Your search keyword '"C. Neil Hunter"' showing total 308 results

1. FtsH4 protease controls biogenesis of the PSII complex by dual regulation of high light-inducible proteins

Author

Vendula Krynická, Petra Skotnicová, Philip J. Jackson, Samuel Barnett, Jianfeng Yu, Anna Wysocka, Radek Kaňa, Mark J. Dickman, Peter J. Nixon, C. Neil Hunter, and Josef Komenda

Subjects

thylakoid, photosystem II biogenesis, FtsH4, high light-inducible protein, proteolysis, Botany, QK1-989

Abstract

FtsH proteases are membrane-embedded proteolytic complexes important for protein quality control and regulation of various physiological processes in bacteria, mitochondria, and chloroplasts. Like most cyanobacteria, the model species Synechocystis sp. PCC 6803 contains four FtsH homologs, FtsH1–FtsH4. FtsH1–FtsH3 form two hetero-oligomeric complexes, FtsH1/3 and FtsH2/3, which play a pivotal role in acclimation to nutrient deficiency and photosystem II quality control, respectively. FtsH4 differs from the other three homologs by the formation of a homo-oligomeric complex, and together with Arabidopsis thaliana AtFtsH7/9 orthologs, it has been assigned to another phylogenetic group of unknown function. Our results exclude the possibility that Synechocystis FtsH4 structurally or functionally substitutes for the missing or non-functional FtsH2 subunit in the FtsH2/3 complex. Instead, we demonstrate that FtsH4 is involved in the biogenesis of photosystem II by dual regulation of high light-inducible proteins (Hlips). FtsH4 positively regulates expression of Hlips shortly after high light exposure but is also responsible for Hlip removal under conditions when their elevated levels are no longer needed. We provide experimental support for Hlips as proteolytic substrates of FtsH4. Fluorescent labeling of FtsH4 enabled us to assess its localization using advanced microscopic techniques. Results show that FtsH4 complexes are concentrated in well-defined membrane regions at the inner and outer periphery of the thylakoid system. Based on the identification of proteins that co-purified with the tagged FtsH4, we speculate that FtsH4 concentrates in special compartments in which the biogenesis of photosynthetic complexes takes place.

Published

2023

2. Progress and challenges in engineering cyanobacteria as chassis for light‐driven biotechnology

Author

Andrew Hitchcock, C. Neil Hunter, and Daniel P. Canniffe

Subjects

Biotechnology, TP248.13-248.65

Abstract

Summary Cyanobacteria are prokaryotic phototrophs that, in addition to being excellent model organisms for studying photosynthesis, have tremendous potential for light‐driven synthetic biology and biotechnology. These versatile and resilient microorganisms harness the energy of sunlight to oxidise water, generating chemical energy (ATP) and reductant (NADPH) that can be used to drive sustainable synthesis of high‐value natural products in genetically modified strains. In this commentary article for the Synthetic Microbiology Caucus we discuss the great progress that has been made in engineering cyanobacterial hosts as microbial cell factories for solar‐powered biosynthesis. We focus on some of the main areas where the synthetic biology and metabolic engineering tools in cyanobacteria are not as advanced as those in more widely used heterotrophic chassis, and go on to highlight key improvements that we feel are required to unlock the full power of cyanobacteria for future green biotechnology.

Published

2020

3. Revealing CO2-Fixing SAR11 Bacteria in the Ocean by Raman-Based Single-Cell Metabolic Profiling and Genomics

Author

Xiaoyan Jing, Yanhai Gong, Teng Xu, Paul A. Davison, Craig MacGregor-Chatwin, C. Neil Hunter, La Xu, Yu Meng, Yuetong Ji, Bo Ma, Jian Xu, and Wei E. Huang

Subjects

Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

The majority of marine microbes remain uncultured, which hinders the identification and mining of CO2-fixing genes, pathways, and chassis from the oceans. Here, we investigated CO2-fixing microbes in seawater from the euphotic zone of the Yellow Sea of China by detecting and tracking their 13C-bicarbonate (13C-HCO3-) intake via single-cell Raman spectra (SCRS) analysis. The target cells were then isolated by Raman-activated Gravity-driven Encapsulation (RAGE), and their genomes were amplified and sequenced at one-cell resolution. The single-cell metabolism, phenotype and genome are consistent. We identified a not-yet-cultured Pelagibacter spp., which actively assimilates 13C-HCO3-, and also possesses most of the genes encoding enzymes of the Calvin-Benson cycle for CO2 fixation, a complete gene set for a rhodopsin-based light-harvesting system, and the full genes necessary for carotenoid synthesis. The four proteorhodopsin (PR) genes identified in the Pelagibacter spp. were confirmed by heterologous expression in E. coli. These results suggest that hitherto uncultured Pelagibacter spp. uses light-powered metabolism to contribute to global carbon cycling.

Published

2022

4. Comparative proteomics of thylakoids from Arabidopsis grown in laboratory and field conditions

Author

Sarah E. Flannery, Federica Pastorelli, William H. J. Wood, C. Neil Hunter, Mark J. Dickman, Philip J. Jackson, and Matthew P. Johnson

Subjects

acclimation, electron transport, light harvesting, photosynthesis, proteomics, Botany, QK1-989

Abstract

Abstract Compared to controlled laboratory conditions, plant growth in the field is rarely optimal since it is frequently challenged by large fluctuations in light and temperature which lower the efficiency of photosynthesis and lead to photo‐oxidative stress. Plants grown under natural conditions therefore place an increased onus on the regulatory mechanisms that protect and repair the delicate photosynthetic machinery. Yet, the exact changes in thylakoid proteome composition which allow plants to acclimate to the natural environment remain largely unexplored. Here, we use quantitative label‐free proteomics to demonstrate that field‐grown Arabidopsis plants incorporate aspects of both the low and high light acclimation strategies previously observed in laboratory‐grown plants. Field plants showed increases in the relative abundance of ATP synthase, cytochrome b6f, ferredoxin‐NADP+ reductases (FNR1 and FNR2) and their membrane tethers TIC62 and TROL, thylakoid architecture proteins CURT1A, CURT1B, RIQ1, and RIQ2, the minor monomeric antenna complex CP29.3, rapidly‐relaxing non‐photochemical quenching (qE)‐related proteins PSBS and VDE, the photosystem II (PSII) repair machinery and the cyclic electron transfer complexes NDH, PGRL1B, and PGR5, in addition to decreases in the amounts of LHCII trimers composed of LHCB1.1, LHCB1.2, LHCB1.4, and LHCB2 proteins and CP29.2, all features typical of a laboratory high light acclimation response. Conversely, field plants also showed increases in the abundance of light harvesting proteins LHCB1.3 and CP29.1, zeaxanthin epoxidase (ZEP) and the slowly‐relaxing non‐photochemical quenching (qI)‐related protein LCNP, changes previously associated with a laboratory low light acclimation response. Field plants also showed distinct changes to the proteome including the appearance of stress‐related proteins ELIP1 and ELIP2 and changes to proteins that are largely invariant under laboratory conditions such as state transition related proteins STN7 and TAP38. We discuss the significance of these alterations in the thylakoid proteome considering the unique set of challenges faced by plants growing under natural conditions.

Published

2021

5. Zeta-Carotene Isomerase (Z-ISO) Is Required for Light-Independent Carotenoid Biosynthesis in the Cyanobacterium Synechocystis sp. PCC 6803

Author

Matthew S. Proctor, Felix S. Morey-Burrows, Daniel P. Canniffe, Elizabeth C. Martin, David J. K. Swainsbury, Matthew P. Johnson, C. Neil Hunter, George A. Sutherland, and Andrew Hitchcock

Subjects

carotenoid, cyanobacteria, Synechocystis, zeta-carotene isomerase (Z-ISO), photosynthesis, Biology (General), QH301-705.5

Abstract

Carotenoids are crucial photosynthetic pigments utilized for light harvesting, energy transfer, and photoprotection. Although most of the enzymes involved in carotenoid biosynthesis in chlorophototrophs are known, some are yet to be identified or fully characterized in certain organisms. A recently characterized enzyme in oxygenic phototrophs is 15-cis-zeta(ζ)-carotene isomerase (Z-ISO), which catalyzes the cis-to-trans isomerization of the central 15–15′ cis double bond in 9,15,9′-tri-cis-ζ-carotene to produce 9,9′-di-cis-ζ-carotene during the four-step conversion of phytoene to lycopene. Z-ISO is a heme B-containing enzyme best studied in angiosperms. Homologs of Z-ISO are present in organisms that use the multi-enzyme poly-cis phytoene desaturation pathway, including algae and cyanobacteria, but appear to be absent in green bacteria. Here we confirm the identity of Z-ISO in the model unicellular cyanobacterium Synechocystis sp. PCC 6803 by showing that the protein encoded by the slr1599 open reading frame has ζ-carotene isomerase activity when produced in Escherichia coli. A Synechocystis Δslr1599 mutant synthesizes a normal quota of carotenoids when grown under illumination, where the photolabile 15–15′ cis double bond of 9,15,9′-tri-cis-ζ-carotene is isomerized by light, but accumulates this intermediate and fails to produce ‘mature’ carotenoid species during light-activated heterotrophic growth, demonstrating the requirement of Z-ISO for carotenoid biosynthesis during periods of darkness. In the absence of a structure of Z-ISO, we analyze AlphaFold models of the Synechocystis, Zea mays (maize), and Arabidopsis thaliana enzymes, identifying putative protein ligands for the heme B cofactor and the substrate-binding site.

Published

2022

6. The molecular basis of phosphite and hypophosphite recognition by ABC-transporters

Author

Claudine Bisson, Nathan B. P. Adams, Ben Stevenson, Amanda A. Brindley, Despo Polyviou, Thomas S. Bibby, Patrick J. Baker, C. Neil Hunter, and Andrew Hitchcock

Subjects

Science

Abstract

Some bacteria can use inorganic phosphite and hypophosphite as sources of inorganic phosphorus. Here, the authors report crystal structures of the periplasmic proteins that bind these reduced phosphorus species and show that a P-H…π interaction between the ligand and binding site determines their specificity.

Published

2017

7. Mapping the ultrafast flow of harvested solar energy in living photosynthetic cells

Author

Peter D. Dahlberg, Po-Chieh Ting, Sara C. Massey, Marco A. Allodi, Elizabeth C. Martin, C. Neil Hunter, and Gregory S. Engel

Subjects

Science

Abstract

During photosynthesis, energy is transferred from photosynthetic antenna to reaction centers via ultrafast energy transfer. Here the authors track energy transfer in photosynthetic bacteria using two-dimensional electronic spectroscopy and show that these transfer dynamics constrain antenna complex organization.

Published

2017

8. Development of SimCells as a novel chassis for functional biosensors

Author

Cordelia P. N. Rampley, Paul A. Davison, Pu Qian, Gail M. Preston, C. Neil Hunter, Ian P. Thompson, Ling Juan Wu, and Wei E. Huang

Subjects

Medicine, Science

Abstract

Abstract This work serves as a proof-of-concept for bacterially derived SimCells (Simple Cells), which contain the cell machinery from bacteria and designed DNA (or potentially a simplified genome) to instruct the cell to carry out novel, specific tasks. SimCells represent a reprogrammable chassis without a native chromosome, which can host designed DNA to perform defined functions. In this paper, the use of Escherichia coli MC1000 ∆minD minicells as a non-reproducing chassis for SimCells was explored, as demonstrated by their ability to act as sensitive biosensors for small molecules. Highly purified minicells derived from E. coli strains containing gene circuits for biosensing were able to transduce the input signals from several small molecules (glucarate, acrylate and arabinose) into the production of green fluorescent protein (GFP). A mathematical model was developed to fit the experimental data for induction of gene expression in SimCells. The intracellular ATP level was shown to be important for SimCell function. A purification and storage protocol was developed to prepare SimCells which could retain their functions for an extended period of time. This study demonstrates that SimCells are able to perform as ‘smart bioparticles’ controlled by designed gene circuits.

