A new twist on PIFE: photoisomerisation-related fluorescence enhancement

PIFE was first used as an acronym for protein-induced fluorescence enhancement, which refers to the increase in fluorescence observed upon the interaction of a fluorophore, such as a cyanine, with a protein. This fluorescence enhancement is due to changes in the rate of cis/trans photoisomerisation. It is clear now that this mechanism is generally applicable to interactions with any biomolecule and, in this review, we propose that PIFE is thereby renamed according to its fundamental working principle as photoisomerisation-related fluorescence enhancement, keeping the PIFE acronym intact. We discuss the photochemistry of cyanine fluorophores, the mechanism of PIFE, its advantages and limitations, and recent approaches to turn PIFE into a quantitative assay. We provide an overview of its current applications to different biomolecules and discuss potential future uses, including the study of protein-protein interactions, protein-ligand interactions and conformational changes in biomolecules.Comment: No Comment

Predicting the structure of large protein complexes using AlphaFold and Monte Carlo tree search

AlphaFold can predict the structure of single- and multiple-chain proteins with very high accuracy. However, the accuracy decreases with the number of chains, and the available GPU memory limits the size of protein complexes which can be predicted. Here we show that one can predict the structure of large complexes starting from predictions of subcomponents. We assemble 91 out of 175 complexes with 10–30 chains from predicted subcomponents using Monte Carlo tree search, with a median TM-score of 0.51. There are 30 highly accurate complexes (TM-score ≥0.8, 33% of complete assemblies). We create a scoring function, mpDockQ, that can distinguish if assemblies are complete and predict their accuracy. We find that complexes containing symmetry are accurately assembled, while asymmetrical complexes remain challenging. The method is freely available and accesible as a Colab notebook https://colab.research.google.com/github/patrickbryant1/MoLPC/blob/master/MoLPC.ipynb

The fatty acid site is coupled to functional motifs in the SARS-CoV-2 spike protein and modulates spike allosteric behaviour

The SARS-CoV-2 spike protein is the first contact point between the SARS-CoV-2 virus and host cells and mediates membrane fusion. Recently, a fatty acid binding site was identified in the spike (Toelzer et al. Science 2020). The presence of linoleic acid at this site modulates binding of the spike to the human ACE2 receptor, stabilizing a locked conformation of the protein. Here, dynamical-nonequilibrium molecular dynamics simulations reveal that this fatty acid site is coupled to functionally relevant regions of the spike, some of them far from the fatty acid binding pocket. Removal of a ligand from the fatty acid binding site significantly affects the dynamics of distant, functionally important regions of the spike, including the receptor-binding motif, furin cleavage site and fusion-peptide-adjacent regions. Simulations of the D614G mutant show differences in behaviour between these clinical variants of the spike: the D614G mutant shows a significantly different conformational response for some structural motifs relevant for binding and fusion. The simulations identify structural networks through which changes at the fatty acid binding site are transmitted within the protein. These communication networks significantly involve positions that are prone to mutation, indicating that observed genetic variation in the spike may alter its response to linoleate binding and associated allosteric communication

A new twist on PIFE: photoisomerisation-related fluorescence enhancement

PIFE was first used as an acronym for protein-induced fluorescence enhancement, which refers to the increase in fluorescence observed upon the interaction of a fluorophore, such as a cyanine, with a protein. This fluorescence enhancement is due to changes in the rate of cis/trans photoisomerisation. It is clear now that this mechanism is generally applicable to interactions with any biomolecule and, in this review, we propose that PIFE is thereby renamed according to its fundamental working principle as photoisomerisation-related fluorescence enhancement, keeping the PIFE acronym intact. We discuss the photochemistry of cyanine fluorophores, the mechanism of PIFE, its advantages and limitations, and recent approaches to turn PIFE into a quantitative assay. We provide an overview of its current applications to different biomolecules and discuss potential future uses, including the study of protein-protein interactions, protein-ligand interactions and conformational changes in biomolecules

Insights into the function of ion channels by computational electrophysiology simulations

Ion channels are of universal importance for all cell types and play key roles in cellular physiology and pathology. Increased insight into their functional mechanisms is crucial to enable drug design on this important class of membrane proteins, and to enhance our understanding of some of the fundamental features of cells. This review presents the concepts behind the recently developed simulation protocol Computational Electrophysiology (CompEL), which facilitates the atomistic simulation of ion channels in action. In addition, the review provides guidelines for its application in conjunction with the molecular dynamics software package GROMACS. We first lay out the rationale for designing CompEL as a method that models the driving force for ion permeation through channels the way it is established in cells, i.e., by electrochemical ion gradients across the membrane. This is followed by an outline of its implementation and a description of key settings and parameters helpful to users wishing to set up and conduct such simulations. In recent years, key mechanistic and biophysical insights have been obtained by employing the CompEL protocol to address a wide range of questions on ion channels and permeation. We summarize these recent findings on membrane proteins, which span a spectrum from highly ion-selective, narrow channels to wide diffusion pores. Finally we discuss the future potential of CompEL in light of its limitations and strengths. This article is part of a Special Issue entitled: Membrane Proteins edited by J.C. Gumbart and Sergei Noskov

