Andrew Hitchcock’s research while affiliated with The University of Sheffield and other places

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Publications (96)


Resonant Vibrational Enhancement of Downhill Energy Transfer in the C -Phycocyanin Chromophore Dimer
  • Article

November 2024

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6 Reads

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1 Citation

The Journal of Physical Chemistry Letters

Siddhartha Sohoni

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Ping-Jui Eric Wu

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Qijie Shen

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[...]

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Gregory S. Engel

Tethering ferredoxin-NADP+ reductase to photosystem I promotes photosynthetic cyclic electron transfer
  • Preprint
  • File available

November 2024

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78 Reads

Fixing CO2 via photosynthesis requires ATP and NADPH. Linear electron transfer (LET) supplies both metabolites, yet depending on environmental conditions, additional ATP is required which can be generated by cyclic electron transfer (CET). How the balance between LET and CET is set remains largely unknown. Ferredoxin(FD)-NADP+ reductase (FNR) has been suggested to act as the switch, channelling photosynthetic electrons to LET when it is bound to photosystem I (PSI) or CET when bound to cytochrome b6f. The essential role of FNR in LET precludes the use of a direct gene knock-out to test this hypothesis. We circumvented this problem by using CRISPR-Cas9 gene editing in Chlamydomonas reinhardtii to create a chimeric form of FNR tethered to PSI via PSAF. Chimeric FNR mutants exhibited impaired photosynthetic growth relative to the wild type, and decreased LET and non-photochemical quenching (NPQ) under high CO2 conditions. However, higher rates of CET and increased NPQ were found in the mutants under low CO2 or low O2 conditions where CET is normally up-regulated. Thus, rather than PSI-FNR interactions promoting LET, tethering FNR to PSI promotes CET at the expense of LET and CO2 fixation.

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Single-Molecule Detection of the Encounter and Productive Electron Transfer Complexes of a Photosynthetic Reaction Center

July 2024

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30 Reads

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1 Citation

Journal of the American Chemical Society

Small, diffusible redox proteins play an essential role in electron transfer (ET) in respiration and photosynthesis, sustaining life on Earth by shuttling electrons between membrane-bound complexes via finely tuned and reversible interactions. Ensemble kinetic studies show transient ET complexes form in two distinct stages: an “encounter” complex largely mediated by electrostatic interactions, which subsequently, through subtle reorganization of the binding interface, forms a “productive” ET complex stabilized by additional hydrophobic interactions around the redox-active cofactors. Here, using single-molecule force spectroscopy (SMFS) we dissected the transient ET complexes formed between the photosynthetic reaction center-light harvesting complex 1 (RC-LH1) of Rhodobacter sphaeroides and its native electron donor cytochrome c2 (cyt c2). Importantly, SMFS resolves the distribution of interaction forces into low (∼150 pN) and high (∼330 pN) components, with the former more susceptible to salt concentration and to alteration of key charged residues on the RC. Thus, the low force component is suggested to reflect the contribution of electrostatic interactions in forming the initial encounter complex, whereas the high force component reflects the additional stabilization provided by hydrophobic interactions to the productive ET complex. Employing molecular dynamics simulations, we resolve five intermediate states that comprise the encounter, productive ET and leaving complexes, predicting a weak interaction between cyt c2 and the LH1 ring near the RC-L subunit that could lie along the exit path for oxidized cyt c2. The multimodal nature of the interactions of ET complexes captured here may have wider implications for ET in all domains of life.


Hybrid xyloglucan utilisation loci are prevalent among plant-associated Bacteroidota

June 2024

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10 Reads

The plant hemicellulose xyloglucan (XyG) is secreted from the roots of numerous plant species, including cereals, and contributes towards soil aggregate formation in terrestrial systems. Whether XyG represents a key nutrient for plant-associated bacteria is unclear. The phylum Bacteroidota are abundant in the plant microbiome and provide several beneficial functions for their host. However, the metabolic and genomic traits underpinning their success remain poorly understood. Here, using proteomics, bacterial genetics, and genomics, we revealed that plant-associated Flavobacterium , a genus within the Bacteroidota, can efficiently utilise XyG through the occurrence of a distinct and conserved gene cluster, referred to as the Xyloglucan Utilisation Loci (XyGUL). Flavobacterium XyGUL is a hybrid of the molecular machinery found in gut Bacteroides spp., Cellvibrio japonicus , and the plant pathogen Xanthomonas . Combining protein biochemistry, computational modelling and phylogenetics, we identified a mutation in the enzyme required for initiating hydrolysis of the XyG polysaccharide, an outer membrane endoxyloglucanase glycoside hydrolase family 5 subfamily 4 (GH5_4), which enhances activity towards XyG. A subclade of GH5_4 homologs carrying this mutation were the dominant form found in soil and plant metagenomes due to their occurrence in Bacteroidota and Proteobacteria. However, only in members of the Bacteroidota spp., particularly Flavobacterium spp. was such a remarkable degree of XyGUL conservation detected. We propose this mechanism enables plant-associated Flavobacterium to specialise in competitive acquisition of XyG exudates and that this hemicellulose may represent an important nutrient source, enabling them to thrive in the plant microbiome, which is typified by intense competition for low molecular weight carbon exudates.


