Photoaffinity crosslinking has been utilized to probe the nature of the ligand-receptor interface for a number of G protein-coupled receptor systems. Often the photoreactive benzophenone moiety incorporated in the ligand is found to react with a methionine in the receptor. We introduced methionines one-ata-time into the region 163-176 of the parathyroid hormone receptor, and find that crosslinking occurs to the side-chain of methionine over a range of 11 amino acids. We call this the ''Magnet Effect'' of methionine. Hence, crosslinking contact points can be significantly shifted by the presence of methionine in a receptor domain.
The Mid-Region of Parathyroid Hormone (1−34) Serves as a Functional Docking Domain in Receptor Activation
Elucidating the bimolecular interface between parathyroid hormone (PTH) and its cognate G protein-coupled receptor (PTHR1) should yield insights into the basis of molecular recognition and the mechanism of ligand-mediated intracellular signaling for a system that is critically important in regulating calcium levels in blood. We used photoaffinity scanning (PAS) to identify key ligand-receptor interactions for residues from the unstructured mid-region domain of PTH-(1-34). Four PTH analogues, containing a single photoreactive p-benzoylphenylalanine (Bpa) residue in position 11, 15, 18, or 21, were found to photo-cross-link within receptor regions [165-176], [183-189], [190-298], and [165-176], respectively. Addition of these mid-region contacts as constraints to our previously proposed model of the PTH-PTHR1 complex and extensive molecular simulation experiments enables substantial refinement of the model. Specifically, (1) the overall receptor-bound conformation of the hormone is not extended, but bent; (2) helix [169-176] of the N-terminal extracellular domain (N-ECD) of the receptor is redirected toward the heptahelical bundle; and (3) the hormone traverses between the top of transmembrane (TM) helices 1 and 2, rather than between TM-7 and TM-1. This significantly alters the model of both the receptor-bound tertiary structure of the hormone and the topological orientation of the C-terminus of the N-ECD in the hormone-receptor bimolecular complex. We propose that the mid-region of PTH-(1-34) has a role in fixing, by extensive contacts with the receptor, the entry of the N-terminal helix of the hormone into the heptahelical bundle between TM-1 and TM-2. This anchorage would orient the amino terminus into position to activate the receptor.
Efforts to elucidate the nature of the bimolecular interaction of parathyroid hormone (PTH) with its cognate receptor, the PTH receptor type 1 (PTHR1), have relied heavily on benzoylphenylalanine-(Bpa-) based photoaffinity cross-linking. However, given the flexibility, size, and shape of Bpa, the resolution at the PTH-PTHR1 interface appears to be reaching the limit of this technique. Here we employ a disulfide-trapping approach developed by others primarily for use in screening compound libraries to identify novel ligands. In this method, cysteine substitutions are introduced into a specific site within the ligand and a region in the receptor predicted to interact with each other. Upon ligand binding, if these cysteines are in close proximity, they form a disulfide bond. Since the geometry governing disulfide bond formation is more constrained than Bpa cross-linking, this novel approach can be employed to generate a more refined molecular model of the PTH-PTHR1 complex. Using a PTH analogue containing a cysteine at position 1, we probed 24 sites and identified 4 in PTHR1 to which cross-linking occurred. Importantly, previous photoaffinity cross-linking studies using a PTH analogue with Bpa at position 1 only identified a single interaction site. The new sites identified by the disulfide-trapping procedure were used as constraints in molecular dynamics simulations to generate an updated model of the PTH-PTHR1 complex. Mapping by disulfide trapping extends and complements photoaffinity cross-linking. It is applicable to other peptide-receptor interfaces and should yield insights about yet unknown sites of ligand-receptor interactions, allowing for generation of more refined models.Class II G protein-coupled receptors (GPCRs) 1 interact with physiologically important peptides. There is intense study of how these peptides associate with their cognate receptors since elucidation of these interactions should provide important insights for the rational design of ligands with enhanced pharmacological properties for use in treating an array of diseases (1,2). Over the past decade, photoaffinity cross-linking has been employed to study the interaction of a number of peptide-GPCR interactions (3). This technique involves systematically probing the receptor for regions of interaction using a peptide that incorporates a photoreactive moiety that irreversibly cross-links to the receptor. We and others have used this approach extensively to study the interaction of parathyroid hormone (PTH) with its cognate receptor, the PTH receptor type 1 (PTHR1) (4-12). This hormone-receptor system plays an integral role in calcium metabolism and bone biology. † This work was supported in part by Grants DK47490 (to M.R.) and GM54082 (to D.F.M.) from the National Institutes of Health.* Address correspondence to this author. Phone: (617) Our research is focused on studying the bimolecular interface of the PTH-PTHR1 complex in order to gain insights that will aid the design of ligands of PTHR1 for the treatment of osteoporosis and o...