Characterisation of peroxisome-organelle contacts and cooperation

Peroxisomes are organelles which are vital for human health and development. They represent dynamic subcellular compartments which play cooperative roles in essential cellular metabolic processes such as lipid metabolism and redox balance. For example, cooperation between peroxisomes and the endoplasmic reticulum (ER) is essential for the production of myelin lipids which are required for normal neurological function. We recently discovered that peroxisome-ER interaction is mediated by physical linkages in the form of membrane contact sites. These contact sites are mediated by the interaction of peroxisomal ACBD5 and ER-resident VAPB proteins. ACBD5-deficient patients have recently been identified who display retinal dystrophy, white matter disease and accumulation of very-long-chain fatty acids, which can only be degraded in peroxisomes. There is currently a need to develop simple and robust tools to allow efficient visualisation and quantification of these membrane contact sites to further their characterisation and investigate their function. Moreover, these should allow the dynamics of membrane contact sites under physiological conditions to be assessed. This study presents the optimisation of two systems to investigate peroxisome-ER interactions, the proximity ligation assay, Duolink® and a split fluorescent reporter system, split superfolder green fluorescent protein. These allow peroxisome-ER interactions to be visualised and measured in situ with a fluorescence-based readout when the organelles are in close proximity. These systems are powerful and modifiable and will help further characterise peroxisome-ER (or other organelle) membrane contacts and shed light on the interplay between peroxisomes and the ER

Technology development for the over-expression, purification and crystallisation of human membrane proteins

Currently, the field of mammalian membrane protein structural biology is in its infancy. Existing technologies and experiences have shown that it is possible to obtain the structures of mammalian membrane proteins if sufficient work and thought has been invested. However, there is still an urgent need to develop new methodologies and approaches to improve all aspects of this important area of biological research. Here, a series of novel technologies for the overproduction, purification and crystallisation of human membrane proteins are described which have been tested with a representative member from each of the G-protein coupled receptor (adenosine 2a receptor (A2aR)) and membrane enzyme (sterol isomerase (SI)) superfamilies. The methylotrophic yeast Pichia pastoris is an excellent host cell for the overproduction of recombinant proteins including membrane proteins of mammalian origin. However, the commercially available expression vectors are far from what is required to maximise the production levels as well as simplify the detergent extraction and purification of human membrane proteins. Here, a series of related expression constructs were made that had different combinations of tags at both ends of the recombinant protein. The final optimised expression vectors had a C3 protease-iLOV-biotin acceptor-His10 (CLBH) tag fused to the C-terminus of the recombinant protein. The -CLBH vectors gave high level production of both test proteins (one Nin – hSI; one Nout – hA2aR) that could be rapidly purified to homogeneity using a generic protocol. The position of the His10 tag did not affect the expression level of the recombinant protein. In contrast, fusion of the biotin acceptor domain to the C-terminus of the recombinant protein increased its expression by a factor of between 2-4. The biotin acceptor domain could also be fully biotinylated in vitro using recombinantly expressed biotin ligase allowing purification/immobilisation of the target protein with streptavidin beads. Removal of the expression/ purification tags from the recombinant proteins with C3 protease occurred more efficiently than when TEV protease was used. An optimised protocol was developed that gave maximal production of our target proteins in fermenter culture at an induction temperature of 22°C. Care was taken to find a methanol feed rate that gave the highest levels of protein production without causing the accumulation of excess methanol in the culture (which is known to be toxic to the yeast). Using this protocol it was possible to make both hSI and hA2aR with a production level >10 mg of recombinant protein per litre of culture. As most MPs are colourless, target protein identification is usually performed by methods such as radioligand binding and/or Western blotting. However, these techniques can be time-consuming, use a lot of protein and do not give any information on the aggregation state of the protein in detergent solution. Previously, it has been shown that the processes of identifying and analysing membrane proteins in detergent solution can be accelerated by attaching green fluorescent protein to the C-terminus of the recombinant MP. Here, the potential of the recently described iLOV fluorescence tag for membrane protein applications was assessed. iLOV was shown to be an useful tool for optimising processes such as yeast clonal selection, protein production in fermenter culture, detergent and construct screening as well as tracking recombinant MPs through the purification process. Of note, the iLOV tag allowed a direct assessment of the stability and dispersity state of both target MPs in a range of detergents by fluorescence size exclusion chromatography (FSEC). Using this approach, it was shown that wild-type hA2aR solubilised using a combination of dodecyl-βDmaltoside (DDM) and cholesteryl-hemisuccinate (CHS) aggregated during purification on a Ni2+ column. Furthermore, it was shown that the hA2aR agonistconformationally-fixed mutant Rag23 is stable in DDM without any CHS present. Moreover, Rag23 was found to be monodisperse in a series of short-chain detergents (decyl-βD-maltoside, nonyl-βD-maltoside (NM) and β-octylglucoside) suggesting that this mutant is well-suited to structural studies. SI was remarkably robust in short chain detergents demonstrating a reasonable level of stability in the short chain detergent NM. The FSEC experiments showed that wild-type SI has considerably higher intrinsic stability than native hA2aR suggesting that membrane enzymes will prove to be more amenable to structural analysis than GPCRs. Rag23 and SI were both purified to homogeneity in a simple four-step procedure: i) Ni2+ purification, ii) cleavage with C3 protease, iii) reverse Ni2+ purification and iv) gel-filtration chromatography. A buffer/salt screen was devised that allowedthose conditions where SI had maximal thermostability in detergent-solution to be identified. SI was found to have greatest stability in sodium phosphate buffer at acidic pH. Using this information, it was possible to purify monodisperse SI in DM suggesting that this protein may make an excellent candidate for structural studies too. Crystallisation trials with SI were performed using the commercially available sparse matrix screen MemSys/MemStart. In addition, a lipidic-sponge phase sparse-matrix crystallisation screen that was developed in collaboration with Prof. Richard Neutze (University of Chalmers, Sweden) was tested using SI. Cholesterol could be incorporated into all of the sponges that make up the screen upto a concentration of 10%. (This is important as the activity of many mammalian membrane proteins is cholesterol-dependent). To date, no diffracting crystals of SI have been obtained with either the conventional or lipidic-sponge phase crystallisation approaches. In short, a series of novel technologies/methodologies have been developed that will act as a platform for future efforts to solve the structures of a wide-range of human membrane proteins

