Matching Items (5)
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- All Subjects: Photosynthesis
- Creators: Mazor, Yuval
Description
In oxygenic photosynthesis, conversion of solar energy to chemical energy is catalyzed by the<br/>pigment-protein complexes Photosystem II (PSII) and Photosystem I (PSI) embedded within the<br/>thylakoid membrane of photoautotrophs. The function of these pigment-protein complexes are<br/>conserved between all photoautotrophs, however, the oligomeric structure, as well as the<br/>spectroscopic properties of the PSI complex, differ. In early evolving photoautotrophs, PSI<br/>exists in a trimeric organization, but in later evolving species this was lost and PSI exists solely<br/>as a monomer. While the reasons for a change in oligomerization are not fully understood, one<br/>of the 11 subunits within cyanobacterial PSI, PsaL, is thought to be involved in trimerization<br/>through the coordination of a calcium ion in an adjacent monomer. Recently published<br/>structures have demonstrated that PSI complexes are capable of trimerization without<br/>coordinating the calcium ion within PsaL.<br/>5 Here we explore the role the calcium ion plays in both<br/>the oligomeric and spectroscopic properties in PSI isolated from Synechocystis sp. PCC 6803.
ContributorsVanlandingham, Jackson R (Author) / Mazor, Yuval (Thesis director) / Mills, Jeremy (Committee member) / School of Life Sciences (Contributor) / School of Molecular Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2021-05
Description
The Heliobacterial Reaction Center (HbRC) is the simplest Type I Reaction Center (RC) known today. However, upon illumination it has been found to produce menaquinol, and this has led to experiments investigating the function of this reduction scheme. The goal of the experiment was to investigate the mechanisms of menaquinol production through the use of Photosystem II (PSII) herbicides that are known to inhibit the QB quinone site in Type II RCs. Seven herbicides were chosen, and out of all of them terbuthylazine showed the greatest effect on the RC in isolated membranes when Transient Absorption Spectroscopy was used. In addition, terbuthylazine decreased menaquinone reduction to menaquinol by ~72%, slightly more than the reported effect of teburtryn (68%)1. In addition, terbuthylazine significantly impacted growth of whole cells under high light more than terbutryn.
ContributorsOdeh, Ahmad Osameh (Author) / Redding, Kevin (Thesis director) / Woodbury, Neal (Committee member) / Allen, James (Committee member) / School of Molecular Sciences (Contributor) / Department of Psychology (Contributor) / Barrett, The Honors College (Contributor)
Created2019-05
Description
The growing global energy demand coupled with the need for a low-carbon economy requires innovative solutions. Microalgal oxygenic photosynthesis provides a sustainable platform for efficient capture of sunlight and storage of some of the energy in the form of reduced carbon derivatives. Under certain conditions, the photosynthetic reductant can be shunted to molecular hydrogen production, yet the efficiency and longevity of such processes are insufficient. In this work, re-engineering of the heterodimeric type I reaction center, also known as photosystem I (PSI), in the green microalga Chlamydomonas reinhardtii was shown to dramatically change algal metabolism and improve photobiological hydrogen production in vivo. First, an internal fusion of the small PsaC subunit of PSI harboring the terminal photosynthetic electron transport chain cofactors with the endogenous algal hydrogenase 2 (HydA2) was demonstrated to assemble on the PSI core in vivo, albeit at ~15% the level of normal PSI accumulation, and make molecular hydrogen from water oxidation. Second, the more physiologically active algal endogenous hydrogenase 1 (HydA1) was fused to PsaC in a similar fashion, resulting in improved levels of accumulation (~75%). Both algal hydrogenases chimeras remained extremely oxygen sensitive and benefited from oxygen removal methods. On the example of PSI-HydA1 chimera, it was demonstrated that the active site of hydrogenase can be reactivated in vivo after complete inactivation by oxygen without the need for new polypeptide synthesis. Third, the hydrogenase domain of Megasphaera elsdenii bacterial hydrogenase (MeHydA) was also fused with psaC, resulting in expression of a PSI-hydrogenase chimera at ~25% the normal level. The heterologous hydrogenase chimera could be activated with the algal maturation system, despite only 32 % sequence identity (43 % similarity). All constructs demonstrated diminished ability to reduce PSI electron acceptors (ferredoxin and flavodoxin) in vitro and indirect evidence indicated that this was true in vivo as well. Finally, chimeric design considerations are discussed in light of the models generated by Alphafold2 and how could they be used to further optimize stability of the PSI-hydrogenase chimeric complexes.