Pseudoprolines: Targeting acis Conformation in a Mimetic of the gp120 V3 Loop of HIV-1
The specific recognition of cis peptide bonds is possible with antibodies that are directed against cyclic and linear peptide antigens derived from the V3 loop of the HIV‐1 protein gp120, into which a thiazolidine derivative (pseudoproline) has been introduced (see schematic representation). This extension of the pseudoproline concept may help to decipher the unique role of proline residues in biologically relevant systems.
Photoaffinity crosslinking has yielded important insights in the study of G protein-coupled receptors and the mode of ligand binding. The most widely used photolabile moiety is p-benzoylphenylalanine largely because of its reportedly high site specificity, reduced reactivity to water and light, photokinetics, and ease of incorporation into peptide ligands during synthesis. However, in the course of our studies directed at characterizing the binding of parathyroid hormone to its cognate G proteincoupled receptor, we find that inherent properties of p-benzoylphenylalanine, such as its size and conformational flexibility, limit the resulting resolution of the ligand-receptor structure. Here, we examine and define these limits. Keywords molecular modeling; parathyroid hormone receptor; p-benzoylphenylalanine; photoaffinity crosslinking; resolution limit G protein-coupled receptors represent the largest family of membrane proteins, with over 800 members identified in the human genome. They constitute one of the most important groups of targets for drug discovery, with approximately half of all drugs currently in clinical use targeted at G protein-coupled receptors (GPCRs). Yet, the nature of ligand binding to GPCRs and the mechanism of activation of GPCRs are poorly understood; the hydrophobic nature of the seven membrane-spanning helices and the conformational complexity of GPCRs pose a problem for direct structure determination by crystallography or NMR.To gain insight into ligand-GPCR interactions, photoaffinity scanning has been commonly applied as a means of mapping the points and zones of contact between hormones and their receptors. Using p-benzoylphenylalanine (Bpa)-based photoaffinity scanning, important advances in our understanding of the ligand-receptor interface have been obtained for a number of ligand-GPCR systems. For example, the 27 amino acid hormone secretin was found to adopt an extended conformation while bound to its receptor, a family B GPCR, with the N-terminal residues of the hormone reaching to the extracellular part of TM6 (1,2). Similarly, photoaffinity crosslinking reveals a binding groove for calcitonin on the calcitonin receptor, also a family B GPCR, extending from residues in the N-ECD to contacts in extracellular loop (ECL) 3, with the N-terminus of the ligand positioned in proximity to TM6 (3). In addition, the crosslinking sites for calcitonin agonists versus antagonists differ due to differential interaction of the analogs with active versus inactive receptor states, suggesting conformational changes involving the N-ECD upon receptor activation (4). The angiotensin-receptor system is an *Corresponding author: Angela Wittelsberger, angela.wittelsberger@tufts.edu. example from GPCR family A. Bpa-based crosslinking shows that the eight amino acid ligand adopts an extended conformation which inserts into the TM bundle with position 8 of the ligand contacting residues in TM3, TM6, and TM7 (5). Finally, for the parathyroid hormone (PTH)-receptor (PTHR1) system, molecular dynamic...