Membrane protein structure determination and characterisation by solution and solid-state nmr

© 2020 by the authors. Licensee MDPI, Basel, Switzerland. Biological membranes define the interface of life and its basic unit, the cell. Membrane proteins play key roles in membrane functions, yet their structure and mechanisms remain poorly understood. Breakthroughs in crystallography and electron microscopy have invigorated structural analysis while failing to characterise key functional interactions with lipids, small molecules and membrane modulators, as well as their conformational polymorphism and dynamics. NMR is uniquely suited to resolving atomic environments within complex molecular assemblies and reporting on membrane organisation, protein structure, lipid and polysaccharide composition, conformational variations and molecular interactions. The main challenge in membrane protein studies at the atomic level remains the need for a membrane environment to support their fold. NMR studies in membrane mimetics and membranes of increasing complexity offer close to native environments for structural and molecular studies of membrane proteins. Solution NMR inherits high resolution from small molecule analysis, providing insights from detergent solubilised proteins and small molecular assemblies. Solid-state NMR achieves high resolution in membrane samples through fast sample spinning or sample alignment. Recent developments in dynamic nuclear polarisation NMR allow signal enhancement by orders of magnitude opening new opportunities for expanding the applications of NMR to studies of native membranes and whole cells

RF Sensors for Monitoring the Electrical Properties of Electrolyte Solutions

A radio frequency electrical sensor for the qualitative analysis and monitoring of the electrical properties of electrolyte solutions is designed, simulated and experimentally tested in this research. This work is based on the use of planar inductors for the detection of a change in the concentration of ionic species in a liquid sample. At first a literature review on the physical chemistry of electrolyte solutions is provided. This will include topics on the conductivity and relaxation properties of electrolytes. This will be followed by a look at dielectric spectroscopy sensors, electrochemical sensors and inductive sensing devices. The principles of electrodynamics and constitutive equations are discussed. Based on these, the principles of operation of the RF electrical sensors are analysed. Two methods of theoretical analysis of such structures are investigated. These methods are; analytical solution and finite element computation method. The former offers greater insight into the system’s parameters whilst the latter offers more information regarding the whole system. Given the qualitative nature of the sensors under investigation and finite element approach was selected and used in latter chapters to obtain grater insight into the behaviour of the system. Planar inductor coils are designed on an FR4 substrate and packaged using PDMS to be used as sensors in the monitoring of electrical properties of electrolytes. Experimental results on these sensors are provided and discussed. The effects of solvent, acidity of the solutions, and environmental factors on the behaviour of the sensors shall be discussed. This is followed by finite element simulations of the sensor and the effect of various parameters on the overall behaviour of the sensing device. A transformer apparatus is also constructed and experimental data are provided for it. An electrolyte is placed on one of the coils of the transformer and scattering parameters are looked upon for data analysis. The results obtained using the FE method, is then used to obtain further information about the principle of operation of the device