Matching Items (28)
Filtering by
- All Subjects: Biochemistry
- All Subjects: ATP Synthase
- Creators: Redding, Kevin
- Member of: Theses and Dissertations
- Member of: Barrett, The Honors College Thesis/Creative Project Collection
- Resource Type: Text
Description
There is a critical need for the development of clean and efficient energy sources. Hydrogen is being explored as a viable alternative to fuels in current use, many of which have limited availability and detrimental byproducts. Biological photo-production of H2 could provide a potential energy source directly manufactured from water and sunlight. As a part of the photosynthetic electron transport chain (PETC) of the green algae Chlamydomonas reinhardtii, water is split via Photosystem II (PSII) and the electrons flow through a series of electron transfer cofactors in cytochrome b6f, plastocyanin and Photosystem I (PSI). The terminal electron acceptor of PSI is ferredoxin, from which electrons may be used to reduce NADP+ for metabolic purposes. Concomitant production of a H+ gradient allows production of energy for the cell. Under certain conditions and using the endogenous hydrogenase, excess protons and electrons from ferredoxin may be converted to molecular hydrogen. In this work it is demonstrated both that certain mutations near the quinone electron transfer cofactor in PSI can speed up electron transfer through the PETC, and also that a native [FeFe]-hydrogenase can be expressed in the C. reinhardtii chloroplast. Taken together, these research findings form the foundation for the design of a PSI-hydrogenase fusion for the direct and continuous photo-production of hydrogen in vivo.
ContributorsReifschneider, Kiera (Author) / Redding, Kevin (Thesis advisor) / Fromme, Petra (Committee member) / Jones, Anne (Committee member) / Arizona State University (Publisher)
Created2013
Description
Ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) is widely accepted as the world's most abundant enzyme and represents the primary entry point for inorganic carbon into the biosphere. Rubisco's slow carboxylation rate of ribulose-1,5-bisphosphate (RuBP) and its susceptibility to inhibition has led some to term it the "bottle neck" of photosynthesis. In order to ensure that Rubisco remains uninhibited, plants require the catalytic chaperone Rubisco activase. Activase is a member of the AAA+ superfamily, ATPases associated with various cellular activities, and uses ATP hydrolysis as the driving force behind a conformational movement that returns activity to inhibited Rubisco active sites. A high resolution activase structure will be an essential tool for examining Rubisco/activase interactions as well as understanding the activase self-association phenomenon. Rubisco activase has long eluded crystallization, likely due to its infamous self-association (polydispersity). Therefore, a limited proteolysis approach was taken to identify soluble activase subdomains as potential crystallization targets. This process involves using proteolytic enzymes to cleave a protein into a few pieces and has previously proven successful in identifying crystallizable protein fragments. Limited proteolysis, utilizing two different proteolytic enzymes (alpha-chymotrypsin and trypsin), identified two tobacco activase products. The fragments that were identified appear to represent most of what is considered to be the AAA+ C-terminal all alpha-domain and some of the AAA+ N-terminal alpha beta alpha-domain. Identified fragments were cloned using the pET151/dTOPO. The project then moved towards cloning and recombinant protein expression in E. coli. NtAbeta(248-383) and NtAbeta(253-354) were successfully cloned, expressed, purified, and characterized through various biophysical techniques. A thermofluor assay of NtAbeta(248-383) revealed a melting temperature of about 30°C, indicating lower thermal stability compared with full-length activase at 43°C. Size exclusion chromatography suggested that NtAbeta(248-383) is monomeric. Circular dichroism was used to identify the secondary structure; a plurality of alpha-helices. NtAbeta(248-383) and NtAbeta(253-354) were subjected to crystallization trials.
