Time efficient detection of protein–ligand interactions with the polarization optimized PO-WaterLOGSY NMR experiment

The identification of compounds that bind to a protein of interest is of central importance in contemporary drug research. For screening of compound libraries, NMR techniques are widely used, in particular the Water-Ligand Observed via Gradient SpectroscopY (WaterLOGSY) experiment. Here we present an optimized experiment, the polarization optimized WaterLOGSY (PO-WaterLOGSY). Based on a water flip-back strategy in conjunction with model calculations and numerical simulations, the PO-WaterLOGSY is optimized for water polarization recovery. Compared to a standard setup with the conventional WaterLOGSY, time consuming relaxation delays have been considerably shortened and can even be omitted through this approach. Furthermore, the robustness of the pulse sequence in an industrial setup was increased by the use of hard pulse trains for selective water excitation and water suppression. The PO-WaterLOGSY thus yields increased time efficiency by factor of 3–5 when compared with previously published schemes. These time savings have a substantial impact in drug discovery, since significantly larger compound libraries can be tested in screening campaigns. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

13C–13C NOESY spectra of a 480 kDa protein: solution NMR of ferritin

Molecular size has limited solution NMR analyses of proteins. We report ¹³C–¹³C NOESY experiments on a 480 kDa protein, the multi-subunit ferritin nanocage with gated pores. By exploiting ¹³C-resonance-specific chemical shifts and spin diffusion effects, we identified 75% of the amino acids, with intraresidue C–C connectivities between nuclei separated by 1–4 bonds. These results show the potential of ¹³C–¹³C NOESY for solution studies of molecular assemblies >100 kDa.     

Heterodimerization of the Entamoeba histolytica EhCPADH virulence complex through molecular dynamics and protein–protein docking

EhCPADH is a protein complex involved in the virulence of Entamoeba histolytica, the protozoan responsible for human amebiasis. It is formed by the EhCP112 cysteine protease and the EhADH adhesin. To explore the molecular basis of the complex formation, three-dimensional models were built for both proteins and molecular dynamics simulations (MDS) and docking calculations were performed. Results predicted that the pEhCP112 proenzyme and the mEhCP112 mature enzyme were globular and peripheral membrane proteins. Interestingly, in pEhCP112, the propeptide appeared hiding the catalytic site (C167, H329, N348); while in mEhCP112, this site was exposed and its residues were found structurally closer than in pEhCP112. EhADH emerged as an extended peripheral membrane protein with high fluctuation in Bro1 and V shape domains. 500 ns-long MDS and protein–protein docking predictions evidenced different heterodimeric complexes with the lowest free energy. pEhCP112 interacted with EhADH by the propeptide and C-terminal regions and mEhCP112 by the C-terminal through hydrogen bonds. In contrast, EhADH bound to mEhCP112 by 442–479 residues, adjacent to the target cell-adherence region (480–600 residues), and by the Bro1 domain (9–349 residues). Calculations of the effective binding free energy and per residue free energy decomposition showed that EhADH binds to mEhCP112 with a higher binding energy than to pEhCP112, mainly through van der Waals interactions and the nonpolar part of solvation energy. The EhADH and EhCP112 structural relationship was validated in trophozoites by immunofluorescence, TEM, and immunoprecipitation assays. Experimental findings fair agreed with in silico results.     

Over-producing soluble protein complex and validating protein–protein interaction through a new bacterial co-expression system

Many proteins exert their functions through a protein complex and protein–protein interactions. However, the study of these types of interactions is complicated when dealing with toxic or hydrophobic proteins. It is difficult to use the popular Escherichia coli host for their expression, as these proteins in all likelihood require a critical partner protein to ensure their proper folding and stability. In the present study, we have developed a novel co-expression vector, pHEX, which is compatible with, and thus can be partnered with, many commercially available E. coli vectors, such as pET, pGEX and pMAL. The pHEX contains the p15A origin of replication and a T7 promoter, which can over-produce a His-tagged recombinant protein. The new co-expression system was demonstrated to efficiently co-produce and co-purify heterodimeric protein complexes, for example PE25/PPE41 (Rv2430c/Rv2431c) and ESAT6/CFP10 (Rv3874/Rv3875), from the human pathogen Mycobacterium tuberculosis H37Rv. Furthermore, the system was also effectively used to characterize protein–protein interactions through convenient affinity tags. Using an in vivo pull-down assay, for the first time we have confirmed the presence of three pairs of PE/PPE-related novel protein interactions in this pathogen. In summary, a convenient and efficient co-expression vector system has been successfully developed. The new system should be applicable to any protein complex or any protein–protein interaction of interest in a wide range of biological organisms.     