ContributorsKanygin, Andrey (Author) / Redding, Kevin E (Thesis advisor) / Jones, Anne K (Committee member) / Mazor, Yuval (Committee member) / Arizona State University (Publisher)
Created2022
Description
The thylakoid membranes of oxygenic photosynthetic organisms contain four large membrane complexes vital for photosynthesis: photosystem II and photosystem I (PSII and PSI, respectively), the cytochrome b6f complex and ATP synthase. Two of these complexes, PSII and PSI, utilize solar energy to carry out the primary reaction of photosynthesis, light induced charge separation. In vivo, both photosystems associate with multiple antennae to increase their light absorption cross section. The antennae, Iron Stress Induced A (IsiA), is expressed in cyanobacteria as part of general stress response and forms a ring system around PSI. IsiA is a member of a large and relatively unexplored antennae family prevalent in cyanobacteria. The structure of the PSI-IsiA super-complex from the cyanobacteria Synechocystis sp. PCC 6803 was resolved to high resolution, revealing how IsiA interacts with PSI as well as the chlorophyll organization within this antennae system. Despite these structural insights, the basis for the binding between 18 IsiA subits and PSI is not fully resolved. Several IsiA mutants were constructed using insights from the atomic structure of PSI-IsiA, revealing the role of the C-terminus of IsiA in its interaction with PSI.
ContributorsLi, Jin (Author) / Mazor, Yuval (Thesis advisor) / Chiu, Po-Lin (Committee member) / Mills, Jeremy (Committee member) / Arizona State University (Publisher)
Created2024
Description
The primary carbon fixing enzyme Rubisco maintains its activity through release of trapped inhibitors by Rubisco activase (Rca). Very little is known about the interaction, but binding has been proposed to be weak and transient. Extensive effort was made to develop Förster resonance energy transfer (FRET) based assays to understand the physical interaction between Rubisco and Rca, as well as understand subunit exchange in Rca.
Preparations of labeled Rubisco and Rca were utilized in a FRET-based binding assay. Although initial data looked promising, this approach was not fruitful, as no true FRET signal was observed. One possibility is that under the conditions tested, Rca is not able to undergo the structural reorganizations necessary to achieve binding-competent conformations. Rca may also be asymmetric, leading to less stable binding of an already weak interaction.
To better understand the structural adjustments of Rca, subunit exchange between different oligomeric species was examined. It was discovered that subunit exchange is nucleotide dependent, with ADP giving the fastest exchange, ATP giving slower exchange and ATPS inhibiting exchange. Manganese, like ADP, destabilizes subunit-subunit interactions for rapid and facile exchange between oligomers. Three different types of assemblies were deduced from the rates of subunit exchange: rigid types with extremely slow dissociation of individual protomers, tight assemblies with the physiological substrate ATP, and loose assemblies that provide fast exchange due to high ADP.
Information gained about Rca subunit exchange can be used to reexamine the physical interaction between Rubisco and Rca using the FRET-binding assay. These binding assays will provide insight into Rca states able to interact with Rubisco, as well as define conditions to generate bound states for structural analysis. In combination with assembly assays, subunit exchange assays and reactivation studies will provide critical information about the structure/function relationship of Rca in the presence of different nucleotides. Together, these FRET-based assays will help to characterize the Rca regulation mechanism and provide valuable insight into the Rubisco reactivation mechanism.
Preparations of labeled Rubisco and Rca were utilized in a FRET-based binding assay. Although initial data looked promising, this approach was not fruitful, as no true FRET signal was observed. One possibility is that under the conditions tested, Rca is not able to undergo the structural reorganizations necessary to achieve binding-competent conformations. Rca may also be asymmetric, leading to less stable binding of an already weak interaction.
To better understand the structural adjustments of Rca, subunit exchange between different oligomeric species was examined. It was discovered that subunit exchange is nucleotide dependent, with ADP giving the fastest exchange, ATP giving slower exchange and ATPS inhibiting exchange. Manganese, like ADP, destabilizes subunit-subunit interactions for rapid and facile exchange between oligomers. Three different types of assemblies were deduced from the rates of subunit exchange: rigid types with extremely slow dissociation of individual protomers, tight assemblies with the physiological substrate ATP, and loose assemblies that provide fast exchange due to high ADP.
Information gained about Rca subunit exchange can be used to reexamine the physical interaction between Rubisco and Rca using the FRET-binding assay. These binding assays will provide insight into Rca states able to interact with Rubisco, as well as define conditions to generate bound states for structural analysis. In combination with assembly assays, subunit exchange assays and reactivation studies will provide critical information about the structure/function relationship of Rca in the presence of different nucleotides. Together, these FRET-based assays will help to characterize the Rca regulation mechanism and provide valuable insight into the Rubisco reactivation mechanism.
ContributorsForbrook, Dayna S (Author) / Wachter, Rebekka M. (Thesis advisor) / Allen, James (Committee member) / Wang, Xu (Committee member) / Arizona State University (Publisher)
Created2017