Discrete amino acid sequences of the alpha 1-adrenergic receptor determine the selectivity of coupling to phosphatidylinositol hydrolysis.

We have constructed a variety of chimeric beta 2/alpha 1 adrenergic receptors (AR) in which selected portions of the third intracellular loop of the alpha (1B)AR were substituted into the corresponding regions of the beta 2AR. The mutant receptors were both transiently and permanently expressed in COS-7 or L-cells, respectively, and tested for their ability to mediate epinephrine-induced activation of polyphosphoinositide (PI) hydrolysis and adenylylcyclase. We have determined that 27 amino acids of the alpha (1B)AR (residues 233-259) derived from the N-terminal portion of the third intracellular loop represent the structural determinant conferring to the beta 2AR the ability to activate PI hydrolysis. This finding suggests that in the alpha (1B)AR the N-terminal portion of the third intracellular loop plays a major role in determining the selectivity of receptor-G protein coupling. However, replacement of alpha 1B sequences in the third intracellular loop of the beta 2AR did not abolish the latter receptor's coupling to activation of adenylylcyclase, thus resulting in chimeric adrenergic receptors which activated both PI hydrolysis and adenylylcyclase. These results indicate that, even if the N-terminal portion of the third intracellular loop is a major determinant of the selectivity of receptor-G protein coupling, other structural domains of the receptors also modulate this property. The comparison of the amino acid sequences which determine the selectivity of G protein coupling in functionally similar receptors may help to elucidate the structural basis for activation of specific G protein-effector systems.     

Genetic analysis of the molecular basis for beta-adrenergic receptor subtype specificity

Pharmacological analysis of ligand binding to the beta-adrenergic receptor (beta AR) has revealed the existence of two distinct receptor subtypes (beta 1 and beta 2) which are the products of different genes. The predicted amino acid sequences of the beta 1 and beta 2 receptors differ by 48%. To identify the regions of the proteins responsible for determining receptor subtype, chimeras were constructed from domains of the human beta 1 and hamster beta 2 receptors. Analysis of the ligand-binding characteristics of these hybrid receptors revealed that residues in the middle portion of the beta AR sequence, particularly around transmembrane regions 4 and 5, contribute to the subtype specific binding of agonists. Smaller molecular replacements of regions of the hamster beta 2 AR with the analogous regions from the avian beta 1 AR, however, failed to identify any single residue substitution capable of altering the subtype specificity of the receptor. These data indicate that, whereas sequences around transmembrane regions 4 and 5 may contribute to conformations which influence the ligand-binding properties of the receptor, the subtype-specific differences in amine-substituted agonist binding cannot be attributed to a single molecular interaction between the ligand and any amino acid residue which is divergent between the beta 1 and beta 2 receptors.     

Coupling of a mutated form of the human beta 2-adrenergic receptor to Gi and Gs. Requirement for multiple cytoplasmic domains in the coupling process.

We constructed five genes encoding mutant human beta 2-adrenergic receptor sequence (beta 2AR) which contained 12-22 amino acid substitutions with corresponding sequence from the human alpha 2AAR in order to assess the receptor domains involved in Gs versus Gi recognition and coupling. Mutant beta 2AR with substitutions in the N (S1)- and C-terminal (S2) portions of the third intracellular loop, the proximal cytoplasmic tail (S3), and two combinations thereof (S2,3 and S1,2,3), were stably expressed in Chinese hamster fibrobasts (CHW-1102), as were the human beta 2AR and alpha 2AAR at comparable receptor levels. All mutant receptors with S2 substitutions (i.e. S2, S2,3, S1,2,3) were significantly (approximately 85%) uncoupled from Gs. Upon exposure to pertussis toxin, which uncouples receptors from Gi, S1,2,3 exhibited a 526 +/- 99% increase in agonist-stimulated adenylylcyclase activity compared with a 59 +/- 13% increase with the wild type receptor. This enhanced ability of S1,2,3 to interact with Gs following pertussis toxin treatment indicates that, in the absence of toxin exposure, substantial coupling occurs between the mutant receptor and Gi. Mutant beta 2AR bearing only one or two alpha 2AAR-substituted sequences showed no such enhancement. Forskolin-stimulated enzyme activities were increased by pertussis toxin treatment to similar degrees in all clones examined, indicating that the observed effects are confined to the receptor-mediated pathway. In the absence of GTP, competition binding experiments with S1,2,3, beta 2AR and alpha 2AAR revealed that approximately 40-50% of the receptors formed a high affinity binding state for agonist. Pertussis toxin treatment markedly reduced this to approximately 19% with S1,2,3, while having no effect on beta 2AR and completely eliminating high affinity agonist binding to alpha 2AAR. These results suggest that S1,2,3 interacts with Gi as well as Gs, and that receptor:G protein coupling requires the concerted participation of multiple cytoplasmic receptor domains.     

