A combined theoretical and experimental study to improve the thermal stability of recombinant D-lactate dehydrogenase immobilized on a novel superparamagnetic Fe3O4NPs@metal–organic framework

Lactate dehydrogenase (LDH) is an enzyme that catalyzes the reduction of nicotinamide adenine dinucleotide (NADH) and pyruvate to nicotinamide adenine dinucleotide (NAD⁺) and D-lactate in the final step of anaerobic glycolysis. This enzyme belongs to the family of oxidoreductases. Humans possess two isoforms of LDH enzyme: NAD-dependent L-lactate dehydrogenase (L-LDH) and NAD-dependent D-lactate dehydrogenase (D-LDH). D-LDH is released during tissue damage, and is a sign of diseases such as kidney stones, heart failure, and some types of cancers and appendicitis. Accordingly, the design and construction of biosensors for the determination of lactate levels are important. The thermal sensitivity of D-LDH and low protein production in the host bacteria limit the use of this protein in certain applications. To solve these problems, two solutions were used in this study. First, the codon-optimized 1008 bp D-LDH gene fused with a histidine tag was cloned at the NcoI/XhoI sites and expressed in E. coli BL21. Second, a new metal–organic framework (Fe₃O₄NPs@Ni-MOF) was synthesized and used for immobilization and stabilization of D-LDH. Fe₃O₄NPs@Ni-MOF core-shell nanocomposites were characterized by Fourier transform infrared spectroscopy, vibrating sample magnetometer, scanning electron microscopy, X-ray diffraction, and the Brunauer–Emmett–Teller method. In comparison with the free enzyme, the immobilized enzyme presented better stability at high temperatures. The immobilization of the enzyme could be useful because most reactions happen at high temperatures in industry. To examine the effect of Fe₃O₄NPs@Ni-MOF on the adsorption and conformation of D-LDH at the atomistic level, a molecular dynamics simulation was carried out. Our study showed that the interaction between Fe₃O₄NPs@Ni-MOF and D-LDH involved van der Waals interactions, hydrophobic interaction energies, cation–π interaction between the Ni ions of the MOF with the enzyme residues and also, the hydrogen bond interactions between enzyme and heteroatoms in the MOF. Root mean square fluctuation and secondary structure analysis showed that Fe₃O₄NPs@Ni-MOF protected the conformation of the enzyme.     

Probing Membrane Protein Insertion into Lipid Bilayers by Solid-State NMR

Determination of the environment surrounding a protein is often key to understanding its function and can also be used to infer the structural properties of the protein. By using proton-detected solid-state NMR, we show that reduced spin diffusion within the protein under conditions of fast magic-angle spinning, high magnetic field, and sample deuteration allows the efficient measurement of site-specific exposure to mobile water and lipids. We demonstrate this site specificity on two membrane proteins, the human voltage dependent anion channel, and the alkane transporter AlkL from Pseudomonas putida. Transfer from lipids is observed selectively in the membrane spanning region, and an average lipid-protein transfer rate of 6 s⁻¹ was determined for residues protected from exchange. Transfer within the protein, as tracked in the ¹⁵N-¹H 2D plane, was estimated from initial rates and found to be in a similar range of about 8 to 15 s⁻¹ for several resolved residues, explaining the site specificity.     

Aromatic Cluster Sensor of Protein Folding: Near‐UV Electronic Circular Dichroism Bands Assigned to Fold Compactness

Both far‐ and near‐UV electronic circular dichroism (ECD) spectra have bands sensitive to thermal unfolding of Trp and Tyr residues containing proteins. Beside spectral changes at 222 nm reporting secondary structural variations (far‐UV range), L_b bands (near‐UV range) are applicable as 3D‐fold sensors of protein's core structure. In this study we show that both L_b(Tyr) and L_b(Trp) ECD bands could be used as sensors of fold compactness. ECD is a relative method and thus requires NMR referencing and cross‐validation, also provided here. The ensemble of 204 ECD spectra of Trp‐cage miniproteins is analysed as a training set for “calibrating” Trp?Tyr folded systems of known NMR structure. While in the far‐UV ECD spectra changes are linear as a function of the temperature, near‐UV ECD data indicate a non‐linear and thus, cooperative unfolding mechanism of these proteins. Ensemble of ECD spectra deconvoluted gives both conformational weights and insight to a protein folding?unfolding mechanism. We found that the L_b²⁹³ band is reporting on the 3D‐structure compactness. In addition, the pure near‐UV ECD spectrum of the unfolded state is described here for the first time. Thus, ECD folding information now validated can be applied with confidence in a large thermal window (5≤T≤85 °C) compared to NMR for studying the unfolding of Trp?Tyr residue pairs. In conclusion, folding propensities of important proteins (RNA polymerase II, ubiquitin protein ligase, tryptase‐inhibitor etc.) can now be analysed with higher confidence.     