Assessment of the Role and Origin of S* in Orange Carotenoid Protein Photoconversion

May 2024

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98 Reads

The orange carotenoid protein (OCP) is the water-soluble mediator of non-photochemical quenching in cyanobacteria, a crucial photoprotective mechanism in response to excess illumination. OCP converts from a globular, inactive state (OCPo) to an extended, active conformation (OCPr) under high-light conditions, resulting in a concomitant redshift in the absorption of the bound carotenoid. Here, OCP was trapped in either the active or inactive state by fixing each protein conformation in trehalose-sucrose glass. Glass-encapsulated OCPo did not convert under intense illumination and OCPr did not convert in darkness, allowing the optical properties of each conformation to be determined at room temperature. We measured pump wavelength-dependent transient absorption of OCPo in glass films and found that initial OCP photoproducts are still formed, despite the glass preventing completion of the photocycle. By comparison to the pump wavelength dependence of the OCPo to OCPr photoconversion yield in buffer, we show that the long-lived carotenoid singlet-like feature (S*) is associated with ground-state heterogeneity within OCPo, rather than triggering OCP photoconversion.


Sulfoquinovosyl diacylglycerol is required for dimerization of the Rhodobacter sphaeroides RC-LH1 core complex

May 2024

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17 Reads

Biochemical Journal

The reaction centre-light harvesting 1 (RC-LH1) core complex is indispensable for anoxygenic photosynthesis. In the purple bacterium Rhodobacter (Rba.) sphaeroides RC-LH1 is produced both as a monomer in which 14 LH1 subunits form a C-shaped antenna around one RC, and as a dimer, where 28 LH1 subunits form an S-shaped antenna surrounding two RCs. Alongside the five RC and LH1 subunits, an additional polypeptide known as PufX provides an interface for dimerization and also prevents LH1 ring closure, introducing a channel for quinone exchange that is essential for photoheterotrophic growth. Structures of Rba. sphaeroides RC-LH1 complexes revealed several new components; protein-Y, which helps to form the quinone channel; protein-Z, of unknown function and seemingly unique to dimers; and a tightly bound sulfoquinovosyl diacylglycerol (SQDG) lipid that interacts with two PufX arginine residues. This lipid lies at the dimer interface alongside weak density for a second molecule, previously proposed to be an ornithine lipid. In this work we have generated strains of Rba.sphaeroides lacking protein-Y, protein-Z, SQDG or ornithine lipids to assess the roles of these previously unknown components in the assembly and activity of RC-LH1. We show that whilst the removal of either protein-Y, protein-Z or ornithine lipids has only subtle effects, SQDG is essential for the formation of RC-LH1 dimers but its absence has no functional effect on the monomeric complex.


