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Proteins function as molecular machines which perform a diverse set of essential jobs. To use these proteins as tools and manipulate them with directed engineering, a deeper understanding of their function and regulation is needed. In the studies presented here,

Proteins function as molecular machines which perform a diverse set of essential jobs. To use these proteins as tools and manipulate them with directed engineering, a deeper understanding of their function and regulation is needed. In the studies presented here, the chemical mechanism of a fluorescent protein and the assembly behavior of a chemo-mechanical protein were explored to better understand their operation. In the first study a photoconvertible fluorescent protein (pcFP) was examined which undergoes a photochemical transformation upon irradiation with blue light resulting in an emission wavelength change from green to red. Photo-transformable proteins have been used in high resolution, subcellular biological imaging techniques, and desires to engineer them have prompted investigations into the mechanism of catalysis in pcFPs. Here, a Kinetic Isotope Effect was measured to determine the rate-limiting step of green-to-red photoconversion in the reconstructed Least Evolved Ancestor (LEA) protein. The results provide insight on the process of photoconversion and evidence for the formation of a long-lived intermediate. The second study presented here focuses on the AAA+ protein Rubisco activase (Rca), which plays a critical role in the removal of inhibitors from the carbon-dioxide fixing enzyme Rubisco. Efforts to engineer Rubisco and Rca can be guided by a deeper understanding of their structure and interactions. The structure of higher plant Rca from spinach, and its interactions with its cognate Rubisco, were investigated through negative-stain electron microscopy (EM) and cryo-EM experiments. Multiple types of higher-order oligomers of plant Rca were imaged which have never been structurally characterized, and the AAA+ core of plant Rca was shown to bind Rubisco side-on, similar to bacterial Rca’s. Higher resolution structures of these aggregates and complexes are needed to make definitive observations on protein-protein interactions. However, the results presented here provide evidence for the formation of regulatory structures and an experimental foundation for future exploration of plant Rca through cryo-EM.


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Title
  • Understanding Fluorescent Protein Photoconversion and Assembly of Spinach Rubisco Activase
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Date Created
2020
Resource Type
  • Text
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    • Masters Thesis Biochemistry 2020

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