Published

2017

9. Augmenting light coverage for photosynthesis through YFP-enhanced charge separation at the Rhodobacter sphaeroides reaction centre

Author

Katie J. Grayson, Kaitlyn M. Faries, Xia Huang, Pu Qian, Preston Dilbeck, Elizabeth C. Martin, Andrew Hitchcock, Cvetelin Vasilev, Jonathan M. Yuen, Dariusz M. Niedzwiedzki, Graham J. Leggett, Dewey Holten, Christine Kirmaier, and C. Neil Hunter

Subjects

Science

Abstract

Photosynthesis uses only a limited range of solar radiation. Here, Graysonet al. genetically incorporated the yellow fluorescent protein (YFP) chromophore into a bacterial photosystem, and show that energy harvested by reaction centre–YFP complexes can augment photosynthesis in vivo.

Published

2017

10. Phycobilisome’s Exciton Transfer Efficiency Relies on an Energetic Funnel Driven by Chromophore–Linker Protein Interactions

Author

Siddhartha Sohoni, Lawson T. Lloyd, Andrew Hitchcock, Craig MacGregor-Chatwin, Ainsley Iwanicki, Indranil Ghosh, Qijie Shen, C. Neil Hunter, and Gregory S. Engel

Subjects

Colloid and Surface Chemistry, General Chemistry, Biochemistry, Catalysis

Published

2023

11. Photosynthesis in the near infrared: the γ subunit of Blastochloris viridis LH1 red-shifts absorption beyond 1000 nm

Author

Andrew Hitchcock, David J.K. Swainsbury, and C. Neil Hunter

Subjects

Cell Biology, Molecular Biology, Biochemistry

Abstract

The reaction centre (RC) in purple phototrophic bacteria is encircled by the primary light-harvesting complex 1 (LH1) antenna, forming the RC–LH1 ‘core’ complex. The Qy absorption maximum of LH1 complexes ranges from ∼875–960 nm in bacteriochlorophyll (BChl) a-utilising organisms, to 1018 nm in the BChl b-containing complex from Blastochloris (Blc.) viridis. The red-shifted absorption of the Blc. viridis LH1 was predicted to be due in part to the presence of the γ subunit unique to Blastochloris spp., which binds to the exterior of the complex and is proposed to increase packing and excitonic coupling of the BChl pigments. The study by Namoon et al. provides experimental evidence for the red-shifting role of the γ subunit and an evolutionary rationale for its incorporation into LH1. The authors show that cells producing RC–LH1 lacking the γ subunit absorb maximally at 972 nm, 46 nm to the blue of the wild-type organism. Wavelengths in the 900–1000 nm region of the solar spectrum transmit poorly through water, thus γ shifts absorption of LH1 to a region where photons have lower energy but are more abundant. Complementation of the mutant with a divergent copy of LH1γ resulted in an intermediate red shift, revealing the possibility of tuning LH1 absorption using engineered variants of this subunit. These findings provide new insights into photosynthesis in the lowest energy phototrophs and how the absorption properties of light-harvesting complexes are modified by the recruitment of additional subunits.

Published

2023

12. Phasor Analysis Reveals Multicomponent Fluorescence Kinetics in the LH2 Complex from Marichromatium purpuratum

Author

Inga Elvers, Tu C. Nguyen-Phan, Alastair T. Gardiner, C. Neil Hunter, Richard J. Cogdell, and Jürgen Köhler

Subjects

Materials Chemistry, Physical and Theoretical Chemistry, Surfaces, Coatings and Films

Published

2022

13. Cryo-EM structures of the Synechocystis sp. PCC 6803 cytochrome b6f complex with and without the regulatory PetP subunit

Author

Matthew S. Proctor, Lorna A. Malone, David A. Farmer, David J.K. Swainsbury, Frederick R. Hawkings, Federica Pastorelli, Thomas Z. Emrich-Mills, C. Alistair Siebert, C. Neil Hunter, Matthew P. Johnson, and Andrew Hitchcock

Subjects

Electron Transport, Cytochrome b6f Complex, Cryoelectron Microscopy, Synechocystis, Cell Biology, Photosynthesis, Thylakoids, Molecular Biology, Biochemistry

Abstract

In oxygenic photosynthesis, the cytochrome b6f (cytb6f) complex links the linear electron transfer (LET) reactions occurring at photosystems I and II and generates a transmembrane proton gradient via the Q-cycle. In addition to this central role in LET, cytb6f also participates in a range of processes including cyclic electron transfer (CET), state transitions and photosynthetic control. Many of the regulatory roles of cytb6f are facilitated by auxiliary proteins that differ depending upon the species, yet because of their weak and transient nature the structural details of these interactions remain unknown. An apparent key player in the regulatory balance between LET and CET in cyanobacteria is PetP, a ∼10 kDa protein that is also found in red algae but not in green algae and plants. Here, we used cryogenic electron microscopy to determine the structure of the Synechocystis sp. PCC 6803 cytb6f complex in the presence and absence of PetP. Our structures show that PetP interacts with the cytoplasmic side of cytb6f, displacing the C-terminus of the PetG subunit and shielding the C-terminus of cytochrome b6, which binds the heme cn cofactor that is suggested to mediate CET. The structures also highlight key differences in the mode of plastoquinone binding between cyanobacterial and plant cytb6f complexes, which we suggest may reflect the unique combination of photosynthetic and respiratory electron transfer in cyanobacterial thylakoid membranes. The structure of cytb6f from a model cyanobacterial species amenable to genetic engineering will enhance future site-directed mutagenesis studies of structure-function relationships in this crucial ET complex.

Published

2022

14. The structure and assembly of reaction centre-light-harvesting 1 complexes in photosynthetic bacteria

Author

David J.K. Swainsbury, Pu Qian, Andrew Hitchcock, and C. Neil Hunter

Subjects

Biophysics, Cell Biology, Molecular Biology, Biochemistry

Abstract

Chlorophototrophic organisms have a charge-separating reaction centre (RC) complex that receives energy from a dedicated light-harvesting (LH) antenna. In the purple phototrophic bacteria, these two functions are embodied by the ‘core’ photosynthetic component, the RC-LH1 complex. RC-LH1 complexes sit within a membrane bilayer, with the central RC wholly or partly surrounded by a curved array of LH1 subunits that bind a series of bacteriochlorophyll (BChl) and carotenoid pigments. Decades of research have shown that the absorption of light initiates a cascade of energy, electron, and proton transfers that culminate in the formation of a quinol, which is subsequently oxidized by the cytochrome bc1 complex. However, a full understanding of all these processes, from femtosecond absorption of light to millisecond quinone diffusion, requires a level of molecular detail that was lacking until the remarkable recent upsurge in the availability of RC-LH1 structures. Here, we survey 13 recently determined RC-LH1 assemblies, and we compare the precise molecular arrangements of pigments and proteins that allow efficient light absorption and the transfer of energy, electrons and protons. We highlight shared structural features, as well as differences that span the bound pigments and cofactors, the structures of individual subunits, the overall architecture of the complexes, and the roles of additional subunits newly identified in just one or a few species. We discuss RC-LH1 structures in the context of prior biochemical and spectroscopic investigations, which together enhance our understanding of the molecular mechanisms of photosynthesis in the purple phototrophic bacteria. A particular emphasis is placed on how the remarkable and unexpected structural diversity in RC-LH1 complexes demonstrates different evolutionary solutions for maximising pigment density for optimised light harvesting, whilst balancing the requirement for efficient quinone diffusion between RC and cytochrome bc1 complexes through the encircling LH1 complex.

Published

2023

15. De novo design of energy transfer proteins housing excitonically coupled chlorophyll special pairs

Author

Nathan Ennist, Shunzhi Wang, Madison Kennedy, Mariano Curti, George Sutherland, Cvetelin Vasilev, Rachel Redler, Valentin Maffeis, Saeed Shareef, Anthony Sica, Ash Hua, Arundhati Deshmukh, Adam Moyer, Derrick Hicks, Avi Swartz, Ralph Cacho, Nathan Novy, Asim Bera, Alex Kang, Banumathi Sankaran, Matthew Johnson, Mike Reppert, Damian Ekiert, Gira Bhabha, Lance Stewart, Justin Caram, Barry Stoddard, Elisabet Romero, C. Neil Hunter, and David Baker

Abstract

Natural photosystems couple light harvesting to charge separation using a “special pair” of chlorophyll molecules that accepts excitation energy from the antenna and initiates an electron-transfer cascade. To investigate the photophysics of special pairs independent of complexities of native photosynthetic proteins, and as a first step towards synthetic photosystems for new energy conversion technologies, we designed C2-symmetric proteins that precisely position chlorophyll dimers. X-ray crystallography shows that one designed protein binds two chlorophylls in a binding orientation matching native special pairs, while a second positions them in a previously unseen geometry. Spectroscopy reveals excitonic coupling, and fluorescence lifetime imaging demonstrates energy transfer. We designed special pair proteins to assemble into 24-chlorophyll octahedral nanocages; the design model and cryo-EM structure are nearly identical. The design accuracy and energy transfer function of these special pair proteins suggest that de novo design of artificial photosynthetic systems is within reach of current computational methods.

Published

2023

16. Cryo-EM structure of the four-subunit Rhodobacter sphaeroides cytochrome bc 1 complex in styrene maleic acid nanodiscs

Author

David J. K. Swainsbury, Frederick R. Hawkings, Elizabeth C. Martin, Sabina Musiał, Jack H. Salisbury, Philip J. Jackson, David A. Farmer, Matthew P. Johnson, C. Alistair Siebert, Andrew Hitchcock, and C. Neil Hunter

Subjects

Multidisciplinary

Abstract

Cytochrome bc 1 complexes are ubiquinol:cytochrome c oxidoreductases, and as such, they are centrally important components of respiratory and photosynthetic electron transfer chains in many species of bacteria and in mitochondria. The minimal complex has three catalytic components, which are cytochrome b , cytochrome c 1 , and the Rieske iron–sulfur subunit, but the function of mitochondrial cytochrome bc 1 complexes is modified by up to eight supernumerary subunits. The cytochrome bc 1 complex from the purple phototrophic bacterium Rhodobacter sphaeroides has a single supernumerary subunit called subunit IV, which is absent from current structures of the complex. In this work we use the styrene–maleic acid copolymer to purify the R. sphaeroides cytochrome bc 1 complex in native lipid nanodiscs, which retains the labile subunit IV, annular lipids, and natively bound quinones. The catalytic activity of the four-subunit cytochrome bc 1 complex is threefold higher than that of the complex lacking subunit IV. To understand the role of subunit IV, we determined the structure of the four-subunit complex at 2.9 Å using single particle cryogenic electron microscopy. The structure shows the position of the transmembrane domain of subunit IV, which lies across the transmembrane helices of the Rieske and cytochrome c 1 subunits. We observe a quinone at the Q o quinone-binding site and show that occupancy of this site is linked to conformational changes in the Rieske head domain during catalysis. Twelve lipids were structurally resolved, making contacts with the Rieske and cytochrome b subunits, with some spanning both of the two monomers that make up the dimeric complex.

