Sensitivity-dependent hierarchical receptor codes for odors

In order to comprehend the strategy of odor encoding by odorant receptors, we isolated 2740 mouse receptor neurons from four olfactory epithelial zones and classified them in terms of their sensitivities and tuning specificities to a chiral pair of odorants, S(+)-carvone (caraway-like odor) and R(-)-carvone (spearmint-like odor). Our approach revealed that the majority of receptors at the lowest effective stimulus concentration represented the principal odor qualities characteristic of each enantiomer by means of the principal odor qualities of the odorants for which the receptors were most sensitive. The chiral-non-discriminating receptors were newly recruited 3.7 times of R(-)-carvone-sensitive receptors and totally became 2.8 times (39/14) of R(-)carvone-sensitive receptors in the subpopulations when the stimulus concentration was increased 10-fold [corrected]. More than 80% of the responsive receptors (an estimated 70 +/- alpha types) exhibited overlapping sensitivities between the enantiomers. The signals from the non-discriminating receptors may be reduced to decode the characteristic odor identity for R(-)-carvone in the brain over an adequate range of stimulus strengths. The information processing of odors appears to involve the selective weighting of the signals from the most sensitive receptors. An analysis of the overall receptor codes to carvones indicated that the system employs hierarchical receptor codes: principal odor qualities are encoded by the most sensitive receptors and lower-ranked odor qualities by less sensitive receptors.     

Evidence for hybrid rodent and human insulin receptors in transfected cells.

Chinese hamster ovary cells and NIH 3T3 cells overexpressing mutant human insulin receptors were examined for the presence of hybrid receptors composed of human and rodent insulin receptors. In the present studies, most of the endogenous rodent receptors were found to be immunoprecipitated from the transfected cells but not the parental cells with a monoclonal antibody specific for human receptor. These data indicate that in these transfected cells, most of the endogenous rodent receptors are in a hybrid complex with the overexpressed human receptor. These results together with the in vitro studies of Treadway et al. (Treadway, J.L., Morrison, B.D., Soos, M.A., Siddle, K., Olefsky, J., Ullrich, A., McClain, D.A., and Pessin, J.E. (1991) Proc. Natl. Acad. Sci. U.S.A. 88, 214-218) showing that hybrid receptors exhibit transdominant inhibition explain the prior finding indicating that overexpression of defective insulin receptors interferes with the normal signaling of endogenous receptors.     

On the origin of the olfactory receptor family: receptor genes of the jawless fish (Lampetra fluviatilis).

In vertebrates, recognition of odorous compounds is based on a large repertoire of receptor subtypes encoded by a multigene family. Towards an understanding of the phylogenetic origin of the vertebrate olfactory receptor family, attempts have been made to identify related receptor genes in the river lampreys (Lampetra fluviatilis), which are descendants of the earliest craniates and living representatives of the most ancient vertebrates. Employing molecular cloning approaches led to the discovery of four genes encoding heptahelical receptors, which share only a rather low overall sequence identity but several of the characteristic structural hallmarks with vertebrate olfactory receptors. Furthermore, in situ hybridization studies demonstrated that the identified genes are expressed in chemosensory cells of the singular lamprey olfactory organ. Molecular phylogenetic analysis confirmed a close relationship of the lamprey receptors to vertebrate olfactory receptors and in addition demonstrated that olfactory genes of the agnathostomes diverged from the gnathostome receptor genes before those split into class I and class II receptors. The data indicate that the lamprey receptors represent the most ancient family of the hitherto identified vertebrate olfactory receptors.     

