Insulin and IGF-1 receptors contain covalently bound palmitic acid

We have studied the biosynthesis of the insulin receptor in a human hepatoma cell line, HepG2. As previously reported, these cells synthesize a disulphide-bonded alpha 2 beta 2 tetrameric insulin receptor. Labelling of HepG2 cells with [3H]palmitate or [3H]myristate followed by immunoprecipitation with a polyclonal antireceptor antibody revealed the incorporation of palmitate, but not myristate, into the beta-subunit and alpha beta-precursor of the receptor in a hydroxylamine-sensitive linkage. The extracellular alpha-subunit was not labelled, demonstrating the specificity of incorporation. Acylation of the insulin receptor was an early event as judged by fatty acid incorporation into the alpha beta-precursor and prevention by protein synthesis inhibitors. Pulse-chase studies demonstrated the expected processing of the alpha beta-precursor to mature alpha- and beta-subunits, but no evidence for preferential turnover of the fatty acid moiety was found. The site of acylation appears to be in the transmembrane or cytoplasmic domain since proteolytic treatment of intact cells produced a truncated beta-subunit still containing label. Binding studies showed that HepG2 cells contain approximately half as many insulin-like growth factor-1 receptors as insulin receptors, raising the possibility that this receptor may also be acylated. Indeed, immunoprecipitation with the antiinsulin receptor serum of MDCK cells expressing IGF-1 receptors, but not insulin receptors, revealed bands corresponding to the alpha beta-precursor, alpha- and beta-subunits, of which the alpha beta-precursor and beta-subunits incorporated [3H]palmitate but the alpha-subunit did not.     

X-ray crystal structure of a small antagonist peptide bound to interleukin-1 receptor type 1

Interleukin (IL-1)alpha and IL-1beta are important mediators of inflammation. The binding of IL-1 to interleukin-1 receptor (IL-1R) type 1 is the initial step in IL-1 signal transduction and therefore is a tempting target for anti-inflammatory therapeutics. To advance our understanding of IL-1R1 binding interactions, we have determined the structure of the extracellular domains of IL-1R1 bound to a 21-amino acid IL-1 antagonist peptide at 3.0-A resolution. The antagonist peptide binds to the domain 1/2 junction of the receptor, which is a conserved binding site for IL-1beta and IL-1 receptor antagonist (IL-1ra). This co-crystal structure also reveals that considerable flexibility is present in IL-1R1 because the carboxyl-terminal domain of the receptor is rotated almost 170 degrees relative to the first two domains of the receptor compared with the previously solved IL-1R1.ligand structures. The structure shows an unexpected binding mode for the peptide and may contribute to the design of smaller IL-1R antagonists.     

Relative localization of the bound acetylcholine receptor subunits and neurotoxin

A series of neurotoxin II (Naja naja oxiana) derivatives, each containing one p-azido-[14C]benzoyl group, have been prepared. Those labeled at Leu1, Lys15, Lys25, Lys26, or Lys46 associate specifically with the acetylcholine receptor from the Torpedo marmorata electric organs and form the crosslinks with it as a result of irradiation. Electrophoresis in polyacrylamide gel and gel chromatography revealed the contacts between the neurotoxins and alpha, beta, gamma and delta subunits of the receptor, modification of a particular subunit being governed by the photoactivable group position in the neurotoxin molecule. The differences of the two neurotoxin binding sites in the receptor were demonstrated by analysis of the photoinduced crosslinks under the conditions of one site being blocked by hexa (trifluoroacetyl) neurotoxin II. The mutual arrangement of the two bound neurotoxin molecules was established. On the basis of data obtained, two models for the acetylcholine receptor subunit topography were proposed.     

Solution structure of amphibian tachykinin Uperolein bound to DPC micelles

Uperolein, a physalaemin-like endecapeptide, has been shown to be selective for Neurokinin 1 receptor. As a first step towards understanding the structure-activity relationship, we report the membrane-induced structure of Uperolein with the aid of circular dichroism and 2D (1)H NMR spectroscopy. Sequence-specific resonance assignments of protons have been made using correlation spectroscopy (TOCSY, DQF-COSY) and NOESY spectroscopy. The interproton distance constraints and dihedral angle constraints have been utilized to generate a family of structures using torsion angle molecular dynamics within program DYANA. The conformational range of the peptide revealed by NMR and CD studies has been analysed in terms of characteristic secondary features. Analysis of NMR data indicates that the global fold of Uperolein can be explained in terms of equilibrium between 3(10)-helix and alpha-helix from residues 5 to 11. An extended highly flexible N-terminus displays some degree of order and a possible turn structure. A comparison between the structures of Uperolein and Substance P, a prototype and endogenous Neurokinin 1 receptor agonist, indicates several common features in the distribution of hydrophobic and hydrophilic residues. Both the peptides show an amphiphilic character towards the middle region. The similarities suggest that the molecules interact with the receptor in an analogous manner.     