ContributorsConrad, Alan (Author) / Wachter, Rebekka (Thesis advisor) / Moore, Thomas (Committee member) / Redding, Kevin (Committee member) / Arizona State University (Publisher)
Created2012
Description
The heliobacterial reaction center (HbRC) is widely considered the simplest and most primitive photosynthetic reaction center (RC) still in existence. Despite the simplicity of the HbRC, many aspects of the electron transfer mechanism remain unknown or under debate. Improving our understanding of the structure and function of the HbRC is important in determining its role in the evolution of photosynthetic RCs. In this work, the function and properties of the iron-sulfur cluster FX and quinones of the HbRC were investigated, as these are the characteristic terminal electron acceptors used by Type-I and Type-II RCs, respectively. In Chapter 3, I develop a system to directly detect quinone double reduction activity using reverse-phase high pressure liquid chromatography (RP-HPLC), showing that Photosystem I (PSI) can reduce PQ to PQH2. In Chapter 4, I use RP-HPLC to characterize the HbRC, showing a surprisingly small antenna size and confirming the presence of menaquinone (MQ) in the isolated HbRC. The terminal electron acceptor FX was characterized spectroscopically and electrochemically in Chapter 5. I used three new systems to reduce FX in the HbRC, using EPR to confirm a S=3/2 ground-state for the reduced cluster. The midpoint potential of FX determined through thin film voltammetry was -372 mV, showing the cluster is much less reducing than previously expected. In Chapter 7, I show light-driven reduction of menaquinone in heliobacterial membrane samples using only mild chemical reductants. Finally, I discuss the evolutionary implications of these findings in Chapter 7.
ContributorsCowgill, John (Author) / Redding, Kevin (Thesis advisor) / Jones, Anne (Committee member) / Fromme, Petra (Committee member) / Arizona State University (Publisher)
Created2012
Description
With a quantum efficiency of nearly 100%, the electron transfer process that occurs within the reaction center protein of the photosynthetic bacteria Rhodobacter (Rh.) sphaeroides is a paragon for understanding the complexities, intricacies, and overall systemization of energy conversion and storage in natural systems. To better understand the way in which photons of light are captured, converted into chemically useful forms, and stored for biological use, an investigation into the reaction center protein, specifically into its cascade of cofactors, was undertaken. The purpose of this experimentation was to advance our knowledge and understanding of how differing protein environments and variant cofactors affect the spectroscopic aspects of and electron transfer kinetics within the reaction of Rh. sphaeroides. The native quinone, ubiquinone, was extracted from its pocket within the reaction center protein and replaced by non-native quinones having different reduction/oxidation potentials. It was determined that, of the two non-native quinones tested—1,2-naphthaquinone and 9,10- anthraquinone—the substitution of the anthraquinone (lower redox potential) resulted in an increased rate of recombination from the P+QA- charge-separated state, while the substitution of the napthaquinone (higher redox potential) resulted in a decreased rate of recombination.
ContributorsSussman, Hallie Rebecca (Author) / Woodbury, Neal (Thesis director) / Redding, Kevin (Committee member) / Lin, Su (Committee member) / School of Molecular Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2015-12
Description
Photosynthesis is a critical process that fixes the carbon utilized in cellular respiration. In higher plants, the immutans gene codes for a protein that is both involved in carotenoid biosynthesis and plastoquinol oxidation (Carol et al 1999, Josse et al 2003). This plastoquinol terminal oxidase (PTOX) is of great interest in understanding electron flow in the plastoquinol pool. In order to characterize this PTOX, polyclonal antibodies were developed. Expression of Synechococcus WH8102 PTOX in E. coli provided a useful means to harvest the protein required for antibody production. Once developed, the antibody was tested for limit of concentration, effectiveness in whole cell lysate, and overall specificity. The antibody raised against PTOX was able to detect as low as 10 pg of PTOX in SDS-PAGE, and could detect PTOX extracted from lysed Synechococcus WH8102. The production of this antibody could determine the localization of the PTOX in Synechococcus.