Genomic organization of adrenergic and serotonin receptors in the mouse: linkage mapping of sequence-related genes provides a method for examining mammalian chromosome evolution.

Five sequence-related genes encoding four adrenergic receptors and a serotonin receptor were localized to specific regions of four mouse chromosomes with respect to 11 other genetic markers. Linkage was established by the analysis of the haplotypes of 114 interspecific backcross mice. Adra2r (alpha 2-C10) and Adrb1r (beta 1) receptors mapped to the distal region of mouse chromosome 19. These genes were separated by 2.6 +/- 1.5 cM in a segment of mouse chromosome 19 that has a similar organization of these genes on the long arm of human chromosome 10. The Adra1r (alpha 1B), Adrb2r (beta 2), and Htra1 (5HT1A) genes mapped to proximal mouse chromosome 11, proximal mouse chromosome 18, and distal mouse chromosome 13, respectively. The organization of genes linked to these loci on regions of the three mouse chromosomes is consistent with the organization of homologous human genes on human chromosome 5. These findings further define the relationship of linkage groups conserved during the evolution of the mouse and human genomes. We have identified a region that may have been translocated during evolution and suggest that the human genomic organization of adrenergic receptors more closely resembles that of a putative primordial ancestor.     

Comparative expression of the human beta(2) and beta(3) adrenergic receptors in Saccharomyces cerevisiae

The beta(3) adrenergic receptor (beta(3)AR) is the predominant beta subtype in human brown adipocytes and is essential for regulating thermogenic lipolysis. To establish a novel experimental system for the biochemical analysis of this protein, we engineered several yeast strains. We show that the sterol background of the host strain greatly modulates the beta(3)AR expression but not in the same way as it modulates the beta(2) adrenergic receptor (beta(2)AR), the other main studied adipocyte subtype. The human beta(3)AR expressed in yeast is N-glycosylated but not phosphorylated. This latter characteristic distinguishes it from the beta(2)AR. We showed that both beta(2)AR and beta(3)AR follow the secretory pathway to the yeast plasma membrane (PM) and are degraded in the vacuole. In the yeast strains used in this work, the two receptors also share a common mechanism of direct signal transduction through the yeast G(alpha) protein, Gpa1p. These strains thus appear to be useful for biochemical and structural studies of the human beta(3)AR in an in vivo reconstitution system.     

The effect of pH on beta(2) adrenoceptor function. Evidence for protonation-dependent activation

The transition of rhodopsin from the inactive to the active state is associated with proton uptake at Glu(134) (1), and recent mutagenesis studies suggest that protonation of the homologous amino acid in the alpha(1B) adrenergic receptor (Asp(142)) may be involved in its mechanism of activation (2). To further explore the role of protonation in G protein-coupled receptor activation, we examined the effects of pH on the rate of ligand-induced conformational change and on receptor-mediated G protein activation for the beta(2) adrenergic receptor (beta(2)AR). The rate of agonist-induced change in the fluorescence of NBD-labeled, purified beta(2)AR was 2-fold greater at pH 6.5 than at pH 8, even though agonist affinity was lower at pH 6.5. This biophysical analysis was corroborated by functional studies; basal (agonist-independent) activation of Galpha(s) by the beta(2)AR was greater at pH 6.5 compared with pH 8.0. Taken together, these results provide evidence that protonation increases basal activity by destabilizing the inactive state of the receptor. In addition, we found that the pH sensitivity of beta(2)AR activation is not abrogated by mutation of Asp(130), which is homologous to the highly conserved acidic amino acids that link protonation to activation of rhodopsin (Glu(134)) and the alpha(1B) adrenergic receptor (Asp(142)).     