Alpha and beta subunits of the nicotinic acetylcholine receptor contain covalently bound lipid

Labeling of the BC3H1 muscle-like cell line with [3H] palmitate, followed by immunoprecipitation of the acetylcholine receptor, indicated that the alpha and beta subunits of the receptor contain covalently bound fatty acid. After acid hydrolysis, fatty acid methyl esters could be recovered from the isolated [3H]palmitate-labeled alpha subunit. Treatment of differentiated BC3H1 cells with cerulenin, an inhibitor of fatty acid and sterol synthesis and fatty acid acylation of proteins, resulted in a 50% inhibition in expression of the acetylcholine receptor on the cell surface under conditions where there was minimal inhibition of protein synthesis. We conclude that this previously undetected post-translational modification may play a role in assembly and/or surface expression of the acetylcholine receptor.     

DNA binding properties of glucocorticosteroid receptors bound to the steroid antagonist RU-486.

RU-486 is an anti-fertility steroid which also has anti-glucocorticosteroid effects. RU-486 is shown to be a strong antagonist of the glucocorticosteroid-induced cytolytic response of the murine thymoma lines W7TB and T1M1b , and of the induction of mouse mammary tumor virus (MMTV) mRNA in T1M1b cells. The glucocorticosteroid receptor of W7 cells has high affinity for RU-486 (Kd = 3 X 10(-9) M) but the complex formed has low nuclear transfer capacity. Binding of RU-486, as compared with the glucocorticosteroid agonist triamcinolone acetonide, to mouse receptor results in a decreased affinity for DNA in general and a reduced specific recognition of a site in the promoter region of MMTV proviral DNA. The RU-486 complex formed with rat liver receptor exhibits the same behavior; in addition, it is shown that only a fraction of these complexes are activated by temperature and these form highly salt-sensitive interactions with DNA. These results indicate that the binding of RU-486 to glucocorticosteroid receptors mimics pharmacologically the properties of a class of receptor variants (nt-) which are non-functional and have reduced nuclear transfer and altered DNA binding capacity. These results substantiate the importance of DNA binding in receptor function.     

Conformation of a peptide ligand bound to its G-protein coupled receptor

Many peptide hormones elicit a wide array of physiological effects by binding to G-protein coupled receptors. We have determined the conformation of pituitary adenylate cyclase activating polypeptide, PACAP(1--21)NH(2), bound to a PACAP-specific receptor by NMR spectroscopy. Residues 3--7 form a unique beta-coil structure that is preceded by an N-terminal extended tail. This beta-coil creates a patch of hydrophobic residues that is important for receptor binding. In contrast, the C-terminal region (residues 8--21) forms an alpha-helix, similar to that in the micelle-bound PACAP. Thus, the conformational difference between PACAP in the receptor-bound and the micelle-bound states is limited to the N-terminal seven residues. This observation is consistent with the two-step ligand transportation model in which PACAP first binds to the membrane nonspecifically and then diffuses two-dimensionally in search of its receptor; a conformational change at the N-terminal region then allows specific interactions between the ligand and the receptor.     

The gene structure of the human growth factor bound protein GRB2

The growth factor bound protein GRB2, a 25-kDa cytosolic protein, plays a key role in two separate pathways of the insulin signal transduction system leading from the insulin receptor to the Ras proteins and thus affecting mitogenic signaling. GRB2 regulates Ras activation through association with the guanine nucleotide exchange factor Sos. The GRB2/Sos complex can connect with insulin receptor substrate 1 (IRS-1), which is one of the primary targets of the insulin and insulin-like growth factor receptors. In a second pathway, independent of IRS-1, GRB2 links the insulin receptor to Ras signaling through another adapter protein, called Shc. In protooncogenic and other noninsulin signaling systems, GRB2 appears to link receptor tyrosine kinases to Ras in similar pathways as well. This study presents the exon-intron organization of the human GRB2 gene. After primers were placed across the known mRNA sequence, Long PCR products spanning introns and their adjacent splice sites were amplified and adequately sequenced to establish the splice sites and flanking regions. The gene was found to consist of five exons (ranging from 78 to 186 bp) and of four introns (from approximately 1 to approximately 7 kb). Intron primers for the respective exons were generated using the newly found flanking sequences. All exons were successfully amplified and sequenced, and the data obtained from Long PCR sequencing were confirmed.     