Solid‐state NMR Study of the YadA Membrane‐Anchor Domain in the Bacterial Outer Membrane

MAS‐NMR was used to study the structure and dynamics at ambient temperatures of the membrane‐anchor domain of YadA (YadA‐M) in a pellet of the outer membrane of E. coli in which it was expressed. YadA is an adhesin from the pathogen Yersinia enterocolitica that is involved in interactions with the host cell, and it is a model protein for studying the autotransport process. Existing assignments were sucessfully transferred to a large part of the YadA‐M protein in the E. coli lipid environment by using ¹³C‐¹³C DARR and PDSD spectra at different mixing times. The chemical shifts in most regions of YadA‐M are unchanged relative to those in microcrystalline YadA‐M preparations from which a structure has previously been solved, including the ASSA region that is proposed to be involved in transition‐state hairpin formation for transport of the soluble domain. Comparisons of the dynamics between the microcrystalline and membrane‐embedded samples indicate greater flexibility of the ASSA region in the outer‐membrane preparation at physiological temperatures. This study will pave the way towards MAS‐NMR structure determination of membrane proteins, and a better understanding of functionally important dynamic residues in native membrane environments.     

Polyoxometalates as a Novel Class of Artificial Proteases: Selective Hydrolysis of Lysozyme under Physiological pH and Temperature Promoted by a Cerium(IV) Keggin‐Type Polyoxometalate

Hen‐egg‐white lysozyme (HEWL) is specifically cleaved at the Trp28–Val29 and Asn44–Arg45 peptide bonds in the presence of a Keggin‐type [Ce(α‐PW₁₁O₃₉)₂]^10? polyoxometalate (POM; 1 ) at pH 7.4 and 37 °C. The reactivity of 1 towards a range of dipeptides was also examined and the calculated reaction rates were comparable to those observed for the hydrolysis of HEWL. Experiments with α‐lactalbumin (α‐LA), a protein that is structurally highly homologous to HEWL but has a different surface potential, showed no evidence of hydrolysis, which indicates the importance of electrostatic interactions between 1 and the protein surface for the hydrolytic reaction to occur. A combination of spectroscopic techniques was used to reveal the molecular interactions between HEWL and 1 that lead to hydrolysis. NMR spectroscopy titration experiments showed that on protein addition the intensity of the ³¹P NMR signal of 1 gradually decreased due to the formation of a large protein/polyoxometalate complex and completely disappeared when the HEWL/ 1 ratio reached 1:2. Circular dichroism (CD) measurements of HEWL indicate that addition of 1 results in a clear decrease in the signal at λ=208 nm, which is attributed to changes in the α‐helical content of the protein. ¹⁵N–¹H heteronuclear single quantum coherence (HSQC) NMR measurements of HEWL in the presence of 1 reveal that the interaction is mainly observed for residues that are located in close proximity to the first site in the α‐helical part of the structure (Trp28–Val29). The less pronounced NMR spectroscopic shifts around the second cleavage site (Asn44–Arg45), which is found in the β‐strand region of the protein, might be caused by weaker metal‐directed binding, compared with strong POM‐directed binding at the first site.     