Evolution of receptors for proglucagon-derived peptides: isolation of frog glucagon receptors

The mammalian proglucagon gene encodes three glucagon-like sequences, glucagon, glucagon-like peptide 1 (GLP-1) and glucagon-like peptide 2 (GLP-2). Each of these three functionally distinct proglucagon-derived peptides has a unique, but related, receptor. To better understand the origin of the unique physiological functions of each proglucagon-derived glucagon-like sequence we have cloned glucagon-like receptors from two species of frogs, Xenopus laevis and Rana pipiens. The cloned glucagon-like receptor sequences were found to be most closely related to glucagon receptors. To determine whether the evolutionary history of the receptors for proglucagon-derived peptides was the same as that inferred for the peptide hormones, we conducted a phylogenetic analysis using both parsimony and distance methods. We show that the evolutionary history of the receptors for glucagon-like sequences differ from the history of the glucagon-like sequences. The phylogeny of receptors for proglucagon-derived peptides is not monophyletic (i.e. they are not each other's closest relatives), as the receptor for the hormone glucose-dependent insulinotropic peptide (GIP) is more closely related to the glucagon receptor than either the GLP-1 or GLP-2 receptors. In contrast to the evolutionary origin of glucagon-like sequences, where glucagon is of most ancient origin, we found that the GLP-2 receptor has the most ancient origin. These observations suggest that the diversification of the glucagon-like sequences encoded by the proglucagon gene and of the receptors for these peptides occurred independently, and that either these hormones or their receptors have been recruited for new functions.     

Binding of antipsychotic drugs to human brain receptors focus on newer generation compounds

Using radioligand binding assays and post-mortem normal human brain tissue, we obtained equilibrium dissociation constants (K(d)s) for nine new antipsychotic drugs (iloperidone, melperone, olanzapine, ORG 5222, quetiapine, risperidone, sertindole, ziprasidone, and zotepine), one metabolite of a new drug (9-OH-risperidone), and three older antipsychotics (clozapine, haloperidol, and pimozide) at nine different receptors (alpha1-adrenergic, alpha2-adrenergic, dopamine D2, histamine H1, muscarinic, and serotonin 5-HT1A, 5-HT1D, 5-HT2A, and 5-HT2C receptors). Iloperidone was the most potent drug at the two adrenergic receptors. ORG 5222 was the most potent drug at dopamine D2 and 5-HT2c receptors, while ziprasidone was the most potent compound at three serotonergic receptors (5-HT1A, 5-HT1D, and 5-HT2A). At the remaining two receptors, olanzapine was the most potent drug at the histamine H1 receptor (Kd=0.087 nM); clozapine at the muscarinic receptor (Kd=9 nM). Certain therapeutic and adverse effects, as well as certain drug interactions can be predicted from a drug's potency for blocking a specific receptor. These data can provide guidelines for the clinician in the choice of antipsychotic drug.     

D1 and D2 Dopamine Receptors in Caudate-Putamen of Nonhuman Primates (Macaca fascicularis)

D1 and D2 dopamine receptors were characterized in the caudate-putamen region of nonhuman primate brains (Macaca fascicularis). D1 dopamine receptors were identified with [3H]SCH 23390 and D2 receptors with [3H]-spiperone. Scatchard analysis of [3H]SCH 23390 saturation data using washed membranes revealed a single high-affinity binding site (KD, 0.352 +/- 0.027 nM) with a density (Bmax) of 35.7 +/- 2.68 pmol/g original wet tissue weight (n = 10). The affinity of [3H]spiperone for the D2 site was 0.039 +/- 0.007 nM and the density was 25.7 +/- 1.97 pmol/g original wet tissue weight (n = 10). D1 and D2 receptors in nonhuman primates may be differentiated on the basis of drug affinities and stereoselectivity. In competition experiments, RS-SKF 38393 was the most selective D1 agonist, whereas (+)-4-propyl-9-hydroxynaphthoxazine [(+)-PHNO] was the most selective D2 agonist. Apomorphine was essentially nonselective for D1 or D2 binding sites. Of the antagonists, R-SKF 83566 and SCH 23390 were the most selective for the D1 site, whereas YM-09151-2 was the most selective for the D2 site. cis-Flupentixol and (S)-butaclamol were the least selective dopamine antagonists. D1 receptors bound benzazepine antagonists (SCH 23390/SCH 23388, R-SKF 83692/RS-SKF 83692) stereoselectively whereas D2 receptors did not. Conversely D2 receptors bound (S)-sulpiride and (+)-PHNO more potently than their enantiomers whereas D1 receptors showed little stereoselectively for each of these isomeric pairs. These binding characteristics may be utilized for evaluation of individual receptor function in vivo.     