Structure of a protein–detergent complex: the balance between detergent cohesion and binding

Despite the major interest in membrane proteins at functional, genomic, and therapeutic levels, their biochemical and structural study remains challenging, as they require, among other things, solubilization in detergent micelles. The complexity of this task derives from the dependence of membrane protein structure on their anisotropic environment, influenced by a delicate balance between many different physicochemical properties. To study such properties in a small protein–detergent complex, we used fluorescence measurements and molecular dynamics (MD) simulations on the transmembrane part of glycophorin A (GpAtm) solubilized in micelles of dihexanoylphosphatidylcholine (DHPC) detergent. Fluorescence measurements show that DHPC has limited ability to solubilize the peptide, while MD provides a possible molecular explanation for this. We observe that the detergent molecules are balanced between two different types of interactions: cohesive interactions between detergent molecules that hold the micelle together, and adhesive interactions with the peptide. While the cohesive interactions are detergent mediated, the adhesion to the peptide depends on the specific interactions between the hydrophobic parts of the detergent and the topography of the peptide dictated by the amino acids. The balance between these two parameters results in a certain frustration of the system and rather slow equilibration. These observations suggest how molecular properties of detergents could influence membrane protein stabilization and solubilization.     

Design and synthesis of a novel anthracene-based fluorescent probe through the application of the Suzuki–Miyaura cross-coupling reaction

We report on a simple synthetic route to a novel anthracene-based bis-armed amino acid derivative as a useful fluorescent probe. Various photophysical studies of this amino acid derivative are also described. Here, Suzuki-Miyaura cross-coupling reaction has been used as a key step for carbon-carbon bond formation.     

Synthetic analogues of the histidine–chlorophyll complex: a NMR study to mimic structural features of the photosynthetic reaction center and the light-harvesting complex

Mg(II)–porphyrin–ligand and (bacterio)chlorophyl–ligand coordination interactions have been studied by solution and solid-state MAS NMR spectroscopy. ¹H, ¹³C and ¹⁵N coordination shifts due to ring currents, electronic perturbations and structural effects are resolved for imidazole (Im) and 1-methylimidazole (1-MeIm) coordinated axially to Mg(II)-OEP and (B)Chl a. As a consequence of a single axial coordination of Im or 1-MeIm to the Mg(II) ion, 0.9–5.2 ppm ¹H, 0.2–5.5 ppm ¹³C and 2.1–27.2 ppm ¹⁵N coordination shifts were measured for selectively labeled [1,3-¹⁵N]-Im, [1,3-¹⁵N,2-¹³C]-Im and [1,3-¹⁵N,1,2-¹³C]-1-MeIm. The coordination shifts depend on the distance of the nuclei to the porphyrin plane and the perturbation of the electronic structure. The signal intensities in the ¹H NMR spectrum reveal a five-coordinated complex, and the isotropic chemical shift analysis shows a close analogy with the electronic structure of the BChl a–histidine in natural light harvesting 2 complexes. The line broadening of the ligand responses support the complementary IR data and provide evidence for a dynamic coordination bond in the complex.Abbreviations (B)Chl a (bacterio)chlorophyll a - HMBC heteronuclear multiple bond correlation - Im imidazole - LH light-harvesting - 1-MeIm 1-methylimidazole - Mg(II)-Por Mg(II)-porphyrin macrocycle - OEP 2,3,7,8,12,13,17,18-octaethylporphyrin     

NMR assignment of the apo-form of a Desulfovibrio gigas protein containing a novel Mo–Cu cluster

We report the 98% assignment of the apo-form of an orange protein, containing a novel Mo–Cu cluster isolated from Desulfovibrio gigas. This protein presents a region where backbone amide protons exchange fast with bulk solvent becoming undetectable. These residues were assigned using ¹³C-detection experiments.     

Binding of small molecules at interface of protein–protein complex – A newer approach to rational drug design

Protein–protein interaction is a vital process which drives many important physiological processes in the cell and has also been implicated in several diseases. Though the protein–protein interaction network is quite complex but understanding its interacting partners using both in silico as well as molecular biology techniques can provide better insights for targeting such interactions. Targeting protein–protein interaction with small molecules is a challenging task because of druggability issues. Nevertheless, several studies on the kinetics as well as thermodynamic properties of protein–protein interactions have immensely contributed toward better understanding of the affinity of these complexes. But, more recent studies on hot spots and interface residues have opened up new avenues in the drug discovery process. This approach has been used in the design of hot spot based modulators targeting protein–protein interaction with the objective of normalizing such interactions.     