Figure 1. Structure of the dimeric Rba. sphaeroides RC-LH1 core complex. (A) Surface view of the complete 93 complex from the lumenal (periplasmic) face. The RC subunits are shown in orange (RC-L), magenta (RC-M) 94 and cyan (RC-H). LH1 subunits are in yellow (α) and blue (β). Additional subunits are in red (PufX), green 95 (protein-Y) and purple (protein-Z). Lipids and cofactors are shown in stick representation in green (BChl), 96 magenta (carotenoids) and grey (SQDG). Unassigned density for lipid 2 is shown as a grey surface. Boxes 97 illustrate areas enlarged in panels B, C and D. (B) Enlarged view highlighting one of the SQDGs and lipid 2 98 bound at the dimer interface. The subunits from the left monomer (PufX, RC-L, α1 and β1), and those from 99 the right monomer (α1', β1' and Z1') are labelled. (C) A further enlarged view of the SQDG lipid with the 100 protein in ribbon representation. Hydrogen bonds between the SQDG head group and PufX Arg49 and Arg53, 101 and the backbone of RC-L residues Leu75 and Gly140 are shown. (D) Enlarged view of the two protein-Z 102 subunits bound to the left monomer (Z1 and Z2, purple) and protein-Y of the right monomer (Y', green) in 103 ribbon representation. The rest of the protein is in surface representation. 104
Figure 2. Lipid biosynthesis pathways and deletion of sqdB and olsBA and PCR verification of knockout 243 strains. (A) sulfoquinovosyl diacylglycerol (SQDG) is synthesised in two steps. The first step is the addition of 244 sulphite to UDP-glucose (UDP-Glc) to produce UDP-sulfoquinovose (UDP-SQ) by SqdB. Next, diacylglycerol is 245 added and UDP is removed by SqdA, C and D to produce SQDG [51]. (B) Ornithine lipids are synthesised by 246 the acyltransferases OlsB and OlsA, which sequentially add a 3-hydroxyacyl group then an acyl group to L-247 ornithine using 3-hydroxyl-ACP and acyl-ACP as substrates, respectively [54]. (C) Structure of the sqdBDC 248 operon. The region labelled ΔsqdB (encompassing Rsp_2569) was removed to abolish SQDG biosynthesis. (D) 249 Structure of the olsBA operon. The labelled region spanning olsB (Rsp_3826) and olsA (Rsp_3827) was 250 removed to prevent OL biosynthesis. (E) Agarose gel of ethidium bromide-stained PCR products showing size 251 differences for the amplified regions spanning the sqdB and olsBA genes showing a clear reduction in size in 252 the knockout strains relative to the wild-type. (F) TLC plate showing loss of SQDG lipid in the ΔsqdB strain. A 253 standard for SQDG was run in lane A and a band of the expected size can be seen in samples from ΔcrtA but 254 not in ΔcrtA ΔsqdB confirming the loss of SQDG biosynthesis. 255
Figure 3. The effects of removing protein-Y, protein-Z, SQDG or ornithine lipids on RC-LH1 dimer formation, 310 absorbance spectra and RC activity. (A-B) Solubilised chromatophore membranes separate into bands of 311 LH2, RC-LH1 monomer and RC-LH1 dimer when centrifuged on sucrose step gradients. Panel A shows the 312 wild-type strain (WT), a control strain that does not produce dimeric RC-LH1 (PufX R49L R53L), a strain lacking 313 protein-Y (ΔpuyA), a strain lacking protein-Z (ΔpuzA), a strain that cannot produce ornithine lipids (ΔolsBA), 314 and a strain that cannot produce SQDG lipids (ΔsqdB). Panel B shows sucrose gradients for the strains in (A) 315 in a background that is also deficient in the crtA gene encoding spheroidene monooxygenase (ΔcrtA). (C-D) 316 UV/Vis/NIR absorbance spectra of the monomer and dimer RC-LH1 bands harvested from the gradients in 317 (B). Panel C shows spectra for the ΔcrtA strain, and those also harbouring the ΔpuyA and ΔpuzA mutations. 318 Panel D shows spectra for the ΔcrtA strain, and strains also harbouring the RC-LH1 dimer-deficient PufX R49L 319 R53L mutations, and the ΔolsBA and ΔsqdB genes. (E) Turnover assays for monomeric and dimeric complexes 320 from the WT, and strains lacking proteins Y and Z in strains also lacking CrtA. (F) Turnover assays for the 321 monomeric WT, PufX R49L R53L monomeric control, and monomeric lipid-deficient mutants produced in the 322 wild-type background strain. Rates in E-F show moles of cyt c2 oxidised per second per mole of RC during 323 illumination using an 810 nm LED of a solution containing 0.01 (E) or 0.05 (F) μM RC-LH1 and 5 μM cyt c2. T-324 tests were performed relative to rates for monomeric or dimeric WT complexes where * denotes a p value 325 from 0.01-0.05 and ns denotes a p value > 0.05. 326
Bacterial strains used in this study. 127
Sulfoquinovosyl diacylglycerol is required for dimerization of the Rhodobacter sphaeroides RC-LH1 core complex

March 2024

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15 Reads

The reaction centre-light harvesting 1 (RC-LH1) core complex is indispensable for anoxygenic photosynthesis. In the purple bacterium Rhodobacter ( Rba. ) sphaeroides RC-LH1 is produced both as a monomer in which 14 LH1 subunits form a crescent-shaped antenna around one RC, and as a dimer, where 28 LH1 subunits form an S-shaped antenna surrounding two RCs. The PufX polypeptide augments the five RC and LH subunits, and in addition to providing an interface for dimerization, PufX also prevents LH1 ring closure, introducing a channel for quinone exchange that is essential for photoheterotrophic growth. Structures of Rba. sphaeroides RC-LH1 complexes revealed several new components; protein-Y, which helps to form a quinone channel; protein-Z, of unknown function but which is unique to dimers; and a tightly bound sulfoquinovosyl diacylglycerol (SQDG) lipid that interacts with two PufX arginines. This lipid lies at the dimer interface alongside weak density for a second molecule, previously proposed to be an ornithine lipid. In this work we have generated strains of Rba. sphaeroides lacking protein-Y, protein-Z, SQDG or ornithine lipids to assess the roles of these previously unknown components in the assembly and activity of RC-LH1. We show that whilst the removal of either protein-Y, protein-Z or ornithine lipids has only subtle effects, SQDG is essential for the formation of RC-LH1 dimers but its absence has no functional effect on the monomeric complex.


