Bound conformations for ligands for G-protein coupled receptors

Summary The conformation of the C-terminus of the α-subunit of transducin, the G-protein of vision, has been determined by transfer NOE when bound to activated (MII) rhodopsin. One hundred three new NOE constraints are apparent when light is shown on a mixture of rhodopsin bilayers and the undecapeptide. Analogs of the α-peptide with covalent constraints were designed restricting the bound conformation; they stabilize MII thus supporting the deduced structure. The NMR structure of a complex of the intracellular loops of rhodopsin facilitates docking of the α-peptide and also shows proximity of residues known by mutational analysis to interact to generate the activated rhodopsin-transducin interface. This constrains the location of transmembrane helices in the structure of activated rhodopsin. Methods for the prediction of affinity have been used to estimate the relative binding constants of peptide analogs with the loop complex and show strong correlation with experimental data. Various models of the rhodopsin-transmembrane helical segments have been computationally fused with distance geometry to determine the overall model which best fits the experimental data on the rhodopsin-transducin interface.     

Bound conformations for ligands for G-protein coupled receptors

The conformation of the C-terminus of the -subunit of transducin, the G-protein of vision, has been determined by transfer NOE when bound to activated (MII) rhodopsin. One hundred three new NOE constraints are apparent when light is shown on a mixture of rhodopsin bilayers and the undecapeptide. Analogs of the -peptide with covalent constraints were designed restricting the bound conformation; they stabilize MII thus supporting the deduced structure. The NMR structure of a complex of the intracellular loops of rhodopsin facilitates docking of the -peptide and also shows proximity of residues known by mutational analysis to interact to generate the activated rhodopsin-transducin interface. This constrains the location of transmembrane helices in the structure of activated rhodopsin. Methods for the prediction of affinity have been used to estimate the relative binding constants of peptide analogs with the loop complex and show strong correlation with experimental data. Various models of the rhodopsin-transmembrane helical segments have been computationally fused with distance geometry to determine the overall model which best fits the experimental data on the rhodopsin-transducin interface.     

Calmodulin interaction with peptides from G-protein coupled receptors measured with S-Tag labeling

We have developed a quantitative assay of calmodulin (CaM) binding to S-Tag labeled peptides derived from G-protein coupled receptor (GPCR) sequences. CaM binding of peptides derived from the third intracellular loop (i3) of mu opioid receptor (MOR) was confirmed and the CaM-binding motif refined. A MORi3 peptide with a Lys > Ala substitution--shown to reduce CaM-binding of intact MOR--bound fivefold less avidly than the wild-type peptide. Screening peptides derived from i3 loops of other GPCR families confirmed 5HT1A, and identified muscarinic receptor 3, and melanocortin receptor 1, as proteins carrying CaM-binding domains. The use of S-Tag labeling can serve for rapid screening of putative CaM-binding domains in GPCRs.     

High yield production of extracellular recombinant levansucrase by Bacillus megaterium

In this study, a high yield production bioprocess with recombinant Bacillus megaterium for the production of the extracellular enzyme levansucrase (SacB) was developed. For basic optimization of culture parameters and nutrients, a recombinant B. megaterium reporter strain that produced green fluorescent protein under control of a vector-based xylose-inducible promoter was used. It enabled efficient microtiter plate-based screening via fluorescence analysis. A pH value of pH?6, 20 % of dissolved oxygen, 37 °C, and elevated levels of biotin (100 μg?L^?1) were found optimal with regard to high protein yield and reduced overflow metabolism. Among the different compounds tested, fructose and glycerol were identified as the preferred source of carbon. Subsequently, the settings were transferred to a B. megaterium strain recombinantly producing levansucrase SacB based on the plasmid-located xylose-inducible expression system. In shake flask culture under the optimized conditions, the novel strain already secreted the target enzyme in high amounts (14 U?mL^?1 on fructose and 17.2 U?mL^?1 on glycerol). This was further increased in high cell density fed-batch processes up to 55 U?mL^?1, reflecting a levansucrase concentration of 0.52 g?L^?1. This is 100-fold more than previous efforts for this enzyme in B. megaterium and more than 10-fold higher than reported values of other extracellular protein produced in this microorganism so far. The recombinant strain could also handle raw glycerol from biodiesel industry which provided the same amount and quality of the recombinant protein and suggests future implementation into existing biorefinery concepts.     

Functional membrane diffusion of G-protein coupled receptors

G-protein-coupled receptor function involves interactions between the receptor, G-proteins and effectors in the cell plasma membrane. The main biochemical processes have been individually identified but the mechanisms governing the successive protein–protein interactions of this complex multi-molecular machinery have yet to be established. We discuss advances in understanding the functional dynamics of the receptor resulting from diffusion measurements, and in the context of the plasma membrane organization. Aurélie Baker and Aude Saulière contributed equally to this work. Presented at the joint biannual meeting of the SFB-GEIMM-GRIP, Anglet France, 14–19 October, 2006.     

Signaling and regulation of G-protein coupled receptors encoded by cytomegaloviruses.