Published

2023

17. Engineering a Rhodopsin-Based Photo-Electrosynthetic System in Bacteria for CO

Author

Paul A, Davison, Weiming, Tu, Jiabao, Xu, Simona, Della Valle, Ian P, Thompson, C Neil, Hunter, and Wei E, Huang

Subjects

Rhodopsin, Autotrophic Processes, Cupriavidus necator, Carbon Dioxide, Carbon

Abstract

A key goal of synthetic biology is to engineer organisms that can use solar energy to convert CO

Published

2022

18. Cryo-EM structures of light-harvesting 2 complexes from

Author

Pu, Qian, Cam T, Nguyen-Phan, Alastair T, Gardiner, Tristan I, Croll, Aleksander W, Roszak, June, Southall, Philip J, Jackson, Cvetelin, Vasilev, Pablo, Castro-Hartmann, Kasim, Sader, C Neil, Hunter, and Richard J, Cogdell

Subjects

Rhodopseudomonas, Bacterial Proteins, Cryoelectron Microscopy, Light-Harvesting Protein Complexes, Peptides, Bacteriochlorophylls

Abstract

The genomes of some purple photosynthetic bacteria contain a multigene

Published

2022

19. Engineering purple bacterial carotenoid biosynthesis to study the roles of carotenoids in light-harvesting complexes

Author

George A, Sutherland, Pu, Qian, C Neil, Hunter, David J K, Swainsbury, and Andrew, Hitchcock

Subjects

Bacterial Proteins, Energy Transfer, Proteobacteria, Light-Harvesting Protein Complexes, Rhodobacter sphaeroides, Photosynthesis, Carotenoids

Abstract

Carotenoids are important photosynthetic pigments that play key roles in light harvesting and energy transfer, photoprotection, and in the folding, assembly, and stabilization of light-harvesting pigment-protein complexes. The genetically tractable purple phototrophic bacteria have been useful for investigating the biosynthesis and function of photosynthetic pigments and cofactors, including carotenoids. Here, we give an overview of the roles of carotenoids in photosynthesis and of their biosynthesis, focusing on the extensively studied purple bacterium Rhodobacter sphaeroides as a model organism. We provide detailed procedures for manipulating carotenoid biosynthesis, and for the preparation and analysis of the light-harvesting and photosynthetic reaction center complexes that bind them. Using appropriate examples from the literature, we discuss how such approaches have enhanced our understanding of the biosynthesis of carotenoids and the photosynthesis-related functions of these fascinating molecules.

Published

2022

20. Enhancing the spectral range of plant and bacterial Light-Harvesting pigment-protein complexes with various synthetic chromophores incorporated into lipid vesicles

Author

Ashley M. Hancock, David J. K. Swainsbury, Sophie A. Meredith, Kenichi Morigaki, C. Neil Hunter, and Peter G. Adams

Subjects

Radiation, Radiological and Ultrasound Technology, Proteobacteria, Light-Harvesting Protein Complexes, Biophysics, Radiology, Nuclear Medicine and imaging, Photosynthesis, Coloring Agents, Thylakoids

Abstract

The Light-Harvesting (LH) pigment-protein complexes found in photosynthetic organisms have the role of absorbing solar energy with high efficiency and transferring it to reaction centre complexes. LH complexes contain a suite of pigments that each absorb light at specific wavelengths, however, the natural combinations of pigments within any one protein complex do not cover the full range of solar radiation. Here, we provide an in-depth comparison of the relative effectiveness of five different organic “dye” molecules (Texas Red, ATTO, Cy7, Dil, DiR) for enhancing the absorption range of two different LH membrane protein complexes (the major LHCII from plants and LH2 from purple phototrophic bacteria). Proteoliposomes were self-assembled from defined mixtures of lipids, proteins and dye molecules and their optical properties were quantified by absorption and fluorescence spectroscopy. Both lipid-linked dyes and alternative lipophilic dyes were found to be effective excitation energy donors to LH protein complexes, without the need for direct chemical or generic modification of the proteins. The Förster theory parameters (e.g., spectral overlap) were compared between each donor-acceptor combination and found to be good predictors of an effective dye-protein combination. At the highest dye-to-protein ratios tested (over 20:1), the effective absorption strength integrated over the full spectral range was increased to ~180% of its natural level for both LH complexes. Lipophilic dyes could be inserted into pre-formed membranes although their effectiveness was found to depend upon favourable physicochemical interactions. Finally, we demonstrated that these dyes can also be effective at increasing the spectral range of surface-supported models of photosynthetic membranes, using fluorescence microscopy. The results of this work provide insight into the utility of self-assembled lipid membranes and the great flexibility of LH complexes for interacting with different dyes.

Published

2022

21. Absolute quantification of cellular levels of photosynthesis-related proteins in Synechocystis sp. PCC 6803

Author

Philip J, Jackson, Andrew, Hitchcock, Amanda A, Brindley, Mark J, Dickman, and C Neil, Hunter

Abstract

Quantifying cellular components is a basic and important step for understanding how a cell works, how it responds to environmental changes, and for re-engineering cells to produce valuable metabolites and increased biomass. We quantified proteins in the model cyanobacterium Synechocystis sp. PCC 6803 given the general importance of cyanobacteria for global photosynthesis, for synthetic biology and biotechnology research, and their ancestral relationship to the chloroplasts of plants. Four mass spectrometry methods were used to quantify cellular components involved in the biosynthesis of chlorophyll, carotenoid and bilin pigments, membrane assembly, the light reactions of photosynthesis, fixation of carbon dioxide and nitrogen, and hydrogen and sulfur metabolism. Components of biosynthetic pathways, such as those for chlorophyll or for photosystem II assembly, range between 1000 and 10,000 copies per cell, but can be tenfold higher for CO

Published

2022

22. How the O2-dependent Mg-protoporphyrin monomethyl ester cyclase forms the fifth ring of chlorophylls

Author

Mark J. Dickman, Guangyu E. Chen, Philip J. Jackson, Nathan B. P. Adams, and C. Neil Hunter

Subjects

0106 biological sciences, 0301 basic medicine, Chlorophyll, Stereochemistry, Protoporphyrins, Plant Science, Reaction intermediate, Reductase, 01 natural sciences, Purple bacteria, Cyclase, Article, Mass Spectrometry, Electron Transport, 03 medical and health sciences, chemistry.chemical_compound, Bacterial Proteins, Metalloproteins, Escherichia coli, Cloning, Molecular, Ferredoxin, Burkholderiales, biology, Chemistry, biology.organism_classification, Turnover number, Dissociation constant, 030104 developmental biology, Bacteriochlorophyll, 010606 plant biology & botany

Abstract

Mg-protoporphyrin IX monomethyl ester (MgPME) cyclase catalyses the formation of the isocyclic ring, producing protochlorophyllide a and contributing substantially to the absorption properties of chlorophylls and bacteriochlorophylls. The O2-dependent cyclase is found in both oxygenic phototrophs and some purple bacteria. We overproduced the simplest form of the cyclase, AcsF, from Rubrivivax gelatinosus, in Escherichia coli. In biochemical assays the di-iron cluster within AcsF is reduced by ferredoxin furnished by NADPH and ferredoxin:NADP+ reductase, or by direct coupling to Photosystem I photochemistry, linking cyclase to the photosynthetic electron transport chain. Kinetic analyses yielded a turnover number of 0.9 min−1, a Michaelis–Menten constant of 7.0 µM for MgPME and a dissociation constant for MgPME of 0.16 µM. Mass spectrometry identified 131-hydroxy-MgPME and 131-keto-MgPME as cyclase reaction intermediates, revealing the steps that form the isocyclic ring and completing the work originated by Sam Granick in 1950. Mg-protoporphyrin IX monomethyl ester cyclase catalyses the formation of the isocyclic ring in the synthesis of chlorophyll. Kinetic analyses and mass spectrometry identified intermediates in the reaction.

Published

2021

23. Overall energy conversion efficiency of a photosynthetic vesicle

Author

Melih Sener, Johan Strumpfer, Abhishek Singharoy, C Neil Hunter, and Klaus Schulten

Subjects

bacterial photosynthesis, excitation transfer, ATP production, energy conversion efficiency, Rhodobacter sphaeroides, Medicine, Science, Biology (General), QH301-705.5

Abstract

The chromatophore of purple bacteria is an intracellular spherical vesicle that exists in numerous copies in the cell and that efficiently converts sunlight into ATP synthesis, operating typically under low light conditions. Building on an atomic-level structural model of a low-light-adapted chromatophore vesicle from Rhodobacter sphaeroides, we investigate the cooperation between more than a hundred protein complexes in the vesicle. The steady-state ATP production rate as a function of incident light intensity is determined after identifying quinol turnover at the cytochrome [Formula: see text] complex (cyt[Formula: see text]) as rate limiting and assuming that the quinone/quinol pool of about 900 molecules acts in a quasi-stationary state. For an illumination condition equivalent to 1% of full sunlight, the vesicle exhibits an ATP production rate of 82 ATP molecules/s. The energy conversion efficiency of ATP synthesis at illuminations corresponding to 1%–5% of full sunlight is calculated to be 0.12–0.04, respectively. The vesicle stoichiometry, evolutionarily adapted to the low light intensities in the habitat of purple bacteria, is suboptimal for steady-state ATP turnover for the benefit of protection against over-illumination.

Published

2016

24. Protochlorophyllide synthesis by recombinant cyclases from eukaryotic oxygenic phototrophs and the dependence on Ycf54

Author

Guangyu E. Chen and C. Neil Hunter

Subjects

0106 biological sciences, Cyanobacteria, Protein subunit, Arabidopsis, Chlamydomonas reinhardtii, Plant Biology, Sequence Homology, Bioenergetics, 01 natural sciences, Biochemistry, Cyclase, 03 medical and health sciences, Chloroplast Proteins, Protochlorophyllide, Escherichia coli, Arabidopsis thaliana, chlorophyll, Amino Acid Sequence, Photosynthesis, Molecular Biology, Research Articles, Burkholderiales, 030304 developmental biology, 0303 health sciences, biology, Phototroph, Chemistry, Arabidopsis Proteins, fungi, food and beverages, Cell Biology, biology.organism_classification, Anoxygenic photosynthesis, Recombinant Proteins, cyclase, Oxygen, tetrapyrroles, Enzymology, Oxygenases, 010606 plant biology & botany

Abstract

The unique isocyclic E ring of chlorophylls contributes to their role as light-absorbing pigments in photosynthesis. The formation of the E ring is catalyzed by the Mg-protoporphyrin IX monomethyl ester cyclase, and the O2-dependent cyclase in prokaryotes consists of a diiron protein AcsF, augmented in cyanobacteria by an auxiliary subunit Ycf54. Here, we establish the composition of plant and algal cyclases, by demonstrating the in vivo heterologous activity of O2-dependent cyclases from the green alga Chlamydomonas reinhardtii and the model plant Arabidopsis thaliana in the anoxygenic photosynthetic bacterium Rubrivivax gelatinosus and in the non-photosynthetic bacterium Escherichia coli. In each case, an AcsF homolog is the core catalytic subunit, but there is an absolute requirement for an algal/plant counterpart of Ycf54, so the necessity for an auxiliary subunit is ubiquitous among oxygenic phototrophs. A C-terminal ∼40 aa extension, which is present specifically in green algal and plant Ycf54 proteins, may play an important role in the normal function of the protein as a cyclase subunit.