Extensive homologies between the methylated nucleotide sequences in several vertebrate ribosomal ribonucleic acids.

The methylated nucleotide sequences in the rRNA molecules of the following vertebrate cultured cells were compared: human (HeLa); hamster (BHK/C13); mouse (L); chick-embryo fibroblast; Xenopus laevis kidney. In each species the combined 18S, 28S and 5.8S molecules possess approx. 110-115 methyl groups, and the methylated oligonucleotides released after complete digestion of the rRNA by T1 ribonuclease encompass several hundred nucleotides. "Fingerprints" of the three mammalian methyl-labelled 18S rRNA species were qualitatively indistinguishable. "Fingerprints" of digests of 28S rRNA of hamster and mouse L-cells were extremely similar to those of HeLa cells, differing in one and three methylated oligonucleotides respectively. "Fingerprints" of methyl-labelled rRNA from chick and Xenopus strongly resembled those of mammals in most respects, but differed in several oligonucleotides in both 18S and 28S rRNA. At least some of the differences between "fingerprints" appear to be due to single base changes or to the presence or absence of methyl groups at particular points in the primary sequence. The findings strongly suggest that the methylated-nucleotide sequences are at least 95% homologous between the rRNA molecules of the two most distantly related vertebrates compared, man and Xenopus laevis.     

Fluorescent localization of the beta-adrenergic receptor on DDT-1 cells. Down-regulation by adrenergic agonists.

Continuous incubation of cultured cells with beta-adrenergic agonists results in the desensitization of adrenergic responsiveness accompanied by the down-regulation of cell surface beta-adrenergic receptors (beta AR). Previous studies have relied on measurements of ligand binding activity for the detection of the beta AR in the cell. In the present study, we have raised a monoclonal antibody to a synthetic peptide corresponding to amino acid numbers 226-239 of the hamster beta 2AR. This antibody was used to localize the beta AR in hamster smooth-muscle DDT-1 cells by immunofluorescence, without regard for the ability of the receptor to bind ligands. The beta AR was found to be localized primarily at the plasma membrane of these cells, with a nonhomogeneous pattern of distribution. A rapid loss of beta AR-specific immunofluorescence, which paralleled receptor down-regulation as measured by ligand-binding activity, was seen with beta-adrenergic agonists, but not with antagonists. In addition, a transient increase in fluorescence was observed after short times of exposure of the cells to agonists. This fluorescence increase may reflect a ligand-induced conformational change in the receptor.     

Role of specific protein kinase C isoforms in modulation of beta1- and beta2-adrenergic receptors

The function of beta-adrenergic receptor (betaAR) is modulated by the activity status of alpha1-adrenergic receptors (alpha1ARs) via molecular crosstalk, and this becomes evident when measuring cardiac contractile responses to adrenergic stimulation. The molecular mechanism underlying this crosstalk is unknown. We have previously demonstrated that overexpression of alpha1B-adrenergic receptor (alpha1BAR) in transgenic mice leads to a marked desensitization of betaAR-mediated adenylyl cyclase stimulation which is correlated with increased levels of activated protein kinase C (PKC) beta, delta and [J. Mol. Cell. Cardiol. 30 (1998) 1827]. Therefore, we wished to determine which PKC isoforms play a role in heterologous betaAR desensitization and also which isoforms of the betaAR were the molecular target(s) for PKC. In experiments using constitutively activated PKC expression constructs transfected into HEK 293 cells also expressing the beta2AR, constitutively active (CA)-PKC overexpression was first confirmed by immunoblots using specific anti-PKC antibodies. We then demonstrated that the different PKC subtypes lead to a decreased maximal cAMP accumulation following isoproterenol stimulation with a rank order of PKCalpha > or = PKCzeta>PKC>PKCbetaII. However, a much more dramatic desensitization of adenylyl cyclase stimulation was observed in cells co-transfected with different PKC isoforms and beta1AR. Further, the modulation of beta1AR by PKC isoforms had a different rank order than for the beta2AR: PKCbetaII>PKCalpha>PKC>PKCzeta. PKC-mediated desensitization was reduced by mutating consensus cAMP-dependent protein kinase (PKA)/PKC sites in the third intracellular loop and/or the carboxy-terminal tail of either receptor. Our results demonstrate therefore that the beta1AR is the most likely molecular target for PKC-mediated heterologous desensitization in the mammalian heart and that modulation of adrenergic receptor activity in any given cell type will depend on the complement of PKC isoforms present.     