Cytomegaloviruses (CMVs) are species-specific beta-herpesviruses whose replicative success is largely due to establishment of novel mechanisms for altering the host immune response. CMV encodes 3 families of putative G-protein coupled receptors (GPCRs) likely pirated from the host cell. While the functions of these virally encoded GPCRs remain unclear, the receptors possess potent signaling abilities. Understanding the molecular regulation of these GPCRs will provide important insight into CMV pathogenesis.     

Modelling the activation of G-protein coupled receptors by a single drug

In this paper, the most popular proposed mechanism for activation of G-protein coupled receptors (GPCRs) - the shuttling mechanism - is modelled mathematically. An asymptotic analysis of this model clarifies the dynamics of the system in the presence of a drug, in particular identifying which reactions dominate during the different timescales. The modelling also reveals challenging behaviour in the form of a peak response. This new mechanism gives simple explanations for complex, possibly misunderstood, behaviour.     

Serial rebinding of ligands to clustered receptors as exemplified by bacterial chemotaxis

Serial ligation is the repeated reversible binding of a ligand to one receptor after another. It is a widespread phenomenon throughout biochemical systems, occurring anytime receptors are clustered together and ligand binding is reversible. Computer simulations are used in this work to investigate a representative example, which is the serial ligation of an extracellular aspartate molecule to the membrane-bound chemotaxis receptors of an Escherichia coli bacterium. It is found that the initial binding site of a ligand to a cluster of receptors is more likely to be near the edge of the cluster than near the middle, although there is no overall bias when all rebindings are considered. Serial ligation does not lead directly to signal amplification or attenuation but instead causes binding events to be correlated in both space and time: a ligand is likely to bind many times in rapid succession in a small region of the receptor cluster, but there can also be long intervals between bindings. This leads to an increased level of noise in the received signal but may allow a single ligand to be sensed above a uniform level of background noise. The focus of this paper is on the interpretation of simulation results so they can be generalized to a wide variety of other systems and to allow the identification of systems in which serial ligation is likely to be important. In the process, several characteristic times are identified, as are scaling laws for the spatial and temporal dynamics.     

Lipid-facing correlated mutations and dimerization in G-protein coupled receptors.

A correlated mutation analysis has been performed on the aligned protein sequences of a number of class A G-protein coupled receptor families, including the chemokine, neurokinin, opioid, somatostatin, thyrotrophin and the whole biogenic amine family. Many of the correlated mutations are observed flanking or neighbouring conserved residues. The correlated residues have been plotted onto the transmembrane portion of the rhodopsin crystal structure. The structure shows that a significant proportion of the correlated mutations are located on the external (lipid-facing) region of the helices. The occurrence of these highly correlated patterns of change amongst the external residues suggest that they are sites for protein-protein interactions. In particular, it is suggested that the correlated residues may be involved in either large conformational changes, the formation of heterodimers or homodimers (which may be domain swapped) or oligomers required for activation or internalization. The results are discussed in the light of the subtype-specific heterodimerization observed for the chemokine, opioid and somatostatin receptors.     

The relaxin peptide family and their novel G-protein coupled receptors

Relaxin-1 is a heterodimeric peptide hormone primarily produced by the pregnant corpus luteum and/or placenta and is involved in many essential physiological processes centered on its action as a potent extracellular matrix (ECM) remodeling agent. Insulin-like peptide 3 (INSL3), also known as relaxin-like factor, is predominantly expressed in the Leydig cells of the testes and is an important mediator of testicular descent. The relaxin-1 equivalent peptide in humans is actually the product of the human RLN2 gene, human 2 (H2) relaxin. Recently identified and thought to be the ancestral relaxin, relaxin-3 is specifically expressed in the nucleus incertus of the mouse and rat brain and is most likely an important neuropeptide. Each of the hormones above act on cell membrane G-protein coupled receptors (GPCRs). The relaxin-1 receptor is leucine-rich repeat-containing GPCR 7 (LGR7) whereas INSL3 acts on the closely related LGR8. These receptors have large extra-cellular domains containing multiple leucine-rich repeats (LRRs) and a unique LDL receptor-like cysteine-rich motif (LDLR-domain). Relaxin-3 will bind and activate LGR7 with 50-fold lower activity than H2 relaxin. Two relaxin-3 selective GPCRs; somatostatin and angiotensin like peptide receptor (SALPR) and GPCR 142 were recently identified, these type I GPCRs are unrelated to LGR7 and LGR8. The discovery and characterisation of these receptors is greatly aiding the quest to unravel the mechanics of these important hormones, however with three other family members, insulin-like peptides 4–6 (INSL4, INSL5 and INSL6) with unknown functions and unidentified receptors, there is still much to be learnt about this hormone family.     