How do G-protein-coupled receptors work? The case of metabotropic glutamate and GABA receptors

G-protein coupled receptors (GPCRs) represent the largest membrane proteins family in animal genomes. Being the receptors for most hormones and neurotransmitters, these proteins play a central role in intercellular communication. GPCRs can be classified into several groups based on the sequence similarity of their common structural feature: the heptahelical domain. The metabotropic receptors for the main neurotransmitters glutamate and gamma-aminobutyric acid (GABA) belong to the class III of GPCRs, together with others receptors for Ca2+, for sweet and amino acid taste compounds and for some pheromones, as well as for odorants in fish. Besides their transmembrane heptahelical domain responsible for G-protein activation, most of class III receptors possess a large extracellular domain responsible for ligand recognition. The recent resolution of the structure of this binding domain of one of these receptors, the mGlu1 receptor, together with the recent demonstration that these receptors are dimers, revealed an original mechanism of activation for these GPCRs. Such data open new possibilities to develop drugs aimed at modulating these receptors, and raised a number of interesting questions on the activation mechanism of other GPCRs.     

Expression and purification of functional ligand-binding domains of T1R3 taste receptors

Chemosensory receptors, including odor, taste, and vomeronasal receptors, comprise the largest group of G protein-coupled receptors (GPCRs) in the mammalian genome. However, little is known about the molecular determinants that are critical for the detection and discrimination of ligands by most of these receptors. This dearth of understanding is due in part to difficulties in preparing functional receptors suitable for biochemical and biophysical analyses. Here we describe in detail two strategies for the expression and purification of the ligand-binding domain of T1R taste receptors, which are constituents of the sweet and umami taste receptors. These class C GPCRs contain a large extracellular N-terminal domain (NTD) that is the site of interaction with most ligands and that is amenable to expression as a separate polypeptide in heterologous cells. The NTD of mouse T1R3 was expressed as two distinct fusion proteins in Escherichia coli and purified by column chromatography. Spectroscopic analysis of the purified NTD proteins shows them to be properly folded and capable of binding ligands. This methodology should not only facilitate the characterization of T1R ligand interactions but may also be useful for dissecting the function of other class C GPCRs such as the large family of orphan V2R vomeronasal receptors.     

In vitro assessment of the selectivities of various beta-adrenergic blocking agents

Intrinsic sympathomimetic- and membrane activities of beta-adrenoceptor blocking agents are of little or no clinical significance. A selective blockade of cardiac receptors has important therapeutic consequences, especially in the treatment of patients with obstructive airways diseases. Profound depression of miocardial contractility can be deleterious in patients with cardiac muscle damage and the use of beta-adrenergic blockers with a quantitative selectivity towards chronotropism may become an important consideration. The effects of a number of beta-sympatholytics have been determined on isolated cardiac preparations (beta₁-adrenergic receptors) and tracheal preparations (beta₂-adrenergic receptors) of guinea-pigs. Results indicate that prindolol is the most selective blocker of the beta₁ chronotropic receptors whilst atenolol could be classified as being the most cardioselective beta-adrenergic blocker investigated. Butoxamine, on the other hand, proved to be the most beta₂-selective one.     

Sequence,Structure and Ligand Binding Evolution of Rhodopsin-Like G Protein-Coupled Receptors: A Crystal Structure-Based Phylogenetic Analysis

G protein-coupled receptors (GPCRs) form the largest family of membrane receptors in the human genome. Advances in membrane protein crystallization so far resulted in the determination of 24 receptors available as high-resolution atomic structures. We performed the first phylogenetic analysis of GPCRs based on the available set of GPCR structures. We present a new phylogenetic tree of known human rhodopsin-like GPCR sequences based on this structure set. We can distinguish the three separate classes of small-ligand binding GPCRs, peptide binding GPCRs, and olfactory receptors. Analyzing different structural subdomains, we found that small molecule binding receptors most likely have evolved from peptide receptor precursors, with a rhodopsin/S1PR1 ancestor, most likely an ancestral opsin, forming the link between both classes. A light-activated receptor therefore seems to be the origin of the small molecule hormone receptors of the central nervous system. We find hints for a common evolutionary path of both ligand binding site and central sodium/water binding site. Surprisingly, opioid receptors exhibit both a binding cavity and a central sodium/water binding site similar to the one of biogenic amine receptors instead of peptide receptors, making them seemingly prone to bind small molecule ligands, e.g. opiates. Our results give new insights into the relationship and the pharmacological properties of rhodopsin-like GPCRs.     