19F NMR Spectroscopy as a Probe of Cytoplasmic Viscosity and Weak Protein Interactions in Living Cells

Protein mobility in living cells is vital for cell function. Both cytosolic viscosity and weak protein–protein interactions affect mobility, but examining viscosity and weak interaction effects is challenging. Herein, we demonstrate the use of ¹⁹F NMR spectroscopy to measure cytoplasmic viscosity and to characterize nonspecific protein–protein interactions in living Escherichia coli cells. The origins of resonance broadening in Escherichia coli cells were also investigated. We found that sample inhomogeneity has a negligible effect on resonance broadening, the cytoplasmic viscosity is only about 2–3 times that of water, and ubiquitous transient weak protein–protein interactions in the cytosol play a significant role in governing the detection of proteins by using in‐cell NMR spectroscopy.     

A Minimal Membrane Metal Transport System: Dynamics and Energetics of mer Proteins

The mer operon in bacteria encodes a set of proteins and enzymes that impart resistance to environmental mercury toxicity by importing Hg²⁺ and reducing it to volatile Hg(0). Because the reduction occurs in the cytoplasm, mercuric ions must first be transported across the cytoplasmic membrane by one of a few known transporters. MerF is the smallest of these, containing only two transmembrane helices and two pairs of vicinal cysteines that coordinate mercuric ions. In this work, we use molecular dynamics simulations to characterize the dynamics of MerF in its apo and Hg²⁺-bound states. We find that the apo state positions one of the cysteine pairs closer to the periplasmic side of the membrane, while in the bound state the same pair approaches the cytoplasmic side. This finding is consistent with the functional requirement of accepting Hg²⁺ from the periplasmic space, sequestering it on acceptance, and transferring it to the cytoplasm. Conformational changes in the TM helices facilitate the functional interaction of the two cysteine pairs. Free-energy calculations provide a barrier of 16 kcal/mol for the association of the periplasmic Hg²⁺-bound protein MerP with MerF and 7 kcal/mol for the subsequent association of MerF's two cysteine pairs. Despite the significant conformational changes required to move the binding site across the membrane, coarse-grained simulations of multiple copies of MerF support the expectation that it functions as a monomer. Our results demonstrate how conformational changes and binding thermodynamics could lead to such a small membrane protein acting as an ion transporter. Published 2019. This article is a U.S. Government work and is in the public domain in the USA.     

Observation of CH⋅⋅⋅π Interactions between Methyl and Carbonyl Groups in Proteins

Protein structure and function is dependent on myriad noncovalent interactions. Direct detection and characterization of these weak interactions in large biomolecules, such as proteins, is experimentally challenging. Herein, we report the first observation and measurement of long‐range “through‐space” scalar couplings between methyl and backbone carbonyl groups in proteins. These J couplings are indicative of the presence of noncovalent C−H⋅⋅⋅π hydrogen‐bond‐like interactions involving the amide π network. Experimentally detected scalar couplings were corroborated by a natural bond orbital analysis, which revealed the orbital nature of the interaction and the origins of the through‐space J couplings. The experimental observation of this type of CH⋅⋅⋅π interaction adds a new dimension to the study of protein structure, function, and dynamics by NMR spectroscopy.     

Insights into Intramolecular Trp and His Side‐Chain Orientation and Stereospecific π Interactions Surrounding Metal Centers: An Investigation Using Protein Metal‐Site Mimicry in Solution