ContributorsKhan, Mohammad Iqbal (Author) / Moore, Thomas (Thesis director) / Redding, Kevin (Committee member) / Roberson, Robert (Committee member) / Barrett, The Honors College (Contributor) / Department of Chemistry and Biochemistry (Contributor) / School of Life Sciences (Contributor)
Created2014-05
Description
The FoF1 ATP synthase is a molecular motor critical to the metabolism of virtually all life forms, and it acts in the manner of a hydroelectric generator. The F1 complex contains an (αβ)3 (hexamer) ring in which catalysis occurs, as well as a rotor comprised by subunit-ε in addition to the coiled-coil and globular foot domains of subunit-γ. The F1 complex can hydrolyze ATP in vitro in a manner that drives counterclockwise (CCW) rotation, in 120° power strokes, as viewed from the positive side of the membrane. The power strokes that occur in ≈ 300 μsec are separated by catalytic dwells that occur on a msec time scale. A single-molecule rotation assay that uses the intensity of polarized light, scattered from a 75 × 35 nm gold nanorod, determined the average rotational velocity of the power stroke (ω, in degrees/ms) as a function of the rotational position of the rotor (θ, in degrees, measured in reference to the catalytic dwell). The velocity is not constant but rather accelerates and decelerates in two Phases. Phase-1 (0° - 60°) is believed to derive power from elastic energy in the protein. At concentrations of ATP that limit the rate of ATP hydrolysis, the rotor can stop for an ATP-binding dwell during Phase-1. Although the most probable position that the ATP-binding dwell occurs is 40° after the catalytic dwell, the ATP-binding dwell can occur at any rotational position during Phase-1 of the power stroke. Phase-2 of the power stroke (60° - 120°) is believed to be powered by the ATP-binding induced closure of the lever domain of a β-subunit (as it acts as a cam shaft against the γ-subunit). Algorithms were written, to sort and analyze F1-ATPase power strokes, to determine the average rotational velocity profile of power strokes as a function of the rotational position at which the ATP-binding dwell occurs (θATP-bd), and when the ATP-binding dwell is absent. Sorting individual ω(θ) curves, as a function of θATP-bd, revealed that a dependence of ω on
θATP-bd exists. The ATP-binding dwell can occur even at saturating ATP concentrations. We report that ω follows a distinct pattern in the vicinity of the ATP-binding dwell, and that the ω(θ) curve contains the same oscillations within it regardless of θATP-bd. We observed that an acceleration/deceleration dependence before and after the ATP-binding dwell, respectively, remained for increasing time intervals as the dwell occurred later in Phase-1, to a maximum of ≈ 40°. The results were interpreted in terms of a model in which the ATP-binding dwell results from internal drag at a variable position on the γε rotor.
θATP-bd exists. The ATP-binding dwell can occur even at saturating ATP concentrations. We report that ω follows a distinct pattern in the vicinity of the ATP-binding dwell, and that the ω(θ) curve contains the same oscillations within it regardless of θATP-bd. We observed that an acceleration/deceleration dependence before and after the ATP-binding dwell, respectively, remained for increasing time intervals as the dwell occurred later in Phase-1, to a maximum of ≈ 40°. The results were interpreted in terms of a model in which the ATP-binding dwell results from internal drag at a variable position on the γε rotor.