Published

2020

25. Biosynthesis of the modified tetrapyrroles—the pigments of life

Author

C. Neil Hunter, Martin J. Warren, and Donald A. Bryant

Subjects

0301 basic medicine, bilin, precorrin, Biochemistry, Cofactor, 03 medical and health sciences, chemistry.chemical_compound, Biosynthesis, Siroheme, adenosylcobalamin (AdoCbl), chlorophyll, heme, cobalamin, Molecular Biology, Heme, coenzyme F430, photosynthesis, 030102 biochemistry & molecular biology, biology, JBC Reviews, bacteriochlorophyll, uroporphyrinogen III, Pigments, Biological, vitamin B12, Cell Biology, heme d1, Small molecule, Tetrapyrrole, Combinatorial chemistry, 030104 developmental biology, Tetrapyrroles, chemistry, 5-aminolevulinic acid, biology.protein, tetrapyrrole, Bacteriochlorophyll, biosynthesis, Biogenesis

Abstract

Modified tetrapyrroles are large macrocyclic compounds, consisting of diverse conjugation and metal chelation systems and imparting an array of colors to the biological structures that contain them. Tetrapyrroles represent some of the most complex small molecules synthesized by cells and are involved in many essential processes that are fundamental to life on Earth, including photosynthesis, respiration, and catalysis. These molecules are all derived from a common template through a series of enzyme-mediated transformations that alter the oxidation state of the macrocycle and also modify its size, its side-chain composition, and the nature of the centrally chelated metal ion. The different modified tetrapyrroles include chlorophylls, hemes, siroheme, corrins (including vitamin B12), coenzyme F430, heme d1, and bilins. After nearly a century of study, almost all of the more than 90 different enzymes that synthesize this family of compounds are now known, and expression of reconstructed operons in heterologous hosts has confirmed that most pathways are complete. Aside from the highly diverse nature of the chemical reactions catalyzed, an interesting aspect of comparative biochemistry is to see how different enzymes and even entire pathways have evolved to perform alternative chemical reactions to produce the same end products in the presence and absence of oxygen. Although there is still much to learn, our current understanding of tetrapyrrole biogenesis represents a remarkable biochemical milestone that is summarized in this review.

Published

2020

26. Chromosome-free bacterial cells are safe and programmable platforms for synthetic biology

Author

Manuela Gesell Salazar, Christoph M. Decker, Aidong Yang, Hua Ye, Ian P. Thompson, Hong Zeng, Catherine Fan, C. Neil Hunter, Wei E. Huang, Frank Schmidt, Helen E. Townley, Khemmathin Lueangwattanapong, Paul A. Davison, Zhanfeng Cui, and Robert Habgood

Subjects

Cell, Catechols, Heterologous, Antineoplastic Agents, medicine.disease_cause, Microbiology, 03 medical and health sciences, Synthetic biology, Drug Delivery Systems, Neoplasms, Escherichia coli, Tumor Cells, Cultured, medicine, cancer, Gene Regulatory Networks, Gene, Cell Proliferation, 030304 developmental biology, bacterial therapy, 0303 health sciences, Multidisciplinary, SimCells, Artificial cell, biology, Pseudomonas putida, 030306 microbiology, Chemistry, Chromosomes, Bacterial, Biological Sciences, Cellular Reprogramming, biology.organism_classification, Cell biology, medicine.anatomical_structure, Cancer cell, Cupriavidus necator, Synthetic Biology, Genetic Engineering, minimal genome

Abstract

Significance We constructed simple cells (SimCells) whose native chromosomes were removed and replaced by synthetic genetic circuits. The chromosome-free SimCells can process designed DNA and express target genes for an extended period of time. The strategy of SimCell generation is applicable to most bacteria, creating a universal platform for reprogramming bacteria. We demonstrated that SimCells can be designed as safe agents for bacterial therapy through synthesis and delivery of a potent anticancer drug against a variety of cancer cell lines. This showed that the nonreplicating and programmable property of SimCells is advantageous for applications in sensitive environments. The results of this work will both improve our understanding of natural living systems and simultaneously lay the foundations for future advances in synthetic biology., A type of chromosome-free cell called SimCells (simple cells) has been generated from Escherichia coli, Pseudomonas putida, and Ralstonia eutropha. The removal of the native chromosomes of these bacteria was achieved by double-stranded breaks made by heterologous I-CeuI endonuclease and the degradation activity of endogenous nucleases. We have shown that the cellular machinery remained functional in these chromosome-free SimCells and was able to process various genetic circuits. This includes the glycolysis pathway (composed of 10 genes) and inducible genetic circuits. It was found that the glycolysis pathway significantly extended longevity of SimCells due to its ability to regenerate ATP and NADH/NADPH. The SimCells were able to continuously express synthetic genetic circuits for 10 d after chromosome removal. As a proof of principle, we demonstrated that SimCells can be used as a safe agent (as they cannot replicate) for bacterial therapy. SimCells were used to synthesize catechol (a potent anticancer drug) from salicylic acid to inhibit lung, brain, and soft-tissue cancer cells. SimCells represent a simplified synthetic biology chassis that can be programmed to manufacture and deliver products safely without interference from the host genome.

Published

2020

27. 2.4-Å structure of the double-ring Gemmatimonas phototrophica photosystem

Author

Pu Qian, Alastair T. Gardiner, Ivana Šímová, Katerina Naydenova, Tristan I. Croll, Philip J. Jackson, null Nupur, Miroslav Kloz, Petra Čubáková, Marek Kuzma, Yonghui Zeng, Pablo Castro-Hartmann, Bart van Knippenberg, Kenneth N. Goldie, David Kaftan, Pavel Hrouzek, Jan Hájek, Jon Agirre, C. Alistair Siebert, David Bína, Kasim Sader, Henning Stahlberg, Roman Sobotka, Christopher J. Russo, Tomáš Polívka, C. Neil Hunter, Michal Koblížek, Qian, Pu [0000-0002-5888-8546], Gardiner, Alastair T [0000-0001-6161-2914], Šímová, Ivana [0000-0002-6559-5143], Naydenova, Katerina [0000-0001-5533-5930], Croll, Tristan I [0000-0002-3514-8377], Jackson, Philip J [0000-0001-9671-2472], Nupur [0000-0002-4053-2904], Čubáková, Petra [0000-0003-4118-4662], Castro-Hartmann, Pablo [0000-0002-8991-9560], van Knippenberg, Bart [0000-0002-6859-332X], Goldie, Kenneth N [0000-0002-7405-0049], Kaftan, David [0000-0003-0932-0986], Hrouzek, Pavel [0000-0002-2061-0266], Agirre, Jon [0000-0002-1086-0253], Siebert, C Alistair [0000-0002-8126-1979], Bína, David [0000-0002-9259-4218], Sader, Kasim [0000-0002-8517-5410], Stahlberg, Henning [0000-0002-1185-4592], Sobotka, Roman [0000-0001-5909-3879], Russo, Christopher J [0000-0002-4442-744X], Polívka, Tomáš [0000-0002-6176-0420], Hunter, C Neil [0000-0003-2533-9783], Koblížek, Michal [0000-0001-6938-2340], and Apollo - University of Cambridge Repository

Subjects

Multidisciplinary, 34 Chemical Sciences, 3406 Physical Chemistry, 7 Affordable and Clean Energy

Abstract

Phototrophic Gemmatimonadetes evolved the ability to use solar energy following horizontal transfer of photosynthesis-related genes from an ancient phototrophic proteobacterium. The electron cryo-microscopy structure of the Gemmatimonas phototrophica photosystem at 2.4 Å reveals a unique, double-ring complex. Two unique membrane-extrinsic polypeptides, RC-S and RC-U, hold the central type 2 reaction center (RC) within an inner 16-subunit light-harvesting 1 (LH1) ring, which is encircled by an outer 24-subunit antenna ring (LHh) that adds light-gathering capacity. Femtosecond kinetics reveal the flow of energy within the RC-dLH complex, from the outer LHh ring to LH1 and then to the RC. This structural and functional study shows that G. phototrophica has independently evolved its own compact, robust, and highly effective architecture for harvesting and trapping solar energy.

Published

2022

28. Engineering purple bacterial carotenoid biosynthesis to study the roles of carotenoids in light-harvesting complexes

Author

George A. Sutherland, Pu Qian, C. Neil Hunter, David J.K. Swainsbury, and Andrew Hitchcock

Published

2022

29. Cryo-EM Structure of the Rhodobacter sphaeroides Light-Harvesting 2 Complex at 2.1 Å

Author

Giorgio Divitini, Pablo Castro-Hartmann, Kasim Sader, David J. K. Swainsbury, Pu Qian, Tristan I. Croll, C. Neil Hunter, Croll, Tristan [0000-0002-3514-8377], Divitini, Giorgio [0000-0003-2775-610X], and Apollo - University of Cambridge Repository

Subjects

Photosynthetic reaction centre, Cryo-electron microscopy, Light-Harvesting Protein Complexes, Rhodobacter sphaeroides, 010402 general chemistry, Ring (chemistry), 01 natural sciences, Biochemistry, 03 medical and health sciences, Bacterial Proteins, Molecule, 030304 developmental biology, 0303 health sciences, Strain (chemistry), biology, Chemistry, Hydrogen bond, Cryoelectron Microscopy, Periplasmic space, Bacteriochlorophyll A, biology.organism_classification, Carotenoids, 0104 chemical sciences, Crystallography, Energy Transfer

Abstract

Light-harvesting 2 (LH2) antenna complexes augment the collection of solar energy in many phototrophic bacteria. Despite its frequent role as a model for such complexes, there has been no three-dimensional (3D) structure available for the LH2 from the purple phototroph Rhodobacter sphaeroides. We used cryo-electron microscopy (cryo-EM) to determine the 2.1 Å resolution structure of this LH2 antenna, which is a cylindrical assembly of nine αβ heterodimer subunits, each of which binds three bacteriochlorophyll a (BChl) molecules and one carotenoid. The high resolution of this structure reveals all of the interpigment and pigment-protein interactions that promote the assembly and energy-transfer properties of this complex. Near the cytoplasmic face of the complex there is a ring of nine BChls, which absorb maximally at 800 nm and are designated as B800; each B800 is coordinated by the N-terminal carboxymethionine of LH2-α, part of a network of interactions with nearby residues on both LH2-α and LH2-β and with the carotenoid. Nine carotenoids, which are spheroidene in the strain we analyzed, snake through the complex, traversing the membrane and interacting with a ring of 18 BChls situated toward the periplasmic side of the complex. Hydrogen bonds with C-terminal aromatic residues modify the absorption of these pigments, which are red-shifted to 850 nm. Overlaps between the macrocycles of the B850 BChls ensure rapid transfer of excitation energy around this ring of pigments, which act as the donors of energy to neighboring LH2 and reaction center light-harvesting 1 (RC-LH1) complexes.