Generalized biomolecular modeling and design with RoseTTAFold All-Atom

March 2024

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199 Reads

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208 Citations

Science

Deep learning methods have revolutionized protein structure prediction and design but are currently limited to protein-only systems. We describe RoseTTAFold All-Atom (RFAA) which combines a residue-based representation of amino acids and DNA bases with an atomic representation of all other groups to model assemblies containing proteins, nucleic acids, small molecules, metals, and covalent modifications given their sequences and chemical structures. By fine tuning on denoising tasks we obtain RFdiffusionAA, which builds protein structures around small molecules. Starting from random distributions of amino acid residues surrounding target small molecules, we design and experimentally validate, through crystallography and binding measurements, proteins that bind the cardiac disease therapeutic digoxigenin, the enzymatic cofactor heme, and the light harvesting molecule bilin.



Generalized Biomolecular Modeling and Design with RoseTTAFold All-Atom

October 2023

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218 Reads

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42 Citations

Although AlphaFold2 (AF2) and RoseTTAFold (RF) have transformed structural biology by enabling high-accuracy protein structure modeling, they are unable to model covalent modifications or interactions with small molecules and other non-protein molecules that can play key roles in biological function. Here, we describe RoseTTAFold All-Atom (RFAA), a deep network capable of modeling full biological assemblies containing proteins, nucleic acids, small molecules, metals, and covalent modifications given the sequences of the polymers and the atomic bonded geometry of the small molecules and covalent modifications. Following training on structures of full biological assemblies in the Protein Data Bank (PDB), RFAA has comparable protein structure prediction accuracy to AF2, excellent performance in CAMEO for flexible backbone small molecule docking, and reasonable prediction accuracy for protein covalent modifications and assemblies of proteins with multiple nucleic acid chains and small molecules which, to our knowledge, no existing method can model simultaneously. By fine-tuning on diffusive denoising tasks, we develop RFdiffusion All-Atom (RFdiffusionAA), which generates binding pockets by directly building protein structures around small molecules and other non-protein molecules. Starting from random distributions of amino acid residues surrounding target small molecules, we design and experimentally validate proteins that bind the cardiac disease therapeutic digoxigenin, the enzymatic cofactor heme, and optically active bilin molecules with potential for expanding the range of wavelengths captured by photosynthesis. We anticipate that RFAA and RFdiffusionAA will be widely useful for modeling and designing complex biomolecular systems.


Citations (65)


... Similar strategies were widely used in previous computational simulations of RC-LH1 complexes. [23][24][25] First, the entire RC-LH1 complex was embedded into a pre-equilibrated lipid bilayer composed of single-component POPC, guided by the predicted phospholipid position of the Positioning of Proteins in Membrane server. [26] To mimic the negatively charged environment as closely as possible to the native state, we retained all original lipid molecules identified in the cryo-EM structure, including negatively charged phospholipids such as PG and CL. ...

Reference:

Tunneling Mechanisms of Quinones in Photosynthetic Reaction Center–Light Harvesting 1 Supercomplexes
Single-Molecule Detection of the Encounter and Productive Electron Transfer Complexes of a Photosynthetic Reaction Center
  • Citing Article
  • July 2024

Journal of the American Chemical Society

... The flexible protein still poses a challenge for modern docking although significant progress had been made. Those includes molecular dynamics simulations to scan conformational landscape of CYPs and docking into conformational ensemble of rigid structures instead of a single structure [9] and, more recently developed, RosettaFold-All-Atom (RFAA) [10], FIG. 1: Difference between redocking and crossdocking. ...

Generalized biomolecular modeling and design with RoseTTAFold All-Atom
  • Citing Article
  • March 2024

Science

... Of interest in biomedical communities, tasks such as Protein-Protein Interaction (PPI) and function prediction were improved with this approach (12,17,18). Generating natural seeming sequences from noise has also been possible with pLMs (19)(20)(21). However, a more recent study of pLM pretraining strategies suggests that Masked Language Modeling (MLM) is particularly effective for structure-based modeling, injecting many structurally correlated patterns into the pLM latent space (22). ...