Structure of the parathyroid hormone receptor C terminus bound to the G-protein dimer Gbeta1gamma2

A critical role of the Gbetagamma dimer in heterotrimeric G-protein signaling is to facilitate the engagement and activation of the Galpha subunit by cell-surface G-protein-coupled receptors. However, high-resolution structural information of the connectivity between receptor and the Gbetagamma dimer has not previously been available. Here, we describe the structural determinants of Gbeta1gamma2 in complex with a C-terminal region of the parathyroid hormone receptor-1 (PTH1R) as obtained by X-ray crystallography. The structure reveals that several critical residues within PTH1R contact only Gbeta residues located within the outer edge of WD1- and WD7-repeat segments of the Gbeta toroid structure. These regions encompass a predicted membrane-facing region of Gbeta thought to be oriented in a fashion that is accessible to the membrane-spanning receptor. Mutation of key receptor contact residues on Gbeta1 leads to a selective loss of function in receptor/heterotrimer coupling while preserving Gbeta1gamma2 activation of the effector phospholipase-C beta.     

Redox properties of human transferrin bound to its receptor

Virtually all organisms require iron, and iron-dependent cells of vertebrates (and some more ancient species) depend on the Fe(3+)-binding protein of the circulation, transferrin, to meet their needs. In its iron-donating cycle, transferrin is first captured by the transferrin receptor on the cell membrane, and then internalized to a proton-pumping endosome where iron is released. Iron exits the endosome to enter the cytoplasm via the ferrous iron transporter DMT1, a molecule that accepts only Fe(2+), but the reduction potential of ferric iron in free transferrin at endosomal pH (approximately 5.6) is below -500 mV, too low for reduction by physiological agents such as the reduced pyridine nucleotides with reduction potentials of -284 mV. We now show that in its complex with the transferrin receptor, which persists throughout the transferrin-to-cell cycle of iron uptake, the potential is raised by more than 200 mV. Reductive release of iron from transferrin, which binds Fe(2+) very weakly, is therefore physiologically feasible, a further indication that the transferrin receptor is more than a passive conveyor of transferrin and its iron.     

Structure of herpes simplex virus glycoprotein D bound to the human receptor nectin-1

Binding of herpes simplex virus (HSV) glycoprotein D (gD) to a cell surface receptor is required to trigger membrane fusion during entry into host cells. Nectin-1 is a cell adhesion molecule and the main HSV receptor in neurons and epithelial cells. We report the structure of gD bound to nectin-1 determined by x-ray crystallography to 4.0 Å resolution. The structure reveals that the nectin-1 binding site on gD differs from the binding site of the HVEM receptor. A surface on the first Ig-domain of nectin-1, which mediates homophilic interactions of Ig-like cell adhesion molecules, buries an area composed by residues from both the gD N- and C-terminal extensions. Phenylalanine 129, at the tip of the loop connecting β-strands F and G of nectin-1, protrudes into a groove on gD, which is otherwise occupied by C-terminal residues in the unliganded gD and by N-terminal residues in the gD/HVEM complex. Notably, mutation of Phe129 to alanine prevents nectin-1 binding to gD and HSV entry. Together these data are consistent with previous studies showing that gD disrupts the normal nectin-1 homophilic interactions. Furthermore, the structure of the complex supports a model in which gD-receptor binding triggers HSV entry through receptor-mediated displacement of the gD C-terminal region.

Authors Summary

Herpes simplex virus (HSV) is a widespread human pathogen. Four viral glycoproteins (gD, gB, gH/gL) are required for HSV entry into host cells. gD binding to a cell surface receptor triggers conformational changes in the other viral glycoproteins leading to membrane fusion and viral entry. Two structurally unrelated cellular protein receptors, nectin-1 and HVEM, can mediate HSV entry upon binding to gD. The structure presented here reveals the molecular basis for the stable interaction between HSV-1 gD and the receptor nectin-1. Comparison with the previously determined structures of the gD/HVEM complex and unliganded gD shows that, despite the fact that the two receptors interact with different binding sites, they both cause a similar conformational change in gD. Therefore, our data point to a conserved mechanism for receptor mediated activation of the HSV entry process. In addition, the gD/Nectin-1 structure reveals that the gD-binding site overlaps with a surface involved in nectin-1 homo-dimerization. This observation explains how gD interferes with the cell adhesion function of nectin-1. Finally, the gD/Nectin-1 complex displays similarities with other viral ligands bound to immunoglobulin-like receptors suggesting a convergent mechanism for receptors selection and usage.     