Published

2021

30. Cryo-EM structure of the monomeric Rhodobacter sphaeroides RC-LH1 core complex at 2.5Å

Author

David J. K. Swainsbury, Philip J. Jackson, Jack H. Salisbury, Elizabeth C. Martin, Tristan I. Croll, C. Neil Hunter, Pu Qian, Kasim Sader, Andrew Hitchcock, Pablo Castro-Hartmann, Qian, Pu [0000-0002-5888-8546], Swainsbury, David JK [0000-0002-0754-0363], Croll, Tristan I [0000-0002-3514-8377], Salisbury, Jack H [0000-0002-9527-0593], Martin, Elizabeth C [0000-0001-9600-7298], Jackson, Philip J [0000-0001-9671-2472], Hitchcock, Andrew [0000-0001-6572-434X], Castro-Hartmann, Pablo [0000-0002-8991-9560], Sader, Kasim [0000-0002-8517-5410], Hunter, C Neil [0000-0003-2533-9783], and Apollo - University of Cambridge Repository

Subjects

quinone, Models, Molecular, Protein Conformation, alpha-Helical, Light, Cryo-electron microscopy, Stereochemistry, Protein subunit, Photosynthetic Reaction Center Complex Proteins, Light-Harvesting Protein Complexes, Gene Expression, Rhodobacter sphaeroides, Bioenergetics, Ring (chemistry), Biochemistry, chemistry.chemical_compound, Bacterial Proteins, Structural Biology, light harvesting, Protein Interaction Domains and Motifs, Photosynthesis, Molecular Biology, Bacteriochlorophylls, Research Articles, Binding Sites, biology, Chemistry, bacteriochlorophyll, Cryoelectron Microscopy, Cell Biology, biology.organism_classification, Carotenoids, Transmembrane protein, carotenoid, Quinone, reaction centre, Hydroquinones, Protein Subunits, Coenzyme Q – cytochrome c reductase, Protein Conformation, beta-Strand, Bacteriochlorophyll, Protein Multimerization, Peptides, Protein Binding

Abstract

Reaction centre light-harvesting 1 (RC–LH1) complexes are the essential components of bacterial photosynthesis. The membrane-intrinsic LH1 complex absorbs light and the energy migrates to an enclosed RC where a succession of electron and proton transfers conserves the energy as a quinol, which is exported to the cytochrome bc1 complex. In some RC–LH1 variants quinols can diffuse through small pores in a fully circular, 16-subunit LH1 ring, while in others missing LH1 subunits create a gap for quinol export. We used cryogenic electron microscopy to obtain a 2.5 Å resolution structure of one such RC–LH1, a monomeric complex from Rhodobacter sphaeroides. The structure shows that the RC is partly enclosed by a 14-subunit LH1 ring in which each αβ heterodimer binds two bacteriochlorophylls and, unusually for currently reported complexes, two carotenoids rather than one. Although the extra carotenoids confer an advantage in terms of photoprotection and light harvesting, they could impede passage of quinones through small, transient pores in the LH1 ring, necessitating a mechanism to create a dedicated quinone channel. The structure shows that two transmembrane proteins play a part in stabilising an open ring structure; one of these components, the PufX polypeptide, is augmented by a hitherto undescribed protein subunit we designate as protein-Y, which lies against the transmembrane regions of the thirteenth and fourteenth LH1α polypeptides. Protein-Y prevents LH1 subunits 11–14 adjacent to the RC QB site from bending inwards towards the RC and, with PufX preventing complete encirclement of the RC, this pair of polypeptides ensures unhindered quinone diffusion.

Published

2021

31. Cryo-EM structure of the Rhodospirillum rubrum RC-LH1 complex at 2.5 Å

Author

Pablo Castro-Hartmann, David J. K. Swainsbury, Kasim Sader, Pu Qian, Nigel W. Moriarty, Tristan I. Croll, C. Neil Hunter, Hunter, C Neil [0000-0003-2533-9783], and Apollo - University of Cambridge Repository

Subjects

quinone, Protein Conformation, alpha-Helical, Cryo-electron microscopy, Light-Harvesting Protein Complexes, cryo-electron microscopy, macromolecular substances, Bioenergetics, Ligands, Rhodospirillum rubrum, Biochemistry, chemistry.chemical_compound, Electron Transport Complex III, Bacterial Proteins, Structural Biology, Benzoquinones, Molecular Biology, Bacteriochlorophylls, Research Articles, Phospholipids, photosynthesis, Binding Sites, biology, Resolution (electron density), Cryoelectron Microscopy, carotenoids, Hydrogen Bonding, Cell Biology, Ligand (biochemistry), biology.organism_classification, light-harvesting, Quinone, reaction centre, Hydroquinones, Crystallography, Monomer, chemistry, Coenzyme Q – cytochrome c reductase, Bacteriochlorophyll, Crystallization

Abstract

The reaction centre light-harvesting 1 (RC–LH1) complex is the core functional component of bacterial photosynthesis. We determined the cryo-electron microscopy (cryo-EM) structure of the RC–LH1 complex from Rhodospirillum rubrum at 2.5 Å resolution, which reveals a unique monomeric bacteriochlorophyll with a phospholipid ligand in the gap between the RC and LH1 complexes. The LH1 complex comprises a circular array of 16 αβ-polypeptide subunits that completely surrounds the RC, with a preferential binding site for a quinone, designated QP, on the inner face of the encircling LH1 complex. Quinols, initially generated at the RC QB site, are proposed to transiently occupy the QP site prior to traversing the LH1 barrier and diffusing to the cytochrome bc1 complex. Thus, the QP site, which is analogous to other such sites in recent cryo-EM structures of RC–LH1 complexes, likely reflects a general mechanism for exporting quinols from the RC–LH1 complex.

Published

2021

32. FRET measurement of cytochrome bc

Author

Cvetelin, Vasilev, David J K, Swainsbury, Michael L, Cartron, Elizabeth C, Martin, Sandip, Kumar, Jamie K, Hobbs, Matthew P, Johnson, Andrew, Hitchcock, and C Neil, Hunter

Subjects

Rhodobacter sphaeroides

Abstract

In the model purple phototrophic bacterium Rhodobacter (Rba.) sphaeroides, solar energy is converted via coupled electron and proton transfer reactions within the intracytoplasmic membranes (ICMs), infoldings of the cytoplasmic membrane that form spherical 'chromatophore' vesicles. These bacterial 'organelles' are ideal model systems for studying how the organisation of the photosynthetic complexes therein shape membrane architecture. In Rba. sphaeroides, light-harvesting 2 (LH2) complexes transfer absorbed excitation energy to dimeric reaction centre (RC)-LH1-PufX complexes. The PufX polypeptide creates a channel that allows the lipid soluble electron carrier quinol, produced by RC photochemistry, to diffuse to the cytochrome bc

Published

2021

33. Depletion of the FtsH1/3 Proteolytic Complex Suppresses the Nutrient Stress Response in the Cyanobacterium Synechocystis sp strain PCC 6803

Author

Matthias E. Futschik, Mark J. Dickman, Vendula Krynická, Jens Georg, Philip J. Jackson, C. Neil Hunter, Wolfgang R. Hess, and Josef Komenda

Subjects

0106 biological sciences, 0301 basic medicine, Proteases, Mutant, Phosphate, Plant Science, Signal transduction, Biology, 01 natural sciences, 03 medical and health sciences, Accumulation, Gene expression, Escherichia coli, Transcription factor, 2. Zero hunger, Regulation of gene expression, Nitrogen starvation, Protein, Regulator, Synechocystis, Cell Biology, biology.organism_classification, Photosystem Ii, Cell biology, Chloroplast, 030104 developmental biology, Regulon, Acclimation, 010606 plant biology & botany

Abstract

The membrane-embedded FtsH proteases found in bacteria, chloroplasts, and mitochondria are involved in diverse cellular processes including protein quality control and regulation. The genome of the model cyanobacterium Synechocystis sp PCC 6803 encodes four FtsH homologs designated FtsH1 to FtsH4. The FtsH3 homolog is present in two hetero-oligomeric complexes: FtsH2/3, which is responsible for photosystem II quality control, and the essential FtsH1/3 complex, which helps maintain Fe homeostasis by regulating the level of the transcription factor Fur. To gain a more comprehensive insight into the physiological roles of FtsH hetero-complexes, we performed genome-wide expression profiling and global proteomic analyses of Synechocystis mutants conditionally depleted of FtsH3 or FtsH1 grown under various nutrient conditions. We show that the lack of FtsH1/3 leads to a drastic reduction in the transcriptional response to nutrient stress of not only Fur but also the Pho, NdhR, and NtcA regulons. In addition, this effect is accompanied by the accumulation of the respective transcription factors. Thus, the FtsH1/3 complex is of critical importance for acclimation to iron, phosphate, carbon, and nitrogen starvation in Synechocystis. Germany Federal Ministry of Education and Research [031L0106B] Grant Agency of the Czech RepublicGrant Agency of the Czech Republic [P501-12-G055] Czech Ministry of Education Ministry of Education, Youth & Sports - Czech Republic [LO1416] Portuguese Fundacao para a Ciencia e a Tecnologia (Foundation for Science and Technology) [PTDC/BIA-MIC/4418/2012, IF/00881/2013, UID/Multi/04326/2013] United Kingdom Biotechnology and Biological Sciences Research Council (BBSRC)Biotechnology and Biological Sciences Research Council (BBSRC) [BB/M012166/1, BB/M000265/1] European Research CouncilEuropean Research Council (ERC) [338895]

Published

2019

34. Dissecting the cytochrome c2–reaction centre interaction in bacterial photosynthesis using single molecule force spectroscopy

Author

Guy E Mayneord, Cvetelin Vasilev, C. Neil Hunter, Amanda A. Brindley, and Matthew P. Johnson

Subjects

0303 health sciences, Cytochrome, biology, Dimer, Force spectroscopy, Cell Biology, 010402 general chemistry, 01 natural sciences, Biochemistry, Redox, 0104 chemical sciences, Dissociation constant, 03 medical and health sciences, chemistry.chemical_compound, Electron transfer, chemistry, Membrane protein complex, Biophysics, biology.protein, Bacteriochlorophyll, Molecular Biology, 030304 developmental biology

Abstract

The reversible docking of small, diffusible redox proteins onto a membrane protein complex is a common feature of bacterial, mitochondrial and photosynthetic electron transfer (ET) chains. Spectroscopic studies of ensembles of such redox partners have been used to determine ET rates and dissociation constants. Here, we report a single-molecule analysis of the forces that stabilise transient ET complexes. We examined the interaction of two components of bacterial photosynthesis, cytochrome c2 and the reaction centre (RC) complex, using dynamic force spectroscopy and PeakForce quantitative nanomechanical imaging. RC–LH1–PufX complexes, attached to silicon nitride AFM probes and maintained in a photo-oxidised state, were lowered onto a silicon oxide substrate bearing dispersed, immobilised and reduced cytochrome c2 molecules. Microscale patterns of cytochrome c2 and the cyan fluorescent protein were used to validate the specificity of recognition between tip-attached RCs and surface-tethered cytochrome c2. Following the transient association of photo-oxidised RC and reduced cytochrome c2 molecules, retraction of the RC-functionalised probe met with resistance, and forces between 112 and 887 pN were required to disrupt the post-ET RC–c2 complex, depending on the retraction velocities used. If tip-attached RCs were reduced instead, the probability of interaction with reduced cytochrome c2 molecules decreased 5-fold. Thus, the redox states of the cytochrome c2 haem cofactor and RC ‘special pair’ bacteriochlorophyll dimer are important for establishing a productive ET complex. The millisecond persistence of the post-ET cytochrome c2[oxidised]–RC[reduced] ‘product’ state is compatible with rates of cyclic photosynthetic ET, at physiologically relevant light intensities.