ContributorsBukhari, Zain Aziz (Author) / Frasch, Wayne D. (Thesis director) / Allen, James P. (Committee member) / Redding, Kevin (Committee member) / School of Molecular Sciences (Contributor) / Department of Physics (Contributor) / Barrett, The Honors College (Contributor)
Created2016-12
Description
Transient Receptor Potential (TRP) ion channels are a diverse family of nonselective, polymodal sensors in uni- and multicellular eukaryotes that are implicated in an assortment of biological contexts and human disease. The cold-activated TRP Melastatin-8 (TRPM8) channel, also recognized as the human body's primary cold sensor, is among the few TRP channels responsible for thermosensing. Despite sustained interest in the channel, the mechanisms underlying TRPM8 activation, modulation, and gating have proved challenging to study and remain poorly understood. In this thesis, I offer data collected on various expression, extraction, and purification conditions tested in E. Coli expression systems with the aim to optimize the generation of a structurally stable and functional human TRPM8 pore domain (S5 and S6) construct for application in structural biology studies. These studies, including the biophysical technique nuclear magnetic spectroscopy (NMR), among others, will be essential for elucidating the role of the TRPM8 pore domain in in regulating ligand binding, channel gating, ion selectively, and thermal sensitivity. Moreover, in the second half of this thesis, I discuss the ligation-independent megaprimer PCR of whole-plasmids (MEGAWHOP PCR) cloning technique, and how it was used to generate chimeras between TRPM8 and its nearest analog TRPM2. I review steps taken to optimize the efficiency of MEGAWHOP PCR and the implications and unique applications of this novel methodology for advancing recombinant DNA technology. I lastly present preliminary electrophysiological data on the chimeras, employed to isolate and study the functional contributions of each individual transmembrane helix (S1-S6) to TRPM8 menthol activation. These studies show the utility of the TRPM8\u2014TRPM2 chimeras for dissecting function of TRP channels. The average current traces analyzed thus far indicate that the S2 and S3 helices appear to play an important role in TRPM8 menthol modulation because the TRPM8[M2S2] and TRPM8[M2S3] chimeras significantly reduce channel conductance in the presence of menthol. The TRPM8[M2S4] chimera, oppositely, increases channel conductance, implying that the S4 helix in native TRPM8 may suppress menthol modulation. Overall, these findings show that there is promise in the techniques chosen to identify specific regions of TRPM8 crucial to menthol activation, though the methods chosen to study the TRPM8 pore independent from the whole channel may need to be reevaluated. Further experiments will be necessary to refine TRPM8 pore solubilization and purification before structural studies can proceed, and the electrophysiology traces observed for the chimeras will need to be further verified and evaluated for consistency and physiological significance.
ContributorsWaris, Maryam Siddika (Author) / Van Horn, Wade (Thesis director) / Redding, Kevin (Committee member) / School of Molecular Sciences (Contributor) / Department of English (Contributor) / Barrett, The Honors College (Contributor)
Created2016-05
Description
First evolving in cyanobacteria, the light reactions of oxygenic photosynthesis are carried out by the membrane proteins, photosystem II and photosystem I, located in the thylakoid membrane. Both utilize light captured by their core antenna systems to catalyze a charge separation event at their respective reaction centers and energizes electrons to be transferred energetically uphill, eventually to be stored as a high energy chemical bond. These protein complexes are highly conserved throughout different photosynthetic lineages and understanding the variations across species is vital for a complete understanding of how photosynthetic organisms can adapt to vastly different environmental conditions. Most knowledge about photosynthesis comes from only a handful of model organisms grown under laboratory conditions. Studying model organisms has facilitated major breakthroughs in understanding photosynthesis, however, due to the vast global diversity of environments where photosynthetic organisms are found, certain aspects of this process may be overlooked or missed by focusing on a select group of organisms optimized for studying in laboratory conditions. This dissertation describes the isolation of a new extremophile cyanobacteria, Cyanobacterium aponinum 0216, from the Arizona Sonoran Desert and its innate ability to grow in light intensities that exceed other model organisms. A structure guided approach was taken to investigate how the structure of photosystem I can influence the spectroscopic properties of chlorophylls, with a particular focus on long wavelength chlorophylls, in an attempt to uncover if photosystem I is responsible for high light tolerance in Cyanobacterium aponinum 0216. To accomplish this, the structure of photosystem I was solved by cryogenic electron microscopy to 2.7-anstrom resolution. By comparing the structure and protein sequences of Cyanobacterium aponinum to other model organisms, specific variations were identified and explored by constructing chimeric PSIs in the model organism Synechocystis sp. PCC 6803 to determine the effects that each specific variation causes. The results of this dissertation describe how the protein structure and composition affect the spectroscopic properties of chlorophyll molecules and the oligomeric structure of photosystem I, possibly providing an evolutionary advantage in the high light conditions observed in the Arizona Sonoran Desert.