Generalized Biomolecular Modeling and Design with RoseTTAFold All-Atom

... In addition, the expression trends of most carotenoid synthesis-related genes closely mirrored the trends in carotenoid content ( Figure 5). This is consistent with recent studies that emphasize the coordinated regulation of chlorophyll and carotenoid pathways, ensuring a balance between these pigments, which is essential for effective light harvesting and photoprotection [49]. In addition, the expression trends of most carotenoid synthesis-related genes closely mirrored the trends in carotenoid content ( Figure 5). ...

Coordinating plant pigment production: A green role for ORANGE family proteins
  • Citing Article
  • August 2023

Molecular Plant

... To immobilize the carotenoid for spectroscopic analysis, we trapped OCP in either its OCPo or OCPr form at room temperature using a trehalose-sucrose glass 65,66 (herein referred to simply as "trehalose"), as previously described. 67,68 We conclude that the S* spectral feature cannot be directly correlated with the photoconversion yield and that this spectral feature merely arises from ground-state OCPo heterogeneity, comparable with solution-phase carotenoid studies. 48,49,62- 64 We do, nevertheless observe a wavelength-dependent photoswitching yield, showing that higher energy photons cause more rapid photoswitching. ...

Twisted Carotenoids Do Not Support Efficient Intramolecular Singlet Fission in the Orange Carotenoid Protein
  • Citing Article
  • June 2023

The Journal of Physical Chemistry Letters

... The EET pathways in PC 620 and PBS have been intensively investigated by time-resolved optical spectroscopy. [21][22][23][24][25] An ultrafast energy transfer process at ∼500 fs revealed by the transient absorption (TA) anisotropy experiment was attributed to EET from α84 to β84 located in adjacent monomers of PC 620 . 5 The EET lifetime from β155 to β84 in a single monomer of PC 620 was estimated to be 50 ps by Debreczeny and Sauer under the FRET mechanism, 26,27 and this process was determined to be around 17 ps in the latest experiment inside PBS. 25 These lifetime constants were much longer than those from subsequent TA experiments on PBS, in which the lifetime constants for energy flow along the PC rod were determined to be around 1-10 ps and the energy equilibration among PC 620 hexamers completed within 3 ps. ...

Phycobilisome's Exciton Transfer Efficiency Relies on an Energetic Funnel Driven by Chromophore-Linker Protein Interactions
  • Citing Article
  • May 2023

Journal of the American Chemical Society

... where E X (i) denotes the i-th excited state of dimer X (X = 1, 2, ···, 16) and V X,X′ (i,id ′) represents the excitonic coupling between the i-th excited state of dimer X and the i′-th excited state of dimer X′. Notably, the off-diagonal elements associated with the identical BChl a dimer are assigned a value of zero, i.e., V X,X (i,id ′) = 0 (i ≠ i′). ...

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

Bioscience Reports

... However, the structure of this complex fails to explain the unique features of the Hlr. halochloris complex (Qian et al., 2018;Namoon et al., 2022;Hitchcock et al., 2023). Therefore, a more detailed picture of the Hlr. ...

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

Biochemical Journal

... 11,20 These simulations identified high flexibility among side chains, leading to three binding modes for the quinol substrate. Two of these modes appear proximal to heme b L and enable electron and proton transfer, while a third mode represents a pre-reactive state, in agreement with recent cryoEM structures with a bound Q. [21][22][23] Additionally, our MD results show that the Q o site is highly hydrated, with several water molecules creating an H-bond network connecting quinol with conserved residues such as Y147, E295, and Y297 (residue numbering from the bc 1 complex of R. sphaeroides, Fig. 1B). Through this network, at least five distinct proton wires were identified that could facilitate proton transport to final acceptors like H152, D278 and the heme b L propionate-A group (PRA bL ) that then release the protons to the bulk water. ...

Cryo-EM structure of the four-subunit Rhodobacter sphaeroides cytochrome bc1 complex in styrene maleic acid nanodiscs

Proceedings of the National Academy of Sciences

... A significant finding of our study is that the MIC is strongly affected by the inclusion of reducing agents like L-Cys, which is critical for fastidious anaerobic bacteria, especially those associated with periodontitis, such as F. nucleatum and Campylobacter jejuni [86][87][88]. If not included, these bacteria will be highly susceptible to any new antimicrobial being tested, thus yielding a spuriously low MIC. ...

Cysteine Biosynthesis in Campylobacter jejuni: Substrate Specificity of CysM and the Dualism of Sulfide

Biomolecules