Published

2019

35. The ChlD subunit links the motor and porphyrin binding subunits of magnesium chelatase

Author

Nathan B. P. Adams, Andrew Hitchcock, Bethany Johnson, Amanda A. Brindley, Mark J. Dickman, Philip J. Jackson, David A. Farmer, James D. Reid, and C. Neil Hunter

Subjects

AAA proteins, Enzyme complex, Protein subunit, Lyases, protein–protein interactions, Biochemistry, 03 medical and health sciences, Bacterial Proteins, Protein Domains, ATP hydrolysis, Magnesium, Molecular Biology, Research Articles, 030304 developmental biology, 0303 health sciences, biology, Microscale thermophoresis, Chemistry, 030302 biochemistry & molecular biology, Synechocystis, Active site, Cell Biology, biology.organism_classification, Recombinant Proteins, tetrapyrroles, Magnesium chelatase, integrins, biology.protein, Biophysics, Research Article

Abstract

Magnesium chelatase initiates chlorophyll biosynthesis, catalysing the MgATP2−-dependent insertion of a Mg2+ ion into protoporphyrin IX. The catalytic core of this large enzyme complex consists of three subunits: Bch/ChlI, Bch/ChlD and Bch/ChlH (in bacteriochlorophyll and chlorophyll producing species, respectively). The D and I subunits are members of the AAA+ (ATPases associated with various cellular activities) superfamily of enzymes, and they form a complex that binds to H, the site of metal ion insertion. In order to investigate the physical coupling between ChlID and ChlH in vivo and in vitro, ChlD was FLAG-tagged in the cyanobacterium Synechocystis sp. PCC 6803 and co-immunoprecipitation experiments showed interactions with both ChlI and ChlH. Co-production of recombinant ChlD and ChlH in Escherichia coli yielded a ChlDH complex. Quantitative analysis using microscale thermophoresis showed magnesium-dependent binding (Kd 331 ± 58 nM) between ChlD and H. The physical basis for a ChlD–H interaction was investigated using chemical cross-linking coupled with mass spectrometry (XL–MS), together with modifications that either truncate ChlD or modify single residues. We found that the C-terminal integrin I domain of ChlD governs association with ChlH, the Mg2+ dependence of which also mediates the cooperative response of the Synechocystis chelatase to magnesium. The interaction site between the AAA+ motor and the chelatase domain of magnesium chelatase will be essential for understanding how free energy from the hydrolysis of ATP on the AAA+ ChlI subunit is transmitted via the bridging subunit ChlD to the active site on ChlH.

Published

2019

36. Single-molecule study of redox control involved in establishing the spinach plastocyanin-cytochrome bf electron transfer complex

Author

Matthew P. Johnson, Lorna A. Malone, Guy E Mayneord, C. Neil Hunter, David J. K. Swainsbury, and Cvetelin Vasilev

Subjects

Electron transfer, Membrane, Docking (molecular), Chemistry, Cytochrome b6f complex, Biophysics, Molecule, Cell Biology, Photosystem I, Biochemistry, Redox, Plastocyanin

Abstract

Small diffusible redox proteins play a ubiquitous role in bioenergetic systems, facilitating electron transfer (ET) between membrane bound complexes. Sustaining high ET turnover rates requires that the association between extrinsic and membrane-bound partners is highly specific, yet also sufficiently weak to promote rapid post-ET separation. In oxygenic photosynthesis the small soluble electron carrier protein plastocyanin (Pc) shuttles electrons between the membrane integral cytochrome b6f (cytb6f) and photosystem I (PSI) complexes. Here we use peak-force quantitative nanomechanical mapping (PF-QNM) atomic force microscopy (AFM) to quantify the dynamic forces involved in transient interactions between cognate ET partners. An AFM probe functionalised with Pc molecules is brought into contact with cytb6f complexes, immobilised on a planar silicon surface. PF-QNM interrogates the unbinding force of the cytb6f-Pc interactions at the single molecule level with picoNewton force resolution and on a time scale comparable to the ET time in vivo (ca. 120 μs). Using this approach, we show that although the unbinding force remains unchanged the interaction frequency increases over five-fold when Pc and cytb6f are in opposite redox states, so complementary charges on the cytb6f and Pc cofactors likely contribute to the electrostatic forces that initiate formation of the ET complex. These results suggest that formation of the docking interface is under redox state control, which lowers the probability of unproductive encounters between Pc and cytb6f molecules in the same redox state, ensuring the efficiency and directionality of this central reaction in the ‘Z-scheme’ of photosynthetic ET.

Published

2019

37. Dynamic Thylakoid Stacking Is Regulated by LHCII Phosphorylation but Not Its interaction with PSI

Author

Samuel F. H. Barnett, William H.J. Wood, Matthew P. Johnson, C. Neil Hunter, and Sarah E. Flannery

Subjects

0106 biological sciences, Spinacia, biology, Physiology, Chemistry, Phosphatase, Stacking, food and beverages, macromolecular substances, Plant Science, Photosynthesis, biology.organism_classification, 01 natural sciences, Chloroplast thylakoid, Chloroplast, Electron transfer, Thylakoid, Genetics, Biophysics, Research Article, 010606 plant biology & botany

Abstract

Grana stacking in plant chloroplast thylakoid membranes dynamically responds to the light environment. These dynamics have been linked to regulation of the relative antenna sizes of PSI and PSII (state transitions), the PSII repair cycle, and the regulation of photosynthetic electron transfer. Here, we used 3D structured illumination microscopy, a subdiffraction-resolution fluorescence imaging technique, to investigate the light-intensity dependence, kinetics, reversibility, and regulation of dynamic thylakoid stacking in spinach (Spinacia oleracea) and Arabidopsis (Arabidopsis thaliana). Low-intensity white light (150 μmol photons m(−2) s(−1)) behaved similarly to light preferentially exciting PSII (660 nm), causing a reduction in grana diameter and an increased number of grana per chloroplast. By contrast, high-intensity white light (1000 μmol photons m(−2) s(−1)), darkness, and light preferentially exciting PSI (730 nm) reversed these changes. These dynamics occurred with a half-time of 7 to 8 min and were accompanied by state transitions. Consistent with this, the dynamics were dependent on STN7 (light-harvesting complex II [LHCII] kinase) and TAP38 (LHCII phosphatase), which are required for state transitions but were unaffected by the absence of STN8 (PSII kinase) or PSII core phosphatase (PSII phosphatase). Unlike state transitions, however, thylakoid stacking dynamics did not rely on the presence of the LHCI and PSI subunit L phospho-LHCII binding sites on PSI. Since oligomerization of thylakoid curvature protein (CURT1A) was unaffected by the absence of STN7 or TAP38, we conclude that the primary determinant of dynamic thylakoid stacking is LHCII phosphorylation.

Published

2019

38. Picosecond Dynamical Response to a Pressure-Induced Break of the Tertiary Structure Hydrogen Bonds in a Membrane Chromoprotein

Author

Judith Peters, Elizabeth C. Martin, Arvi Freiberg, C. Neil Hunter, Jörg Pieper, Liina Kangur, and Maksym Golub

Subjects

Hydrogen, Hydrostatic pressure, Light-Harvesting Protein Complexes, chemistry.chemical_element, Rhodobacter sphaeroides, 010402 general chemistry, 01 natural sciences, chemistry.chemical_compound, Protein structure, 0103 physical sciences, Hydrostatic Pressure, Materials Chemistry, Physical and Theoretical Chemistry, Bacteriochlorophylls, 010304 chemical physics, Chemistry, Hydrogen bond, Protein dynamics, Hydrogen Bonding, Carotenoids, Protein tertiary structure, 0104 chemical sciences, Surfaces, Coatings and Films, Membrane protein complex, Chemical physics, Neurosporene

Abstract

We used elastic incoherent neutron scattering (EINS) to find out if structural changes accompanying local hydrogen bond rupture are also reflected in global dynamical response of the protein complex. Chromatophore membranes from LH2-only strains of the photosynthetic bacterium Rhodobacter sphaeroides, with spheroidenone or neurosporene as the major carotenoids, were subjected to high hydrostatic pressure at ambient temperature. Optical spectroscopy conducted at high pressure confirmed rupture of tertiary structure hydrogen bonds. In parallel, we used EINS to follow average motions of the hydrogen atoms in LH2, which reflect the flexibility of this complex. A decrease of the average atomic mean square displacements of hydrogen atoms was observed up to a pressure of 5 kbar in both carotenoid samples due to general stiffening of protein structures, while at higher pressures a slight increase of the displacements was detected in the neurosporene mutant LH2 sample only. These data show a correlation between the local pressure-induced breakage of H-bonds, observed in optical spectra, with the altered protein dynamics monitored by EINS. The slightly higher compressibility of the neurosporene mutant sample shows that even subtle alterations of carotenoids are manifested on a larger scale and emphasize a close connection between the local structure and global dynamics of this membrane protein complex.

Published

2019

39. Turning the challenge of quantum biology on its head: biological control of quantum optical systems

Author

Graham J. Leggett, Anna Lishchuk, Päivi Törmä, Cvetelin Vasilev, C. Neil Hunter, and Matthew P. Johnson

Subjects

Materials science, Protein Conformation, Exciton, Photosystem II Protein Complex, Resonance, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Molecular physics, 0104 chemical sciences, Quantum biology, Coupling (physics), Quantum Theory, Synthetic Biology, Physical and Theoretical Chemistry, Surface plasmon resonance, 0210 nano-technology, Quantum, Plasmon, Harmonic oscillator

Abstract

When light-harvesting complex II (LHCII), isolated from spinach, is adsorbed onto arrays of gold nanostructures formed by interferometric lithography, a pronounced splitting of the plasmon band is observed that is attributable to strong coupling of the localised surface plasmon resonance to excitons in the pigment-protein complex. The system is modelled as coupled harmonic oscillators, yielding an exciton energy of 2.24 ± 0.02 eV. Analysis of dispersion curves yields a Rabi energy of 0.25 eV. Extinction spectra of the strongly coupled system yield a resonance at 1.43 eV that varies as a function of the density of nanostructures in the array. The enhanced intensity of this feature is attributed to strong plasmon-exciton coupling. Comparison of data for a large number of light-harvesting complexes indicates that by control of the protein structure and/or pigment compliment it is possible to manipulate the strength of plasmon-exciton coupling. In strongly coupled systems, ultra-fast exchange of energy occurs between pigment molecules: coherent coupling between non-local excitons can be manipulated via selection of the protein structure enabling the observation of transitions that are not seen in the weak coupling regime. Synthetic biology thus provides a means to control quantum-optical interactions in the strong coupling regime.