ContributorsDobson, Zachary (Author) / Fromme, Petra (Thesis advisor) / Mazor, Yuval (Thesis advisor) / Redding, Kevin (Committee member) / Moore, Gary (Committee member) / Arizona State University (Publisher)
Created2022
Description
The FOF1 ATP synthase is responsible for generating the majority of adenosine triphosphate (ATP) in almost all organisms on Earth. A major unresolved question is the mechanism of the FO motor that converts the transmembrane flow of protons into rotation that drives ATP synthesis. Using single-molecule gold nanorod experiments, rotation of individual FOF1 were observed to measure transient dwells (TDs). TDs occur when the FO momentarily halts the ATP hydrolysis rotation by the F1-ATPase. The work presented here showed increasing TDs with decreasing pH, with calculated pKa values of 5.6 and 7.5 for wild-type (WT) Escherichia coli (E. coli) subunit-a proton input and output half-channels, respectively. This is consistent with the conclusion that the periplasmic proton half-channel is more easily protonated than the cytoplasmic half-channel. Mutation in one proton half-channel affected the pKa values of both half-channels, suggesting that protons flow through the FO motor via the Grotthuss mechanism. The data revealed that 36° stepping of the E. coli FO subunit-c ring during ATP synthesis consists of an 11° step caused by proton translocations between subunit-a and the c-ring, and a 25° step caused by the electrostatic interaction between the unprotonated c-subunit and the aR210 residue in subunit-a. The occurrence of TDs fit to the sum of three Gaussian curves, which suggested that the asymmetry between the FO and F1 motors play a role in the mechanism behind the FOF1 rotation. Replacing the inner (N-terminal) helix of E. coli c10-ring with sequences derived from c8 to c17-ring sequences showed expression and full assembly of FOF1. Decrease in anticipated c-ring size resulted in increased ATP synthesis activity, while increase in c-ring size resulted in decreased ATP synthesis activity, loss of Δψ-dependence to synthesize ATP, decreased ATP hydrolysis activity, and decreased ACMA quenching activity. Low levels of ATP synthesis by the c12 and c15-ring chimeras are consistent with the role of the asymmetry between the FO and F1 motors that affects ATP synthesis rotation. Lack of a major trend in succinate-dependent growth rates of the chimeric E. coli suggest cellular mechanisms that compensates for the c-ring modification.
ContributorsYanagisawa, Seiga (Author) / Frasch, Wayne D (Thesis advisor) / Misra, Rajeev (Committee member) / Redding, Kevin (Committee member) / Singharoy, Abhishek (Committee member) / Wideman, Jeremy (Committee member) / Arizona State University (Publisher)
Created2023
Description
The objective of this study is to create a spectrophotometric assay that can measure quinone reduction in the HbRC. The key techniques used in the project consisted of a PCR, a pseudo golden gate, a transformation into E. coli, a conjugation into Heliomicrobium modesticaldum, a growth study, a HbRC prep, and absorbance spectroscopy. PCR was crucial for amplifying the Cyt c553-PshX gene for the pseudo golden gate. The pseudo golden gate ligated Cyt c553-PshX into the plasmid pMTL86251 in order to transform the plasmid with the desired gene into the E. coli strain S17-1. This E. coli strain allows for conjugation into H. modesticaldum. H. modesticaldum cannot uptake DNA by itself, so the E. coli creates a pilus to transfer the desired plasmid to H. modesticaldum. The growth study was crucial for determining if H. modesitcaldum could be induced using xylose without killing the cells or inhibiting the growth in such a way that the project could not be continued. The HbRC prep was used to isolate and purify the Cyt c553-PshX protein. Absorbance spectroscopy and JTS kinetic assay was used to characterize and confirm that the protein eluted from the affinity column was Cyt c553-PshX. The results of the absorbance spectra and JTS kinetic assay confirmed that Cyt c553-PshX was not made. The study is currently being continued using a new system that utilizes SpyCatcher SpyTag covalent linkages in order to attach cytochrome to reduce P800 to the HbRC.
ContributorsBarnes, Katherine (Author) / Redding, Kevin (Thesis director) / Mazor, Yuval (Committee member) / Singharoy, Abhishek (Committee member) / Barrett, The Honors College (Contributor) / School of Molecular Sciences (Contributor) / Department of English (Contributor)
Created2022-12