13C Isotopologue editing of FMN bound to phototropin domains

The plant blue light receptor phototropin comprises a protein kinase domain and two FMN-binding LOV domains (LOV1 and LOV2). Blue light irradiation of recombinant LOV domains is conducive to the addition of a cysteinyl thiolate group to carbon 4a of the FMN chromophore, and spontaneous cleavage of that photoadduct completes the photocycle of the receptor. The present study is based on (13)C NMR signal modulation observed after reconstitution of LOV domains of different origins with random libraries of (13)C-labeled FMN isotopologues. Using this approach, all (13)C signals of FMN bound to LOV1 and LOV2 domains of Avena sativa and to the LOV2 domain of the fern, Adiantum capillus-veneris, could be unequivocally assigned under dark and under blue light irradiation conditions. (13)C Chemical shifts of FMN are shown to be differently modulated by complexation with the LOV domains under study, indicating slight differences in the binding interactions of FMN and the apoproteins.     

Molecular mechanisms of non‐transferrin‐bound and transferring‐bound iron uptake in primary hippocampal neurons

The molecular mechanisms of iron trafficking in neurons have not been elucidated. In this study, we characterized the expression and localization of ferrous iron transporters Zip8, Zip14 and divalent metal transporter 1 (DMT1), and ferrireductases Steap2 and stromal cell‐derived receptor 2 in primary rat hippocampal neurons. Steap2 and Zip8 partially co‐localize, indicating these two proteins may function in Fe³⁺ reduction prior to Fe²⁺ permeation. Zip8, DMT1, and Steap2 co‐localize with the transferrin receptor/transferrin complex, suggesting they may be involved in transferrin receptor/transferrin‐mediated iron assimilation. In brain interstitial fluid, transferring‐bound iron (TBI) and non‐transferrin‐bound iron (NTBI) exist as potential iron sources. Primary hippocampal neurons exhibit significant iron uptake from TBI (Transferrin‐⁵⁹Fe³⁺) and NTBI, whether presented as ⁵⁹Fe²⁺‐citrate or ⁵⁹Fe³⁺‐citrate; reductase‐independent ⁵⁹Fe²⁺ uptake was the most efficient uptake pathway of the three. Kinetic analysis of Zn²⁺ inhibition of Fe²⁺ uptake indicated that DMT1 plays only a minor role in the uptake of NTBI. In contrast, localization and knockdown data indicate that Zip8 makes a major contribution. Data suggest also that cell accumulation of ⁵⁹Fe from TBI relies at least in part on an endocytosis‐independent pathway. These data suggest that Zip8 and Steap2 play a major role in iron accumulation from NTBI and TBI by hippocampal neurons.

     

Solubilization of membrane bound opiate receptor from rat brain

Sonication of rat brain membranes for 9 minutes solubilized 35% of their stereospecific opiate binding activity; a second 9 minute sonication of the insoluble residue released an additional 21% of the original binding. The opiate binding properties of the solubilized material were highly similar to those of membrane bound receptor by a number of criteria, including affinity, effect of sodium, and the IC₅₀ of unlabeled opiates in displacing ³H-etorphine binding. Moreover, storage of the solubilized receptor fraction for two weeks at ?20°C did not significantly change the receptor binding. Sonication thus appears to be a useful first step in purifying the opiate receptor.     

Structure of IL-22 bound to its high-affinity IL-22R1 chain

IL-22 is an IL-10 family cytokine that initiates innate immune responses against bacterial pathogens and contributes to immune disease. IL-22 biological activity is initiated by binding to a cell-surface complex composed of IL-22R1 and IL-10R2 receptor chains and further regulated by interactions with a soluble binding protein, IL-22BP, which shares sequence similarity with an extracellular region of IL-22R1 (sIL-22R1). IL-22R1 also pairs with the IL-20R2 chain to induce IL-20 and IL-24 signaling. To define the molecular basis of these diverse interactions, we have determined the structure of the IL-22/sIL-22R1 complex. The structure, combined with homology modeling and surface plasmon resonance studies, defines the molecular basis for the distinct affinities and specificities of IL-22 and IL-10 receptor chains that regulate cellular targeting and signal transduction to elicit effective immune responses.     

Comparison of the kinetics of cycling of the transferrin receptor in the presence or absence of bound diferric transferrin.