Differential distribution of the P1 and P2 protamine gene sequences in eutherian and marsupial mammals and a monotreme

At the protein level, the P1 protamine is the predominant form of mammalian protamine, present in all mammalian spermatozoa analyzed to date. An additional variant, the P2 protamine, has been detected only in spermatozoa of the mouse, hamster and human. Southern blot analysis of a group of restriction enzyme-digested mammalian DNAs has revealed the presence of sequences homologous to the P1 and the P2 mouse protamine genes in diverse species. In agreement with protein studies, nucleotide sequences homologous to the mouse P1 protamine cDNA are widespread, being present in the genomic DNAs of human, rat, dog, ram, horse, bull, hamster, baboon, flying fox (megabat), microbat, boar, North American opossum, and wallaby. Although we detect genomic sequences with strong homology to the mouse protamine 2 cDNA in rat and hamster, we also find weaker but reproducible hybridization to the genomic DNA of human, boar, dog, bull, microbat, wallaby, and platypus. With the exception of the human, the P2 protamine has not been detected in the spermatozoa of these latter species.     

Expression of major gap junction connexin types in the working myocardium of eight chordates.

The alpha1 connexin (connexin43) is regarded as the major gap junction protein of the myocardium because it predominates there in mammals. Here, we show that it is not the major connexin of the working myocardium in non-mammalian vertebrates, which instead express beta1-like connexins homologous to mammalian connexin32. A phylogenetic series of hearts was immunostained with seven antibodies raised against peptide sequences specific for three distinct members of the gap junction connexin family: alpha1, beta1 and alpha5 (mammalian connexin40/avian connexin42). Working myocardium from two ascidian chordates (Ciona and Mogula), a teleost (Carassius), a frog (Xenopus) and two reptiles (Anolis and Alligator) was found to express a beta1-like connexin, rather than an alpha1-like connexin. An alpha1-like connexin was nevertheless often detected in other cardiac tissues. In the chicken (by ancestry a reptile), the developing myocardium expressed a beta1-like connexin strongly on embryonic day 6 but less strongly at hatching, and minimally in the adult. Myocardial expression of alpha5 connexin increased during development, but remained strongest in the coronary vascular endothelial and cardiac conduction tissues. The arteriolar smooth muscle of the chicken expressed alpha1 connexin throughout development, but its myocardium did not. In contrast, the working myocardium of a marsupial mammal (the opossum Trichosurus) strongly expressed an alpha1 connexin just like placental mammals. These results imply that a shift from beta1 to alpha1 connexin expression in the heart occurred prior to the evolution of the opossums. The beta and alpha connexin subfamilies have different permeabilities and gating properties, and we discuss factors that might have made this shift beneficial.     