Metal‐binding scaffolds incorporating a Trp/His‐paired epitope are instrumental in giving novel insights into the physicochemical basis of functional and mechanistic versatility conferred by the Trp–His interplay at a metal site. Herein, by coupling biometal site mimicry and ¹H and ¹³C NMR spectroscopy experiments, modular constructs EDTA‐(L ‐Trp, L ‐His) (EWH; EDTA=ethylenediamino tetraacetic acid) and DTPA‐(L ‐Trp, L ‐His) (DWH; DTPA=diethylenetriamino pentaacetic acid) were employed to dissect the static and transient physicochemical properties of hydrophobic/hydrophilic aromatic interactive modes surrounding biometal centers. The binding feature and identities of the stoichiometric metal‐bound complexes in solution were investigated by using ¹H and ¹³C NMR spectroscopy, which facilitated a cross‐validation of the carboxylate, amide oxygen, and tertiary amino groups as the primary ligands and indole as the secondary ligand, with the imidazole (Im) N3 nitrogen being weakly bound to metals such as Ca²⁺ owing to a multivalency effect. Surrounding the metal centers, the stereospecific orientation of aromatic rings in the diastereoisomerism is interpreted with the Ca²⁺–EWH complex. With respect to perturbed Trp side‐chain rotamer heterogeneity, drastically restricted Trp side‐chain flexibility and thus a dynamically constrained rotamer interconversion due to π interactions is evident from the site‐selective ¹³C NMR spectroscopic signal broadening of the Trp indolyl C3 atom. Furthermore, effects of Trp side‐chain fluctuation on indole/Im orientation were the subject of a 2D NMR spectroscopy study by using the Ca²⁺‐bound state; a C? H2(indolyl)/C? H5(Im⁺) connectivity observed in the NOESY spectra captured direct evidence that the N? H1 of the Ca²⁺–Im⁺ unit interacted with the pyrrole ring of the indole unit in Ca²⁺‐bound EWH but not in DWH, which is assignable to a moderately static, anomalous, T‐shaped, interplanar π⁺–π stacking alignment. Nevertheless, a comparative ¹³C NMR spectroscopy study of the two homologous scaffolds revealed that the overall response of the indole unit arises predominantly from global attractions between the indole ring and the entire positively charged first coordination sphere. The study thus demonstrates the coordination‐sphere/geometry dependence of the Trp/His side‐chain interplay, and established that π interactions allow ¹³C NMR spectroscopy to offer a new window for investigating Trp rotamer heterogeneity near metal‐binding centers.     

Retinal Conformation and Dynamics in Activation of Rhodopsin Illuminated by Solid‐state 2H NMR Spectroscopy†

Solid‐state NMR spectroscopy gives a powerful avenue for investigating G protein‐coupled receptors and other integral membrane proteins in a native‐like environment. This article reviews the use of solid‐state ²H NMR to study the retinal cofactor of rhodopsin in the dark state as well as the meta I and meta II photointermediates. Site‐specific ²H NMR labels have been introduced into three regions (methyl groups) of retinal that are crucially important for the photochemical function of rhodopsin. Despite its phenomenal stability ²H NMR spectroscopy indicates retinal undergoes rapid fluctuations within the protein binding cavity. The spectral lineshapes reveal the methyl groups spin rapidly about their three‐fold (C₃) axes with an order parameter for the off‐axial motion of For the dark state, the ²H NMR structure of 11‐cis‐retinal manifests torsional twisting of both the polyene chain and the β‐ionone ring due to steric interactions of the ligand and the protein. Retinal is accommodated within the rhodopsin binding pocket with a negative pretwist about the C11=C12 double bond. Conformational distortion explains its rapid photochemistry and reveals the trajectory of the 11‐cis to trans isomerization. In addition, ²H NMR has been applied to study the retinylidene dynamics in the dark and light‐activated states. Upon isomerization there are drastic changes in the mobility of all three methyl groups. The relaxation data support an activation mechanism whereby the β‐ionone ring of retinal stays in nearly the same environment, without a large displacement of the ligand. Interactions of the β‐ionone ring and the retinylidene Schiff base with the protein transmit the force of the retinal isomerization. Solid‐state ²H NMR thus provides information about the flow of energy that triggers changes in hydrogen‐bonding networks and helix movements in the activation mechanism of the photoreceptor.     

α-Synuclein as a Target for Metallo-Anti-Neurodegenerative Agents

The unique thermodynamic and kinetic coordination chemistry of ruthenium allows it to modulate key adverse aggregation and membrane interactions of α-synuclein (α-syn) associated with Parkinson's disease. We show that the low-toxic Ru^III complex trans-[ImH][RuCl₄(Me₂SO)(Im)] (NAMI-A) has dual inhibitory effects on both aggregation and membrane interactions of α-syn with submicromolar affinity, and disassembles pre-formed fibrils. NAMI-A abolishes the cytotoxicity of α-syn towards neuronal cells and mitigates neurodegeneration and motor impairments in a rat model of Parkinson's. Multinuclear NMR and MS analyses show that NAMI-A binds to residues involved in protein aggregation and membrane binding. NMR studies reveal the key steps in pro-drug activation and the effect of activated NAMI-A species on protein folding. Our findings provide a new basis for designing ruthenium complexes which could mitigate α-syn-induced Parkinson's pathology differently from organic agents.     