LDL receptor-related proteins in neurodevelopment

Low-density lipoprotein receptor-related proteins (LRPs) are evolutionarily ancient cell-surface receptors with diverse biological functions. All are expressed in the central nervous system and, for most receptors, animal models have shown that they are indispensable for successful neurodevelopment. The mechanisms by which they regulate the formation of the nervous system are varied and include the transduction of extracellular signals and the modulation of intracellular signal propagation, as well as cargo transport, the function most commonly attributed to this gene family. Here, we will summarize recent advances in our understanding of the molecular basis on which these receptors function during development .     

Toll样受体与肿瘤免疫

Toll样受体(Toll-like receptor)是天然免疫系统中最重要的模式识别受体,在病原体感染过程中对入侵病原体的识别,激活免疫应答起重要作用。近年发现Toll样受体在多种肿瘤的发生过程中起重要的调控作用。Toll样受体在肿瘤细胞中具有表达,并且Toll样受体信号诱导的促炎症反应是肿瘤发生的必要条件,但是有些Toll样受体的配体仍然表现出极强的抗肿瘤活性,目前,Toll样受体在肿瘤免疫中的机制研究已经成为Toll样受体作为药物靶点的临床应用的关键。本文对Toll样受体在肿瘤免疫中的机制进行综述。     

Neuronal nAChR stereoselectivity to non-natural epibatidine derivatives

The frog toxin epibatidine is one of the most powerful ligands of the neuronal nicotinic receptors and derivatives show promising possibilities for labeling in positron emission tomography studies. In an attempt to reduce epibatidine toxicity, new methyl derivatives were synthesized, tested in positron emission tomography imaging and in electrophysiology. labeling as well as physiological experiments highlighted the differences in sensitivity of the neuronal nicotinic acetylcholine receptors between two methyl enantiomers and the reduction in sensitivity caused by introducing the methyl group. At present, epibatidine derivatives seem the most promising compounds for in vivo labeling of neuronal nicotinic acetylcholine receptors.     

Acetylcholine receptor clustering and triton solubility: neural effect

Previous studies by Prives et al. (1980, 1982a and b) have shown that acetylcholine receptors (AchRs) are extracted from muscle cells in vitro by Triton X-100 at different rates, and that clustered receptors extract most slowly. The present study was aimed at comparing the relative extractability of receptors in clusters with those in intercluster regions and the role of neural factors in regulating this extractability. Using primary rat muscle cells in vitro we confirmed that receptor extraction with Triton X-100 does not fit a single exponential but has more than one rate, and that in control cells clustered receptors extract more slowly than do receptors in intercluster regions. The major new observation in this study was that neural extract lowered the overall Triton extraction rate of intercluster receptors to that of clustered receptors. Additional new observations include the findings that (1) both clustered and intercluster receptors show multiphasic extraction rates; (2) stabilization of AchRs against Triton extraction increases with time in the surface membrane; (3) the effect of neural extract on Triton extractability of AChR is dependent on factors that control RNA synthesis, cytoskeletal elements, and collagen; (4) fixation and/or buffer washes accelerate receptor extraction only in cells that are treated with Triton, but not in control cells; (5) in control cells (not exposed to neural factors) Triton X-100 causes new clusters to form. From experiments using Con A we suggest that the Triton-induced new clusters may not be formed by a redistribution of receptors but are, most likely, due to the presence of groups of intercluster receptors with extraction rates lower than those of surrounding receptors.     

