: Kendrick, Katherine Ellen
Format: Thesis
Language:English
Published: University of Leeds 2018
Subjects:
Arctic
Online Access:https://etheses.whiterose.ac.uk/24226/
https://etheses.whiterose.ac.uk/24226/1/Kendrick_KE_Physics_PhD_2018.pdf
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spelling ftwhiterose:oai:etheses.whiterose.ac.uk:24226 2023-05-15T15:15:31+02:00 Measuring the Adapted Low Temperature Resilience of Cold Shock Proteins - using Single Molecule Force Spectroscopy and Nuclear Magnetic Resonance Kendrick, Katherine Ellen 2018-07 text https://etheses.whiterose.ac.uk/24226/ https://etheses.whiterose.ac.uk/24226/1/Kendrick_KE_Physics_PhD_2018.pdf en eng University of Leeds https://etheses.whiterose.ac.uk/24226/1/Kendrick_KE_Physics_PhD_2018.pdf Kendrick, Katherine Ellen (2018) Measuring the Adapted Low Temperature Resilience of Cold Shock Proteins - using Single Molecule Force Spectroscopy and Nuclear Magnetic Resonance. PhD thesis, University of Leeds. cc_by_nc_sa CC-BY-NC-SA Thesis NonPeerReviewed 2018 ftwhiterose 2023-01-30T21:26:37Z Cold Shock Proteins (CSPs) are produced when organisms experience cold-shock, a sudden drop to roughly 7-10 °C below the optimum temperature, and are thought to aid the melting of non-functional RNA secondary structures. For this function CSPs are required to stay exible at temperatures determined by the optimum environment of the organism. While the thermodynamic properties of these proteins vary depending on the optimum temperature of the source organism, their structures are highly conserved, making this a good model system to explore non-structural adaptations to various environments. Single molecule force spectroscopy was used to measure the mechanical properties of the CSP from Bacillus Subtilis while in the functional state, i.e. bound to nucleic acids. This binding was shown to stabilise the protein, without increasing the rigidity, even when the temperature of the complex was reduced. The affinity of the CSP binding to ssDNA was measured and this was compared to the affinity to ssDNA of a CSP from an Arctic soil bacterium, Psychrobacter sp6. The CSP from the organism adapted to colder environments was found to have a lower binding affinity to ssDNA and the binding strength of ssDNA to both CSPs increased with decreasing temperature. When the binding of ssDNA was measured at the respective cold-shock temperatures of each organism the affinities were of the same order of magnitude, suggesting that the strength of this interaction is tuned to the native environment. To explore how functionality is maintained in organisms adapted to extremely cold environments, the dynamics of the CSP from Psychrobacter sp6 was measured at low, physiologically relevant temperatures using a range of NMR techniques. Results showed evidence of slow exchange with a more disordered state at low temperatures together with fast dynamics at the active site. These were not seen in measurements of the CSP from Bacillus Subtilis at low temperatures, indicating they are part of the protein adaptation to cold environments. Thesis Arctic White Rose eTheses Online (Universities Leeds, Sheffield, York) Arctic
institution Open Polar
collection White Rose eTheses Online (Universities Leeds, Sheffield, York)
op_collection_id ftwhiterose
language English
description Cold Shock Proteins (CSPs) are produced when organisms experience cold-shock, a sudden drop to roughly 7-10 °C below the optimum temperature, and are thought to aid the melting of non-functional RNA secondary structures. For this function CSPs are required to stay exible at temperatures determined by the optimum environment of the organism. While the thermodynamic properties of these proteins vary depending on the optimum temperature of the source organism, their structures are highly conserved, making this a good model system to explore non-structural adaptations to various environments. Single molecule force spectroscopy was used to measure the mechanical properties of the CSP from Bacillus Subtilis while in the functional state, i.e. bound to nucleic acids. This binding was shown to stabilise the protein, without increasing the rigidity, even when the temperature of the complex was reduced. The affinity of the CSP binding to ssDNA was measured and this was compared to the affinity to ssDNA of a CSP from an Arctic soil bacterium, Psychrobacter sp6. The CSP from the organism adapted to colder environments was found to have a lower binding affinity to ssDNA and the binding strength of ssDNA to both CSPs increased with decreasing temperature. When the binding of ssDNA was measured at the respective cold-shock temperatures of each organism the affinities were of the same order of magnitude, suggesting that the strength of this interaction is tuned to the native environment. To explore how functionality is maintained in organisms adapted to extremely cold environments, the dynamics of the CSP from Psychrobacter sp6 was measured at low, physiologically relevant temperatures using a range of NMR techniques. Results showed evidence of slow exchange with a more disordered state at low temperatures together with fast dynamics at the active site. These were not seen in measurements of the CSP from Bacillus Subtilis at low temperatures, indicating they are part of the protein adaptation to cold environments.
format Thesis
author Kendrick, Katherine Ellen
spellingShingle Kendrick, Katherine Ellen
Measuring the Adapted Low Temperature Resilience of Cold Shock Proteins - using Single Molecule Force Spectroscopy and Nuclear Magnetic Resonance
author_facet Kendrick, Katherine Ellen
author_sort Kendrick, Katherine Ellen
title Measuring the Adapted Low Temperature Resilience of Cold Shock Proteins - using Single Molecule Force Spectroscopy and Nuclear Magnetic Resonance
title_short Measuring the Adapted Low Temperature Resilience of Cold Shock Proteins - using Single Molecule Force Spectroscopy and Nuclear Magnetic Resonance
title_full Measuring the Adapted Low Temperature Resilience of Cold Shock Proteins - using Single Molecule Force Spectroscopy and Nuclear Magnetic Resonance
title_fullStr Measuring the Adapted Low Temperature Resilience of Cold Shock Proteins - using Single Molecule Force Spectroscopy and Nuclear Magnetic Resonance
title_full_unstemmed Measuring the Adapted Low Temperature Resilience of Cold Shock Proteins - using Single Molecule Force Spectroscopy and Nuclear Magnetic Resonance
title_sort measuring the adapted low temperature resilience of cold shock proteins - using single molecule force spectroscopy and nuclear magnetic resonance
publisher University of Leeds
publishDate 2018
url https://etheses.whiterose.ac.uk/24226/
https://etheses.whiterose.ac.uk/24226/1/Kendrick_KE_Physics_PhD_2018.pdf
geographic Arctic
geographic_facet Arctic
genre Arctic
genre_facet Arctic
op_relation https://etheses.whiterose.ac.uk/24226/1/Kendrick_KE_Physics_PhD_2018.pdf
Kendrick, Katherine Ellen (2018) Measuring the Adapted Low Temperature Resilience of Cold Shock Proteins - using Single Molecule Force Spectroscopy and Nuclear Magnetic Resonance. PhD thesis, University of Leeds.
op_rights cc_by_nc_sa
op_rightsnorm CC-BY-NC-SA
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