The kinetics of cycling of the transferrin receptor in A431 human epidermoid-carcinoma cells was examined in the presence or absence of bound diferric transferrin. In order to investigate the properties of the receptor in the absence of transferrin, the cells were maintained in defined medium without transferrin. It was demonstrated that Fab fragments of a monoclonal anti-(transferrin receptor) antibody (OKT9) did not alter the binding of diferric 125I-transferrin to the receptor or change the accumulation of [59Fe]diferric transferrin by cells. OKT9 125I-Fab fragments were prepared and used as a probe for the function of the receptor. The first-order rate constants for endocytosis (0.16 +/- 0.02 min-1) and exocytosis (0.056 +/- 0.003 min-1) were found to be significantly lower for control cells than the corresponding rate constants for endocytosis (0.22 +/- 0.02 min-1) and exocytosis (0.065 +/- 0.004 min-1) measured for cells incubated with 1 microM-diferric transferrin (mean +/- S.D., n = 3). The cycling of the transferrin receptor is therefore regulated by diferric transferrin via an increase in both the rate of endocytosis and exocytosis. Examination of the accumulation of OKT9 125I-Fab fragments indicated that diferric transferrin caused a marked decrease in the amount of internalized 125I-Fab fragments associated with the cells after 60 min of incubation at 37 degrees C. Diferric transferrin therefore increases the efficiency of the release of internalized 125I-Fab fragments compared with cells incubated without diferric transferrin. These data indicate that transferrin regulates the sorting of the transferrin receptor at the cell surface and within endosomal membrane compartments.     

Cation-independent mannose 6-phosphate receptor contains covalently bound fatty acid

The cation-independent mannose 6-phosphate receptor (215,000 daltons) was isolated from embryonic bovine tracheal cells and embryonic human skin fibroblasts labelled with [3H]palmitic acid. The tritium label was detected in the protein upon fluorographic analysis of SDS-polyacrylamide gels of the purified receptor. The label was not sensitive to hydroxylamine, methanolic KOH, or beta-mercaptoethanol, but labelled fatty acid was recovered from the protein by acidic methanolysis. Labelled receptor protein could not be isolated from cells grown in the presence of [3H]myristic acid. The results suggest the presence of amide-linked palmitic acid in the structure of the cation-independent mannose 6-phosphate receptor.     

Internalization and degradation of macrophage Fc receptors bound to polyvalent immune complexes

We have studied the Fc receptor-mediated pinocytosis of immunoglobulin G (IgG)-containing immune complexes by mouse macrophages. IgG complexes were formed from affinity-purified rabbit dinitrophenyl IgG and dinitrophenyl modified BSA at molar ratios of 2.5-10:1. Both the specificity of binding and the fate of internalized receptors were analyzed using monoclonal and polyclonal anti-Fc receptor antibodies. Based on the susceptibility of surface-bound ligand to release by proteolysis, we have found that at 37 degrees C, 125I-labeled IgG complexes were rapidly internalized (t1/2 less than 2 min) and delivered to lysosomes; acid-soluble 125I was detectable in the growth medium within 5-10 min of uptake. However, kinetic evidence indicated that Fc receptors were not efficiently re-used for multiple rounds of ligand uptake. Instead, macrophages that were exposed continuously to saturating concentrations of IgG complexes exhibited a selective and largely irreversible removal of Fc receptors from the plasma membrane. This loss of surface receptors correlated with an increased rate of receptor turnover, determined by immune precipitation of Fc receptors from 125I-labeled macrophages. Thus, in contrast to the results obtained in the accompanying paper (I. Mellman, H. Plutner, and P. Ukkonen, 1984, J. Cell Biol. 98:1163-1169) using a monovalent ligand, these data indicate that the interaction of Fc receptors with polyvalent complexes leads to the degradation of both ligand and receptor following their delivery to lysosomes.     

The crystal structure of the endothelial protein C receptor and a bound phospholipid

The endothelial cell protein C receptor (EPCR) shares approximately 20% sequence identity with the major histocompatibility complex class 1/CD1 family of molecules, accelerates the thrombin-thrombomodulin-dependent generation of activated protein C, a natural anticoagulant, binds to activated neutrophils, and can undergo translocation from the plasma membrane to the nucleus. Blocking protein C/activated protein C binding to the receptor inhibits not only protein C activation but the ability of the host to respond appropriately to bacterial challenge, exacerbating both the coagulant and inflammatory responses. To understand how EPCR accomplishes these multiple tasks, we solved the crystal structure of EPCR alone and in complex with the phospholipid binding domain of protein C. The structures were strikingly similar to CD1d. A tightly bound phospholipid resides in the groove typically involved in antigen presentation. The protein C binding site is outside this conserved groove and is distal from the membrane-spanning domain. Extraction of the lipid resulted in loss of protein C binding, which could be restored by lipid reconstitution. CD1d augments the immune response by presenting glycolipid antigens. The EPCR structure is a model for how CD1d binds lipids and further suggests additional potential functions for EPCR in immune regulation, possibly including the anti-phospholipid syndrome.