Published

2019

40. Structures of Rhodopseudomonas palustris RC-LH1 complexes with open or closed quinone channels

Author

Dewey Holten, Christine Kirmaier, David J. K. Swainsbury, Lorna A. Malone, Andrew Hitchcock, Dariusz M. Niedzwiedzki, Mark J. Dickman, C. Neil Hunter, Daniel P. Canniffe, Elizabeth C. Martin, Neil A. Ranson, David A. Farmer, Philip J. Jackson, Pu Qian, Rebecca F. Thompson, and Kaitlyn M. Faries

Subjects

0303 health sciences, Conformational change, Multidisciplinary, biology, Stereochemistry, Chemistry, Resolution (electron density), SciAdv r-articles, 02 engineering and technology, 021001 nanoscience & nanotechnology, Ring (chemistry), biology.organism_classification, Photosynthesis, Quinone, 03 medical and health sciences, Quinone binding, Structural Biology, Rhodopseudomonas palustris, 0210 nano-technology, Research Articles, 030304 developmental biology, Research Article

Abstract

High-resolution structures of reaction-center light-harvesting 1 complexes provide new insights into quinone dynamics., The reaction-center light-harvesting complex 1 (RC-LH1) is the core photosynthetic component in purple phototrophic bacteria. We present two cryo–electron microscopy structures of RC-LH1 complexes from Rhodopseudomonas palustris. A 2.65-Å resolution structure of the RC-LH114-W complex consists of an open 14-subunit LH1 ring surrounding the RC interrupted by protein-W, whereas the complex without protein-W at 2.80-Å resolution comprises an RC completely encircled by a closed, 16-subunit LH1 ring. Comparison of these structures provides insights into quinone dynamics within RC-LH1 complexes, including a previously unidentified conformational change upon quinone binding at the RC QB site, and the locations of accessory quinone binding sites that aid their delivery to the RC. The structurally unique protein-W prevents LH1 ring closure, creating a channel for accelerated quinone/quinol exchange.

Published

2021

41. Multiscale modeling and cinematic visualization of photosynthetic energy conversion processes from electronic to cell scales

Author

Zaida Luthey-Schulten, Barry Isralewitz, AJ Christensen, Stuart Levy, Donna Cox, Melih Sener, Robert Patterson, Kalina Borkiewicz, C. Neil Hunter, Jeff Carpenter, and John E. Stone

Subjects

Computational model, Computer Networks and Communications, Computer science, Fulldome, 010103 numerical & computational mathematics, 01 natural sciences, Computer Graphics and Computer-Aided Design, Multiscale modeling, Article, Theoretical Computer Science, Visualization, 010101 applied mathematics, Artificial Intelligence, Hardware and Architecture, Computer graphics (images), Energy transformation, Ray tracing (graphics), 0101 mathematics, Software

Abstract

Conversion of sunlight into chemical energy, namely photosynthesis, is the primary energy source of life on Earth. A visualization depicting this process, based on multiscale computational models from electronic to cell scales, is presented in the form of an excerpt from the fulldome show Birth of Planet Earth. This accessible visual narrative shows a lay audience, including children, how the energy of sunlight is captured, converted, and stored through a chain of proteins to power living cells. The visualization is the result of a multi-year collaboration among biophysicists, visualization scientists, and artists, which, in turn, is based on a decade-long experimental-computational collaboration on structural and functional modeling that produced an atomic detail description of a bacterial bioenergetic organelle, the chromatophore. Software advancements necessitated by this project have led to significant performance and feature advances, including hardware-accelerated cinematic ray tracing and instanced visualizations for efficient cell-scale modeling. The energy conversion steps depicted feature an integration of function from electronic to cell levels, spanning nearly 12 orders of magnitude in time scales. This atomic detail description uniquely enables a modern retelling of one of humanity’s earliest stories—the interplay between light and life.

Published

2021

42. Structure of the light harvesting 2 complex reveals two carotenoid energy transfer pathways in a photosynthetic bacterium

Author

Kasim Sader, Alastair T. Gardiner, Pu Qian, Pablo Castro-Hartmann, C. Neil Hunter, Katerina Naydenova, Richard J. Cogdell, Christopher J. Russo, and Tu C. Nguyen-Phan

Subjects

chemistry.chemical_classification, Coupling (electronics), Chemistry, Chemical physics, Energy transfer, Resolution (electron density), Molecule, Electron, Ring (chemistry), Carotenoid, Bacterial antenna complex

Abstract

We report the 2.4 Å resolution structure of the light harvesting 2 complex (LH2) from Marichromatium (Mch.) purpuratum determined by electron cryo-microscopy. The structure contains a heptameric ring that is unique among all known LH2 structures, explaining the unusual spectroscopic properties of this bacterial antenna complex. Two sets of distinct carotenoids are identified in the structure, and a network of energy transfer pathways from the carotenoids to bacteriochlorophyll a molecules is shown. The geometry imposed by the heptameric ring controls the resonant coupling of the long wavelength energy absorption band. Together, these details reveal key aspects of the assembly and oligomeric form of purple bacterial LH2 complexes that were previously inaccessible by any technique.One Sentence SummaryThe structure of a heptameric LH2 antenna complex reveals new energy transfer pathways and the basis for assembling LH rings.

Published

2020

43. Cytochrome b

Author

Lorna A, Malone, Matthew S, Proctor, Andrew, Hitchcock, C Neil, Hunter, and Matthew P, Johnson

Subjects

Electron Transport, Cytochrome b6f Complex, Cell Respiration, Electrons, Photosynthesis

Abstract

Cytochrome b

Published

2020

44. A Thermostable Protein Matrix for Spectroscopic Analysis of Organic Semiconductors

Author

Shuangqing Wang, David G. Bossanyi, James P. Pidgeon, John E. Anthony, Daniel Polak, David J. K. Swainsbury, George A. Sutherland, Andrew Hitchcock, Frank C. Spano, Andrew J. Musser, Dirk B. Auman, C. Neil Hunter, P. Leslie Dutton, and Jenny Clark

Subjects

Protein design, Nanoparticle, Peptide, 02 engineering and technology, Xanthophylls, 010402 general chemistry, 01 natural sciences, Biochemistry, Catalysis, Matrix (chemical analysis), Colloid and Surface Chemistry, chemistry.chemical_classification, Aqueous solution, Molecular Structure, Protein Stability, Spectrum Analysis, Temperature, Proteins, General Chemistry, Chromophore, 021001 nanoscience & nanotechnology, Biocompatible material, Combinatorial chemistry, 0104 chemical sciences, Organic semiconductor, chemistry, Semiconductors, 0210 nano-technology, Peptides

Abstract

Advances in protein design and engineering have yielded peptide assemblies with enhanced and non-native functionalities. Here, various molecular organic semiconductors (OSCs), with known excitonic up- and down-conversion properties, are attached to a de novo-designed protein, conferring entirely novel functions on the peptide scaffolds. The protein-OSC complexes form similarly sized, stable, water-soluble nanoparticles that are robust to cryogenic freezing and processing into the solid-state. The peptide matrix enables the formation of protein-OSC-trehalose glasses that fix the proteins in their folded states under oxygen-limited conditions. The encapsulation dramatically enhances the stability of protein-OSC complexes to photodamage, increasing the lifetime of the chromophores from several hours to more than 10 weeks under constant illumination. Comparison of the photophysical properties of astaxanthin aggregates in mixed-solvent systems and proteins shows that the peptide environment does not alter the underlying electronic processes of the incorporated materials, exemplified here by singlet exciton fission followed by separation into weakly bound, localized triplets. This adaptable protein-based approach lays the foundation for spectroscopic assessment of a broad range of molecular OSCs in aqueous solutions and the solid-state, circumventing the laborious procedure of identifying the experimental conditions necessary for aggregate generation or film formation. The non-native protein functions also raise the prospect of future biocompatible devices where peptide assemblies could complex with native and non-native systems to generate novel functional materials.

Published

2020

45. Excitation energy transfer between monomolecular layers of light harvesting LH2 and LH1-reaction centre complexes printed on a glass substrate

Author

C. Neil Hunter, Cvetelin Vasilev, and Xia Huang

Subjects

Materials science, Biomedical Engineering, Light-Harvesting Protein Complexes, Bioengineering, macromolecular substances, 02 engineering and technology, Rhodobacter sphaeroides, 010402 general chemistry, Photosynthesis, Photochemistry, 01 natural sciences, Biochemistry, Microscopy, Deposition (law), Rhodobacter, biology, Substrate (chemistry), General Chemistry, 021001 nanoscience & nanotechnology, biology.organism_classification, Acceptor, Fluorescence, Carotenoids, 0104 chemical sciences, Energy Transfer, 0210 nano-technology, Excitation

Abstract

Light-harvesting 2 (LH2) and light-harvesting 1 – reaction centre (RCLH1) complexes purified from the photosynthetic bacterium Rhodobacter (Rba.) sphaeroides were cross-patterned on glass surfaces for energy transfer studies. Atomic force microscopy (AFM) images of the RCLH1 and LH2 patterns show the deposition of monomolecular layers of complexes on the glass substrate. Spectral imaging and fluorescence life-time imaging microscopy (FLIM) revealed that RCLH1 and LH2 complexes, sealed under physiological conditions, retained their native light-harvesting and energy transfer functions. Measurements of the amplitude and lifetime decay of fluorescence emission from LH2 complexes, the energy transfer donors, and gain of fluorescence emission from acceptor RCLH1 complexes, provide evidence for excitation energy transfer from LH2 to RCLH1. Directional energy transfer on the glass substrate was unequivocally established by using LH2-carotenoid complexes and RCLH1 complexes with genetically removed carotenoids. Specific excitation of carotenoids in donor LH2 complexes elicited fluorescence emission from RCLH1 acceptors. To explore the longevity of this novel nanoprinted photosynthetic unit, RCLH1 and LH2 complexes were cross-patterned on a glass surface and sealed under a protective argon atmosphere. The results show that both complexes retained their individual and collective functions and are capable of directional excitation energy transfer for at least 60 days.

Published

2020

46. The active site of magnesium chelatase

Author

Nathan B P, Adams, Claudine, Bisson, Amanda A, Brindley, David A, Farmer, Paul A, Davison, James D, Reid, and C Neil, Hunter

Subjects

Chlorophyll, Enzyme Activation, Thermosynechococcus, Lyases, Protoporphyrins, Photosynthesis

Abstract

The insertion of magnesium into protoporphyrin initiates the biosynthesis of chlorophyll, the pigment that underpins photosynthesis. This reaction, catalysed by the magnesium chelatase complex, couples ATP hydrolysis by a ChlID motor complex to chelation within the ChlH subunit. We probed the structure and catalytic function of ChlH using a combination of X-ray crystallography, computational modelling, mutagenesis and enzymology. Two linked domains of ChlH in an initially open conformation of ChlH bind protoporphyrin IX, and the rearrangement of several loops envelops this substrate, forming an active site cavity. This induced fit brings an essential glutamate (E660), proposed to be the key catalytic residue for magnesium insertion, into proximity with the porphyrin. A buried solvent channel adjacent to E660 connects the exterior bulk solvent to the active site, forming a possible conduit for the delivery of magnesium or abstraction of protons.