An evaluation of automated in silico ligand docking of amino acid ligands to Family C G-protein coupled receptors

Family C G-protein coupled receptors (GPCRs) consist of the metabotropic glutamate receptors (mGluRs), the calcium-sensing receptor (CaSR), the T1R taste receptors, the GABA(B) receptor, the V2R pheromone receptors, and several chemosensory receptors. A common feature of Family C receptors is the presence of an amino acid binding pocket. The objective of this study was to evaluate the ability of the automatic docking program FlexX to predict the favored amino acid ligand at several Family C GPCRs. The docking process was optimized using the crystal structure of mGluR1 and the 20 amino acids were docked into homology models of the CaSR, the 5.24 chemosensory receptor, and the GPRC6A amino acid receptor. Under optimized docking conditions, glutamate was docked in the binding pocket of mGluR1 with a root mean square deviation of 1.56 angstroms from the co-crystallized glutamate structure and was ranked as the best ligand with a significantly better FlexX score compared to all other amino acids. Ligand docking to a homology model of the 5.24 receptor gave generally correct predictions of the favored amino acids, while the results obtained with models of GPRC6A and the CaSR showed that some of the favored amino acids at these receptors were correctly predicted, while a few other top scoring amino acids appeared to be false positives. We conclude that with certain caveats, FlexX can be successfully used to predict preferred ligands at Family C GPCRs.     

Artificial membrane-like environments for in vitro studies of purified G-protein coupled receptors

Functional reconstitution of transmembrane proteins remains a significant barrier to their biochemical, biophysical, and structural characterization. Studies of seven-transmembrane G-protein coupled receptors (GPCRs) in vitro are particularly challenging because, ideally, they require access to the receptor on both sides of the membrane as well as within the plane of the membrane. However, understanding the structure and function of these receptors at the molecular level within a native-like environment will have a large impact both on basic knowledge of cell signaling and on pharmacological research. The goal of this article is to review the main classes of membrane mimics that have been, or could be, used for functional reconstitution of GPCRs. These include the use of micelles, bicelles, lipid vesicles, nanodiscs, lipidic cubic phases, and planar lipid membranes. Each of these approaches is evaluated with respect to its fundamental advantages and limitations and its applications in the field of GPCR research. This article is part of a Special Issue entitled: Membrane protein structure and function.     

Designing allosteric modulators for active conformational state of m-glutamate G-protein coupled receptors

G-protein coupled receptors (GPCRs) are found to be attractive drug targets for the treatment of various neuronal diseases. Allosteric modulators have their role in enhancing or suppressing the effect of glutamate on mGluRs. Structure of mGluR1 was generated with the help of Modeller software by considering human B2-adrenergic GPCR protein as template. Structure of various already known drug molecules were used for similarity search in the ZINC database and a large number of similar molecules were obtained, than filtering of these molecules were done by applying drug features. Molecules were screened by Molegro Virtual Docking program and numbers of novel molecules were generated by using LigBuilder software. Finally 16 novel drug candidates were selected, which were showing better results than the seed molecule and previously known modulators. These results will help in designing and synthesis of better drugs against diseases like Epilepsy and Parkinson's.     

Neurosteroid modulation of native and recombinant GABAA receptors

Summary 1. The pioneering work of Hans Selye over 50 years ago demonstrated that certain steroid metabolites can produce a rapid depression of central nervous system activity.2. Research during the last 10 years has established that such effects are mediated by a nongenomic and specific interaction of these steroids with the brain's major inhibitory receptor, the GABA_A receptor.3. Here we describe the molecular mechanism of action of such steroids and review attempts to define the steroid binding site on the receptor protein. The therapeutic potential of such neurosteroids is discussed.     

Plasmon-waveguide resonance spectroscopy: a new tool for investigating signal transduction by G-protein coupled receptors

Plasmon-waveguide resonance (PWR) spectroscopy provides a highly sensitive method for characterizing the kinetics, affinities and conformational changes involved in ligand binding to G-protein coupled receptors, without the need for radioactive or other labeling strategies. In the case of the cloned delta-opioid receptor from human brain incorporated into a lipid bilayer, we have shown that affinities determined in this way are consistent with those measured by standard binding procedures using membranes or whole cells containing the receptors, and that the spectral and kinetic properties of the binding processes allow facile distinction between agonist, inverse agonist, and antagonist ligands. We have also shown by direct measurements that G-protein binding affinities and the ability to undergo GTP/GDP exchange are dependent upon the type of ligand pre-bound to the receptor. PWR spectroscopy thus provides a powerful new approach to investigating signal transduction in biological membrane systems.     

Classification of amine type G-protein coupled receptors with feature selection

G-protein coupled receptors (GPCRs) are involved in various physiological processes. Therefore, classification of amine type GPCRs is important for proper understanding of their functions. Though some effective methods have been developed, it still remains unknown how many and which features are essential for this task. Empirical studies show that feature selection might address this problem and provide us with some biologically useful knowledge. In this paper, a feature selection technique is introduced to identify those relevant features of proteins which are potentially important for the prediction of amine type GPCRs. The selected features are finally accepted to characterize proteins in a more compact form. High prediction accuracy is observed on two data sets with different sequence similarity by 5-fold cross-validation test. The comparison with a previous method demonstrates the efficiency and effectiveness of the proposed method.