Appearance of acetylcholine receptors in cultured myoblasts prior to fusion

The development of the acetycholine receptors in chick embryo myoblasts from 11-day old embryos was studied in vitro. Using the purified α-bungarotoxin labeled with radioactive iodide, a high concentration of acetylcholine receptors was found in the prefusing myoblasts; most of these receptors were located in the interior of the myoblasts. However, upon the completion of myoblast fusion, the majority of the acetylcholine receptors appeared on the external cell surface of the myotubes.     

Effect of adenosine-5'-O-(beta, gamma-dichloromethane)triphosphate on ATP-activated currents in sensory neurons in rats

The action of beta,gamma-dihalogenmethane derivatives of ATP on ATP receptors has been studied in the sensory neurons of rats. beta,gamma-Dichloromethane-ATP and beta,gamma-dibromomethane-ATP are competitive blockers and beta,gamma-difluoromethane-ATP is a partial agonist of ATP receptors. At present, beta,gamma-dichloromethane-ATP is the most efficient of the known competitive blockers of these receptors (Ki = 2.10(-5) M). The data obtained confirm that beta- and gamma-phosphates of ATP play an important role in the activation of ATP receptors.     

Ultrastructure and chaetotaxy of sensory receptors in the cercaria of a species of Allopodocotyle Pritchard, 1966 (Digenea: Opecoelidae)

Previous investigations of sensory systems in opecoelid cercariae have focused on chaetotaxy and ultrastructure of sensory receptors. They revealed chaetotaxic patterns within family, genus, and species as well as different receptors. Chaetotaxic and ultrastructural observations have rarely been combined. We investigated the ultrastructure of cercarial sensory receptors in conjunction with chaetotaxy and neuromorphology in a species of Allopodocotyle. Cercariae were treated with acetylthiocholine iodide and silver nitrate, and some were processed for light, scanning (SEM), and transmission (TEM) electron microscopy. Five nerve regions were distinguished. Chaetotaxy was consistent with that of other opecoelids. Five types of receptors were distinguished with SEM. Types differed in number of cilium-like structures (one or more), length of cilium-like structure (short, moderately long, or long), presence or absence of a tegumentary collar, and length of tegumentary collar (low, moderately low, or very high). Internal ultrastructure of some types revealed unsheathed cilium-like structures, basal body, and thickened nerve collars. Possible subtegumentary and sheathed receptors are introduced. Some receptor types were site-specific. For example, receptors with multiple cilium-like structures were concentrated on cephalic region whereas receptors with short cilium-like structure were widespread throughout most regions. Ultrastructure and site-specificity observations suggest that most receptors are mechanoreceptors.     

The cell biology of thrombospondin-1.

Thrombospondin-1 (TSP-1) is a matricellular protein that regulates cellular phenotype during tissue genesis and repair. It acts as a molecular facilitator by bringing together cytokines, growth factors, matrix components, membrane receptors and extracellular proteases. TSP-1 binds to a wide variety of integrin and non-integrin cell surface receptors. The binding sites for these receptors on TSP-1 are dispersed throughout the molecule, with most domains binding multiple receptors. In some cases, TSP-1 binds to multiple receptors concurrently, and recent data indicate that there is cross-talk between the receptor systems. Thus, TSP-1 may function to direct the clustering of receptors to specialized domains for adhesion and signal transduction.     

前列腺素E分子网络对哺乳动物生殖的调控

磷脂酶A2、环氧合酶以及前列腺素E合成酶是前列腺素E合成途径中顺序起作用的重要酶类,其中前列腺素E合成酶有两种不同的亚型,分别介导不同的前列腺素E合成反应。前列腺素E可与其受体特异性结合,并通过旁分泌和自分泌两种形式调节细胞反应,参与多种生理过程。近来研究发现,前列腺素E受体不仅存于质膜,而在核膜上也大量存在。前列腺素E核受体介导的信号转导途径与膜受体介导的信号途径不同,对于基因转录的调控机制也不同。本文综述并探讨了上述分子所组成的网络系统在哺乳动物生殖,尤其是雌性生殖过程中所发挥的重要作用。