Published

2020

47. A photosynthetic antenna complex foregoes unity carotenoid-to-bacteriochlorophyll energy transfer efficiency to ensure photoprotection

Author

David J. K. Swainsbury, Andrew Hitchcock, Dariusz M. Niedzwiedzki, C. Neil Hunter, and Daniel P. Canniffe

Subjects

Light-Harvesting Protein Complexes, Rhodobacter sphaeroides, 010402 general chemistry, Photosynthesis, Photochemistry, 01 natural sciences, chemistry.chemical_compound, Bacterial Proteins, 0103 physical sciences, Ultrafast laser spectroscopy, Bacteriochlorophylls, Multidisciplinary, 010304 chemical physics, biology, Biological Sciences, biology.organism_classification, Carotenoids, Fluorescence, 0104 chemical sciences, Kinetics, Energy Transfer, chemistry, Absorption band, Photoprotection, Excited state, Bacteriochlorophyll

Abstract

Carotenoids play a number of important roles in photosynthesis, primarily providing light-harvesting and photoprotective energy dissipation functions within pigment–protein complexes. The carbon–carbon double bond (C=C) conjugation length of carotenoids (N), generally between 9 and 15, determines the carotenoid-to-(bacterio)chlorophyll [(B)Chl] energy transfer efficiency. Here we purified and spectroscopically characterized light-harvesting complex 2 (LH2) from Rhodobacter sphaeroides containing the N = 7 carotenoid zeta (ζ)-carotene, not previously incorporated within a natural antenna complex. Transient absorption and time-resolved fluorescence show that, relative to the lifetime of the S(1) state of ζ-carotene in solvent, the lifetime decreases ∼250-fold when ζ-carotene is incorporated within LH2, due to transfer of excitation energy to the B800 and B850 BChls a. These measurements show that energy transfer proceeds with an efficiency of ∼100%, primarily via the S(1) → Q(x) route because the S(1) → S(0) fluorescence emission of ζ-carotene overlaps almost perfectly with the Q(x) absorption band of the BChls. However, transient absorption measurements performed on microsecond timescales reveal that, unlike the native N ≥ 9 carotenoids normally utilized in light-harvesting complexes, ζ-carotene does not quench excited triplet states of BChl a, likely due to elevation of the ζ-carotene triplet energy state above that of BChl a. These findings provide insights into the coevolution of photosynthetic pigments and pigment–protein complexes. We propose that the N ≥ 9 carotenoids found in light-harvesting antenna complexes represent a vital compromise that retains an acceptable level of energy transfer from carotenoids to (B)Chls while allowing acquisition of a new, essential function, namely, photoprotective quenching of harmful (B)Chl triplets.

Published

2020

48. FRET measurement of cytochrome bc1 and reaction centre complex proximity in live Rhodobacter sphaeroides cells

Author

Sandip Kumar, Matthew P. Johnson, Cvetelin Vasilev, Jamie K. Hobbs, Michaël L. Cartron, C. Neil Hunter, David J. K. Swainsbury, Elizabeth C. Martin, and Andrew Hitchcock

Subjects

0303 health sciences, Rhodobacter, biology, Cytochrome, Cytochrome bc1, Chemistry, Biophysics, Cell Biology, 010402 general chemistry, biology.organism_classification, 7. Clean energy, 01 natural sciences, Biochemistry, Purple bacteria, 0104 chemical sciences, 03 medical and health sciences, Rhodobacter sphaeroides, Förster resonance energy transfer, Coenzyme Q – cytochrome c reductase, biology.protein, Electrochemical gradient, 030304 developmental biology

Abstract

In the model purple phototrophic bacterium Rhodobacter (Rba.) sphaeroides, solar energy is converted via coupled electron and proton transfer reactions within the intracytoplasmic membranes (ICMs), infoldings of the cytoplasmic membrane that form spherical ‘chromatophore’ vesicles. These bacterial ‘organelles’ are ideal model systems for studying how the organisation of the photosynthetic complexes therein shape membrane architecture. In Rba. sphaeroides, light-harvesting 2 (LH2) complexes transfer absorbed excitation energy to dimeric reaction centre (RC)-LH1-PufX complexes. The PufX polypeptide creates a channel that allows the lipid soluble electron carrier quinol, produced by RC photochemistry, to diffuse to the cytochrome bc1 complex, where quinols are oxidised to quinones, with the liberated protons used to generate a transmembrane proton gradient and the electrons returned to the RC via cytochrome c2. Proximity between cytochrome bc1 and RC-LH1-PufX minimises quinone/quinol/cytochrome c2 diffusion distances within this protein-crowded membrane, however this distance has not yet been measured. Here, we tag the RC and cytochrome bc1 with yellow or cyan fluorescent proteins (Y/CFP) and record the lifetimes of YFP/CFP Forster resonance energy transfer (FRET) pairs in whole cells. FRET analysis shows that that these complexes lie on average within 6 nm of each other. Complementary high-resolution AFM of intact, purified chromatophores verifies the close association of cytochrome bc1 complexes with RC-LH1-PufX dimers. Our results provide a structural basis for the close kinetic coupling observed by spectroscopy between RC-LH1-PufX and cytochrome bc1, and explain how quinols/quinones and cytochrome c2 shuttle on a millisecond timescale between these complexes, sustaining efficient photosynthetic electron flow.

Published

2022

49. Proteorhodopsin Overproduction Enhances the Long-Term Viability of Escherichia coli

Author

Yizhi Song, Di Zhu, Wei E. Huang, Michaël L. Cartron, Mark J. Dickman, Paul A. Davison, C. Neil Hunter, and Philip J. Jackson

Subjects

Shewanella, proteorhodopsin, Cell Survival, Oceans and Seas, Population, Spectrum Analysis, Raman, medicine.disease_cause, Applied Microbiology and Biotechnology, Cell membrane, 03 medical and health sciences, Marine bacteriophage, Bacterial Proteins, single cells, Rhodopsins, Microbial, Environmental Microbiology, Escherichia coli, medicine, 14. Life underwater, Viability assay, Shewanella oneidensis, education, membrane, cell viability, cell membranes, Vibrio, 030304 developmental biology, 2. Zero hunger, 0303 health sciences, education.field_of_study, Proteorhodopsin, Ecology, biology, 030306 microbiology, Chemistry, Cell Membrane, Proton Pumps, biology.organism_classification, Recombinant Proteins, Cell biology, medicine.anatomical_structure, marine bacteria, Raman spectroscopy, biology.protein, Single-Cell Analysis, Bacteria, Food Science, Biotechnology

Abstract

Proteorhodopsin (PR) is part of a diverse, abundant, and widespread superfamily of photoreactive proteins, the microbial rhodopsins. PR, a light-driven proton pump, enhances the ability of the marine bacterium Vibrio strain AND4 to survive and recover from periods of starvation, and heterologously produced PR extends the viability of nutrient-limited Shewanella oneidensis. We show that heterologously produced PR enhances the viability of E. coli cultures over long periods of several weeks and use single-cell Raman spectroscopy (SCRS) to detect PR in 9-month-old cells. We identify a densely packed and consequently stabilized cell membrane as the likely basis for extended viability. Similar considerations are suggested to apply to marine bacteria, for which high PR levels represent a significant investment in scarce metabolic resources. PR-stabilized cell membranes in marine bacteria are proposed to keep a population viable during extended periods of light or nutrient limitation, until conditions improve., Genes encoding the photoreactive protein proteorhodopsin (PR) have been found in a wide range of marine bacterial species, reflecting the significant contribution that PR makes to energy flux and carbon cycling in ocean ecosystems. PR can also confer advantages to enhance the ability of marine bacteria to survive periods of starvation. Here, we investigate the effect of heterologously produced PR on the viability of Escherichia coli. Quantitative mass spectrometry shows that E. coli, exogenously supplied with the retinal cofactor, assembles as many as 187,000 holo-PR molecules per cell, accounting for approximately 47% of the membrane area; even cells with no retinal synthesize ∼148,000 apo-PR molecules per cell. We show that populations of E. coli cells containing PR exhibit significantly extended viability over many weeks, and we use single-cell Raman spectroscopy (SCRS) to detect holo-PR in 9-month-old cells. SCRS shows that such cells, even incubated in the dark and therefore with inactive PR, maintain cellular levels of DNA and RNA and avoid deterioration of the cytoplasmic membrane, a likely basis for extended viability. The substantial proportion of the E. coli membrane required to accommodate high levels of PR likely fosters extensive intermolecular contacts, suggested to physically stabilize the cell membrane and impart a long-term benefit manifested as extended viability in the dark. We propose that marine bacteria could benefit similarly from a high PR content, with a stabilized cell membrane extending survival when those bacteria experience periods of severe nutrient or light limitation in the oceans. IMPORTANCE Proteorhodopsin (PR) is part of a diverse, abundant, and widespread superfamily of photoreactive proteins, the microbial rhodopsins. PR, a light-driven proton pump, enhances the ability of the marine bacterium Vibrio strain AND4 to survive and recover from periods of starvation, and heterologously produced PR extends the viability of nutrient-limited Shewanella oneidensis. We show that heterologously produced PR enhances the viability of E. coli cultures over long periods of several weeks and use single-cell Raman spectroscopy (SCRS) to detect PR in 9-month-old cells. We identify a densely packed and consequently stabilized cell membrane as the likely basis for extended viability. Similar considerations are suggested to apply to marine bacteria, for which high PR levels represent a significant investment in scarce metabolic resources. PR-stabilized cell membranes in marine bacteria are proposed to keep a population viable during extended periods of light or nutrient limitation, until conditions improve.

Published

2019

50. A paralog of a bacteriochlorophyll biosynthesis enzyme catalyzes the formation of 1,2-dihydrocarotenoids in green sulfur bacteria

Author

Daniel P. Canniffe, Jennifer L. Thweatt, Donald A. Bryant, Aline Gomez Maqueo Chew, and C. Neil Hunter

Subjects

0301 basic medicine, Mutant, Flavoprotein, Rhodobacter sphaeroides, Reductase, Chlorobium, medicine.disease_cause, Biochemistry, Microbiology, Chlorobi, 03 medical and health sciences, Blastochloris viridis, Bacterial Proteins, energy metabolism, medicine, Molecular Biology, Carotenoid, Bacteriochlorophylls, chemistry.chemical_classification, photosynthesis, biology, Chlorobaculum tepidum, Cell Biology, biology.organism_classification, Carotenoids, carotenoid, green sulfur bacterium, Biosynthetic Pathways, 030104 developmental biology, chemistry, Green sulfur bacteria, biology.protein, bacterial genetics, Oxidoreductases, Bacteria, Genome, Bacterial, photosynthetic pigment

Abstract

Chlorobaculum tepidum, a green sulfur bacterium, utilizes chlorobactene as its major carotenoid, and this organism also accumulates a reduced form of this monocyclic pigment, 1′,2′-dihydrochlorobactene. The protein catalyzing this reduction is the last unidentified enzyme in the biosynthetic pathways for all of the green sulfur bacterial pigments used for photosynthesis. The genome of C. tepidum contains two paralogous genes encoding members of the FixC family of flavoproteins: bchP, which has been shown to encode an enzyme of bacteriochlorophyll biosynthesis; and bchO, for which a function has not been assigned. Here we demonstrate that a bchO mutant is unable to synthesize 1′,2′-dihydrochlorobactene, and when bchO is heterologously expressed in a neurosporene-producing mutant of the purple bacterium, Rhodobacter sphaeroides, the encoded protein is able to catalyze the formation of 1,2-dihydroneurosporene, the major carotenoid of the only other organism reported to synthesize 1,2-dihydrocarotenoids, Blastochloris viridis. Identification of this enzyme completes the pathways for the synthesis of photosynthetic pigments in Chlorobiaceae, and accordingly and consistent with its role in carotenoid biosynthesis, we propose to rename the gene cruI. Notably, the absence of cruI in B. viridis indicates that a second 1,2-carotenoid reductase, which is structurally unrelated to CruI (BchO), must exist in nature. The evolution of this carotenoid reductase in green sulfur bacteria is discussed herein.

Published

2018