Advances in the study of protein–DNA interaction

Protein-DNA interaction plays an important role in many biological processes. The classical methods and the novel technologies advanced have been developed for the interaction of protein-DNA. Recent developments of these methods and research achievements have been reviewed in this paper.     

TROSY NMR with a 52 kDa sugar transport protein and the binding of a small-molecule inhibitor

Using the sugar transport protein, GalP, from Escherichia coli, which is a homologue of human GLUT transporters, we have overcome the challenges for achieving high-resolution [¹⁵N-¹H]- and [¹³C-¹H]-methyl-TROSY NMR spectra with a 52?kDa membrane protein that putatively has 12 transmembrane-spanning α-helices and used the spectra to detect inhibitor binding. The protein reconstituted in DDM detergent micelles retained structural and functional integrity for at least 48?h at a temperature of 25?°C as demonstrated by circular dichroism spectroscopy and fluorescence measurements of ligand binding, respectively. Selective labelling of tryptophan residues reproducibly gave 12 resolved signals for tryptophan ¹⁵N backbone positions and also resolved signals for ¹⁵N side-chain positions. For improved sensitivity isoleucine, leucine and valine (ILV) methyl-labelled protein was prepared, which produced unexpectedly well resolved [¹³C-¹H]-methyl-TROSY spectra showing clear signals for the majority of methyl groups. The GalP/GLUT inhibitor forskolin was added to the ILV-labelled sample inducing a pronounced chemical shift change in one Ile residue and more subtle changes in other methyl groups. This work demonstrates that high-resolution TROSY NMR spectra can be achieved with large complex α-helical membrane proteins without the use of elevated temperatures. This is a prerequisite to applying further labelling strategies and NMR experiments for measurement of dynamics, structure elucidation and use of the spectra to screen ligand binding.     

Optimisation of overlap extension PCR-based mutagenesis of a GC-rich DNA template: application to the human α2C-adrenoceptor cDNA

PCR-based overlap extension mutagenesis was applied to introduce a Thr³⁸¹ to Lys mutation in the _2C-adrenoceptor (_2C AR) coding sequence. This cDNA contains 71% G+C nucleotides and conventional PCR procedures were inefficient in generating a corresponding amplification product. Only the combined use of a pre-PCR denaturation step at 100 °C followed by quick chilling on ice and the addition of 1 M of a commercial GC Melt reagent and 5% (v/v) dimethylsulphoxide with the Advantage GC cDNA PCR kit yielded efficient amplification during the three successive PCR steps of the overlap extension procedure. Transient expression of the mutant Thr³⁸¹Lys _2C AR in Cos-7 cells was performed to determine the binding profile for a series of ₂ AR ligands using [³H]RX 821002.     

Structural characterization of a carbon monoxide adduct of a heme–DNA complex

Abstract  

The structure of a carbon monoxide (CO) adduct of a complex between heme and a parallel G-quadruplex DNA formed from a single repeat sequence of the human telomere, d(TTAGGG), has been characterized using ¹H and ¹³C NMR spectroscopy and density function theory calculations. The study revealed that the heme binds to the 3′-terminal G-quartet of the DNA though a π–π stacking interaction between the porphyrin moiety of the heme and the G-quartet. The π–π stacking interaction between the pseudo-C ₂-symmetric heme and the C ₄-symmetric G-quartet in the complex resulted in the formation of two isomers possessing heme orientations differing by 180° rotation about the pseudo-C ₂ axis with respect to the DNA. These two slowly interconverting heme orientational isomers were formed in a ratio of approximately 1:1, reflecting that their thermodynamic stabilities are identical. Exogenous CO is coordinated to heme Fe on the side of the heme opposite the G-quartet in the complex, and the nature of the Fe–CO bond in the complex is similar to that of the Fe–CO bonds in hemoproteins. These findings provide novel insights for the design of novel DNA enzymes possessing metalloporphyrins as prosthetic groups.     