Self‐Assembly Behaviors of a Penta‐Phenylene Maltoside and Its Application for Membrane Protein Study

We prepared an amphiphile with a penta‐phenylene lipophilic group and a branched trimaltoside head group. This new agent, designated penta‐phenylene maltoside (PPM), showed a marked tendency to self‐assembly into micelles via strong aromatic–aromatic interactions in aqueous media, as evidenced by ¹H NMR spectroscopy and fluorescence studies. When utilized for membrane protein studies, this new agent was superior to DDM, a gold standard conventional detergent, in stabilizing multiple proteins long term. The ability of this agent to form aromatic–aromatic interactions is likely responsible for enhanced protein stabilization when associated with a target membrane protein.     

Characterization of a Novel Cytochrome Involved in Geobacter sulfurreducens’ Electron Harvesting Pathways

Electron harvesting bacteria are key targets to develop microbial electrosynthesis technologies, which are valid alternatives for the production of value-added compounds without utilization of fossil fuels. Geobacter sulfurreducens, that is capable of donating and accepting electrons from electrodes, is one of the most promising electroactive bacteria. Its electron transfer mechanisms to electrodes have been progressively elucidated, however the electron harvesting pathways are still poorly understood. Previous studies showed that the periplasmic cytochromes PccH and GSU2515 are overexpressed in current-consuming G. sulfurreducens biofilms. PccH was characterized, though no putative partners have been identified. In this work, GSU2515 was characterized by complementary biophysical techniques and in silico simulations using the AlphaFold neural network. GSU2515 is a low-spin monoheme cytochrome with a disordered N-terminal region and an α-helical C-terminal domain harboring the heme group. The cytochrome undergoes a redox-linked heme axial ligand switch, with Met⁹¹ and His⁹⁴ as distal axial ligands in the reduced and oxidized states, respectively. The reduction potential of the cytochrome is negative and modulated by the pH in the physiological range: −78 mV at pH 6 and −113 mV at pH 7. Such pH-dependence coupled to the redox-linked switch of the axial ligand allows the cytochrome to drive a proton-coupled electron transfer step that is crucial to confer directionality to the respiratory chain. Biomolecular interactions and electron transfer experiments indicated that GSU2515 and PccH form a redox complex. Overall, the data obtained highlight for the first time how periplasmic proteins bridge the electron transfer between the outer and inner membrane in the electron harvesting pathways of G. sulfurreducens.     

Chiral α-Amino Acid-Based NMR Solvating Agents

Four new chiral α-(nonafluoro-tert-butoxy)carboxylic acids were synthesized from naturally occurring α-amino acids (alanine, valine, leucine and isoleucine, respectively), and tested in ¹H- and ¹⁹F-NMR experiments as chiral NMR shift reagents. The NMR studies were carried out at room temperature, using CDCl₃ and C₆D₆ as solvents, and (RS)-α-phenylethylamine and (RS)-α-(1-naphthyl)ethylamine as racemic model compounds. To demonstrate the applicability of the reagents, the racemic drugs ketamine and prasugrel were also tested.     

Noncovalent Tagging Proteins with Paramagnetic Lanthanide Complexes for Protein Study

The site‐specific labeling of proteins with paramagnetic lanthanides offers unique opportunities for NMR spectroscopic analysis in structural biology. Herein, we report an interesting way of obtaining paramagnetic structural restraints by employing noncovalent interaction between a lanthanide metal complex, [Ln(L)₃]^n? (L=derivative of dipicolinic acid, DPA), and a protein. These complexes formed by lanthanides and DPA derivatives, which have different substitution patterns on the DPA derivatives, produce diverse thermodynamic and paramagnetic properties when interacting with proteins. The binding affinity of [Ln(L)₃]^n? with proteins, as well as the determined paramagnetic tensor, are tunable by changing the substituents on the ligands. These noncovalent interactions between [Ln(L)₃]^n? and proteins offer great opportunities in the tagging of proteins with paramagnetic lanthanides. We expect that this method will be useful for obtaining multiple angles and distance restraints of proteins in structural biology.     