Rabies virus causes lethal brain infection in about 61000 people per year. Each year, tens of thousands of people receive anti-rabies prophylaxis with plasma-derived immunoglobulins and vaccine soon after exposure. Anti-rabies immunoglobulins are however expensive and have limited availability. VHH are the smallest antigen-binding functional fragments of camelid heavy chain antibodies, also called Nanobodies. The therapeutic potential of anti-rabies VHH was examined in a mouse model using intranasal challenge with a lethal dose of rabies virus. Anti-rabies VHH were administered directly into the brain or systemically, by intraperitoneal injection, 24 hours after virus challenge. Anti-rabies VHH were able to significantly prolong survival or even completely rescue mice from disease. The therapeutic effect depended on the dose, affinity and brain and plasma half-life of the VHH construct. Increasing the affinity by combining two VHH with a glycine-serine linker into bivalent or biparatopic constructs, increased the neutralizing potency to the picomolar range. Upon direct intracerebral administration, a dose as low as 33 µg of the biparatopic Rab-E8/H7 was still able to establish an anti-rabies effect. The effect of systemic treatment was significantly improved by increasing the half-life of Rab-E8/H7 through linkage with a third VHH targeted against albumin. Intraperitoneal treatment with 1.5 mg (2505 IU, 1 ml) of anti-albumin Rab-E8/H7 prolonged the median survival time from 9 to 15 days and completely rescued 43% of mice. For comparison, intraperitoneal treatment with the highest available dose of human anti-rabies immunoglobulins (65 mg, 111 IU, 1 ml) only prolonged survival by 2 days, without rescue. Overall, the therapeutic benefit seemed well correlated with the time of brain exposure and the plasma half-life of the used VHH construct. These results, together with the ease-of-production and superior thermal stability, render anti-rabies VHH into valuable candidates for development of alternative post exposure treatment drugs against rabies.
Bioactive N‐terminal undecapeptides derived from parathyroid hormone: the role of α‐helicity*
The N-terminal 1-34 segment of parathyroid hormone (PTH) is fully active in vitro and in vivo and it can reproduce all biological responses in bone characteristic of the native intact PTH. Recent studies have demonstrated that N-terminal fragments presenting the principal activating domain such as PTH(1-11) and PTH(1-14) with helicity-enhancing substitutions yield potent analogues with PTH(1-34)-like activity. To further investigate the role of alpha-helicity on biological potency, we designed and synthesized by solid-phase methodology the following hPTH(1-11) analogues substituted at positions 1 and/or 3 by the sterically hindered and helix-promoting C(alpha)-tetrasubstituted alpha-amino acids alpha-amino isobutyric acid (Aib), 1-aminocyclopentane-1-carboxylic acid (Ac(5)c) and 1-aminocyclohexane-1-carboxylic acid (Ac(6)c): Ac(5)c-V-Aib-E-I-Q-L-M-H-Q-R-NH(2) (I); Aib-V-Ac(5)c-E-I-Q-L-M-H-Q-R-NH(2) (II); Ac(6)c-V-Aib-E-I-Q-L-M-H-Q-R-NH(2) (III); Aib-V-Ac(6)c-E-I-Q-L-M-H-Q-R-NH(2) (IV); Aib-V-Aib-E-I-Q-L-M-H-Q-R-NH(2) (V); S-V-Aib-E-I-Q-L-M-H-Q-R-NH(2) (VI), S-V-Ac(5)c-E-I-Q-L-M-H-Q-R-NH(2) (VII); Ac(5)c-V-S-E-I-Q-L-M-H-Q-R-NH(2) (VIII); Ac(6)c-V-S-E-I-Q-L-M-H-Q-R-NH(2) (IX); Ac(5)c-V-Ac(5)c-E-I-Q-L-M-H-Q-R-NH(2) (X); Ac(6)c-V-Ac(6)c-E-I-Q-L-M-H-Q-R-NH(2) (XI). All analogues were biologically evaluated and conformationally characterized in 2,2,2-trifluoroethanol (TFE) solution by circular dichroism (CD). Analogues I-V, which cover the full range of biological activity observed in the present study, were further conformationally characterized in detail by nuclear magnetic resonance (NMR) and computer simulations studies. The results of ligand-stimulated cAMP accumulation experiments indicated that analogues I and II are active, analogues III, VI and VII are very weakly active and analogues IV, V, VIII-XI are inactive. The most potent analogue, I exhibits biological activity 3500-fold higher than that of the native PTH(1-11) and only 15-fold weaker than that of the native sequence hPTH(1-34). Remarkably, the two most potent analogues, I and II, and the very weakly active analogues, VI and VII, exhibit similar helix contents. These results indicate that the presence of a stable N-terminal helical sequence is an important but not sufficient condition for biological activity.
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