Using codon optimization, chaperone co-expression, and rational mutagenesis for production and NMR assignments of human eIF2α

Producing a well behaved sample at high concentration is one of the main hurdles when starting a new project on an interesting protein. Especially when one attempts to overexpress a eukaryotic protein in bacteria, some difficulties are encountered, such as low expression level, low solubility, or even lack of folded structure. Overexpression in prokaryotic systems is highly desirable for cost-effective production of different isotope-labeled samples needed for NMR studies. Here we describe generally applicable methods for obtaining highly concentrated protein samples efficiently. This approach was developed as we tried to produce a NMR-suitable sample of the 35 kDa human translation initiation factor eIF2 alpha, a protein that expresses poorly in E. coli and has very low solubility. First, an E. coli codon-optimized gene was synthesized on a thermal cycler, which increased the expression level by a factor of two. Second, we used co-expression of bacterial chaperone proteins, which largely increased the fraction of correctly folded protein found in the soluble phase. Third, we used rational mutagenesis guided by both the sequence alignment among homologues and the homology of one domain to a known fold for improving solubility and stability of the target protein by tenfold. Combining all these methods made it possible to produce from a one-liter preparation a 0.5 mM sample of human eIF2 alpha that showed well-resolved NMR spectra and enabled nearly complete assignment of the protein. These methods may be generally useful for studies of other eukaryotic proteins that are otherwise difficult to express and exhibit poor solubility.     

Effect of protein aggregation on the spectroscopic properties and excited state kinetics of the LHCII pigment–protein complex from green plants

Steady-state and time-resolved absorption and fluorescence spectroscopic experiments have been carried out at room and cryogenic temperatures on aggregated and unaggregated monomeric and trimeric LHCII complexes isolated from spinach chloroplasts. Protein aggregation has been hypothesized to be one of the mechanistic factors controlling the dissipation of excess photo-excited state energy of chlorophyll during the process known as nonphotochemical quenching. The data obtained from the present experiments reveal the role of protein aggregation on the spectroscopic properties and dynamics of energy transfer and excited state deactivation of the protein-bound chlorophyll and carotenoid pigments.     

Probing mammalian spermine oxidase enzyme–substrate complex through molecular modeling,site-directed mutagenesis and biochemical characterization

Spermine oxidase (SMO) and acetylpolyamine oxidase (APAO) are FAD-dependent enzymes that are involved in the highly regulated pathways of polyamine biosynthesis and degradation. Polyamine content is strictly related to cell growth, and dysfunctions in polyamine metabolism have been linked with cancer. Specific inhibitors of SMO and APAO would allow analyzing the precise role of these enzymes in polyamine metabolism and related pathologies. However, none of the available polyamine oxidase inhibitors displays the desired characteristics of selective affinity and specificity. In addition, repeated efforts to obtain structural details at the atomic level on these two enzymes have all failed. In the present study, in an effort to better understand structure–function relationships, SMO enzyme–substrate complex has been probed through a combination of molecular modeling, site-directed mutagenesis and biochemical studies. Results obtained indicate that SMO binds spermine in a similar conformation as that observed in the yeast polyamine oxidase FMS1-spermine complex and demonstrate a major role for residues His82 and Lys367 in substrate binding and catalysis. In addition, the SMO enzyme–substrate complex highlights the presence of an active site pocket with highly polar characteristics, which may explain the different substrate specificity of SMO with respect to APAO and provide the basis for the design of specific inhibitors for SMO and APAO.     

Changes in the protein and activity levels of the plastid NADH–plastoquinone–oxidoreductase complex during fruit development

Plastids contain an NADH dehydrogenase complex (Ndh complex) homologous to the mitochondrial complex I (EC 1.6.5.3). In this work, we have analysed the changes in the Ndh complex during ripening of pepper (Capsicum annum L., cv. Maor) and tomato (Lycopersicon esculentum Mill., cv. Marglobe) fruits. The Ndh complex was mainly present in the outer pericarp of tomato fruits, whereas it was evenly distributed in the pericarp of pepper. In both kinds of fruit we observed a decrease in the total amount of Ndh complex from the green to the red stage of development. This decrease corresponds to parallel decreases in the content and activity of the complex in plastids during the transition from chloroplasts to chromoplasts. Levels of plastidial quinol peroxidase activity were also higher during the first stages of tomato fruit development than during the latter stages of ripening. However, when referred to total plastid protein, the amount and activity of the Ndh complex in chloroplasts isolated from green fruits was higher than in chloroplasts isolated from leaves. These results strongly suggest that function of the Ndh complex, probably related to a plastidial electron transport chain, can be important during the first stages of fruit development.