Labeling Strategy and Signal Broadening Mechanism of Protein NMR Spectroscopy in Xenopus laevis Oocytes

We used Xenopus laevis oocytes, a paradigm for a variety of biological studies, as a eukaryotic model system for in‐cell protein NMR spectroscopy. The small globular protein GB1 was one of the first studied in Xenopus oocytes, but there have been few reports since then of high‐resolution spectra in oocytes. The scarcity of data is at least partly due to the lack of good labeling strategies and the paucity of information on resonance broadening mechanisms. Here, we systematically evaluate isotope enrichment and labeling methods in oocytes injected with five different proteins with molecular masses of 6 to 54 kDa. ¹⁹F labeling is more promising than ¹⁵N, ¹³C, and ²H enrichment. We also used ¹⁹F NMR spectroscopy to quantify the contribution of viscosity, weak interactions, and sample inhomogeneity to resonance broadening in cells. We found that the viscosity in oocytes is only about 1.2 times that of water, and that inhomogeneous broadening is a major factor in determining line width in these cells.     

Tryptophan receptors containing acridine-based thiourea

Four derivatives of acridine and acridinium compounds (L1, L2, L1H and L2H) comprised thiourea-binding sites were synthesised. The binding abilities of receptors L1, L2, L1H and L2H towards amino acids (l-Trp, l-Phe, l-Leu, l-Ala and l-Gly) were studied by ¹H NMR spectroscopy, UV–vis and fluorescence spectrophotometry. Hydrogen bonding interactions between thiourea-binding site of the ligand and the carboxylate groups in zwitterionic amino acids were found to be the main interactions driving complexation to take place. The stoichiometry of 1:1 ligand to amino acid was observed in all cases. Neutral ligands L1 and L2 showed weak binding towards all studied amino acids. The cyclic ligand L1 showed better binding ability towards tryptophan (Trp) than the acyclic ligand L2 did (K for Trp is 307 and 266 M^? 1 for L1 and L2, respectively). Interestingly, binding abilities of the protonated ligands, L1H and L2H, towards studied amino acids, especially Trp (K for Trp is 3157 and 2873 M^? 1 for L1H and L2H, respectively), were increased due to R–COO^? …H…N⁺–acridinium interactions. Calculated structures of L1H·Trp and L2H·Trp showed that the polyglycol moiety in L1H provided a hydrophobic cavity for binding Trp resulting in a stronger binding affinity of L1H over L2H.     

Reconstitution of the Cytb5–CytP450 Complex in Nanodiscs for Structural Studies using NMR Spectroscopy

Cytochrome P450s (P450s) are a superfamily of enzymes responsible for the catalysis of a wide range of substrates. Dynamic interactions between full‐length membrane‐bound P450 and its redox partner cytochrome b₅ (cytb₅) have been found to be important for the enzymatic activity of P450. However, the stability of the circa 70 kDa membrane‐bound complex in model membranes renders high‐resolution structural NMR studies particularly difficult. To overcome these challenges, reconstitution of the P450–cytb₅ complex in peptide‐based nanodiscs, containing no detergents, has been demonstrated, which are characterized by size exclusion chromatography and NMR spectroscopy. In addition, NMR experiments are used to identify the binding interface of the P450–cytb₅ complex in the nanodisc. This is the first successful demonstration of a protein–protein complex in a nanodisc using NMR structural studies and should be useful to obtain valuable structural information on membrane‐bound protein complexes.     

PI by NMR: Probing CH–π Interactions in Protein–Ligand Complexes by NMR Spectroscopy

While CH–π interactions with target proteins are crucial determinants for the affinity of arguably every drug molecule, no method exists to directly measure the strength of individual CH–π interactions in drug–protein complexes. Herein, we present a fast and reliable methodology called PI (π interactions) by NMR, which can differentiate the strength of protein–ligand CH–π interactions in solution. By combining selective amino-acid side-chain labeling with ¹H-¹³C NMR, we are able to identify specific protein protons of side-chains engaged in CH–π interactions with aromatic ring systems of a ligand, based solely on ¹H chemical-shift values of the interacting protein aromatic ring protons. The information encoded in the chemical shifts induced by such interactions serves as a proxy for the strength of each individual CH–π interaction. PI by NMR changes the paradigm by which chemists can optimize the potency of drug candidates: direct determination of individual π interactions rather than averaged measures of all interactions.