Construction of a human ventricular cDNA library and characterization of a beta myosin heavy chain cDNA clone

Summary We have constructed and characterized for the first time a complementary DNA (cDNA) clone, pHMC3, which codes for a cardiac myosin heavy chain mRNA from human heart. This clone contains a 1.7 kb DNA segment and specifies 543 amino acids of the carboxyl portion of the myosin heavy chain. The DNA sequence and encoded amino acid sequence were compared to the hamster alpha (pVHC1) and beta (pVHC2/pVHC3) cardiac myosin heavy chain cDNA and amino acid sequences and the rat cardiac myosin heavy chain sequences as well. The myosin heavy chain mRNAs are highly conserved and this is reflected in our cDNA clone. The pHMC3 clone is 87.9% homologous to the hamster alpha cDNA and 92.2% homologous to the hamster beta cDNA clones. The 3 untranslated region of pHMC3 is 64.1% homologous to the hamster beta clone while the hamster alpha myosin heavy chain shows only 25% homology to pHMC3 and exhibits extensive diversity. Similar results rere obtained when pHMC3 was compared to the rat cardiac myosin heavy chain cDNA sequences. The comparisons showed that pHMC3 is a beta cardiac myosin heavy chain cDNA clone.     

Antibodies to the conserved cytoplasmic domain of the integrin beta 1 subunit react with proteins in vertebrates, invertebrates, and fungi

The integrin family of cell surface receptors can be divided into three groups on the basis of their homologous beta subunits: beta 1, beta 2, and beta 3. We have raised an antibody against a synthetic peptide corresponding to the COOH-terminal domain of the chicken integrin beta 1 subunit that reacts with beta subunits from a variety of vertebrates, invertebrates, and fungi, demonstrating strong evolutionary conservation of sequences in this domain. In Drosophila cells, the antibody recognizes integrin alpha beta complexes that appear to be identical with position-specific antigens. Cross-reactive proteins are also detected in Caenorhabditis elegans and Candida albicans. The antiserum is specific for beta 1 subunits and does not recognize other integrin beta subunits in humans. In immunofluorescence analyses of cultured cells, the antibody reacts only with permeabilized cells confirming that this highly conserved COOH-terminal segment is a cytoplasmic domain.     

Adrenergic regulation of adipocyte metabolism

Adipocytes can be readily isolated from intact adipose tissue. In adipocytes from hamster and human white adipose tissue it is possible to demonstrate beta, alpha 1, and alpha 2 adrenoceptors. Alpha 2 adrenoceptor activation inhibits while beta adrenoceptor activation stimulates cyclic AMP accumulation and lipolysis. The effects of catecholamines on cyclic AMP accumulation are mediated through regulation of adenylate cyclase activity, which is activated through beta adrenoceptors and inhibited through alpha 2 adrenoceptors. Activation of alpha 1 adrenergic receptors has been shown to be associated with elevations of cytosol calcium and increased turnover of phosphatidylinositol. In white adipocytes, the only known alpha 1 adrenergic effects are inhibition of glycogen synthase and stimulation of glycogen phosphorylase via mechanisms distinct from those by which cyclic AMP produces similar end effects. In brown adipocytes, alpha 1 adrenoceptor activation stimulates respiration. Thyroid hormones primarily regulate the sensitivity of adipocytes to beta-adrenergic amines while having little effect on alpha adrenoceptor sensitivity.     

Resistance of the human beta1-adrenergic receptor to agonist-induced ubiquitination: a mechanism for impaired receptor degradation

Down-regulation is a classic response of most G protein-coupled receptors to prolonged agonist stimulation. We recently showed that when expressed in baby hamster kidney cells, the human beta1-but not the beta2-adrenergic receptor (AR) is totally resistant to agonist-mediated down-regulation, whereas both have similar rates of basal degradation (Liang, W., Austin, S., Hoang, Q., and Fishman, P. H. (2003) J. Biol. Chem. 278, 39773-39781). To identify the underlying mechanism(s) for this resistance, we investigated the role of proteasomes, lysosomes, and ubiquitination in the degradation of beta1AR expressed in baby hamster kidney and human embryonic kidney 293 cells. Both lysosomal and proteasomal inhibitors reduced beta1AR degradation in agonist-stimulated cells but were less effective on basal degradation. To determine whether beta1AR trafficked to lysosomes we used confocal fluorescence microscopy. We observed some colocalization of beta1AR and lysosomal markers in agonist-treated cells but much less than that of beta2AR even in cells co-transfected with arrestin-2, which increases beta1AR internalization. Ubiquitination of beta2AR readily occurred in agonist-stimulated cells, whereas ubiquitination of beta1AR was not detectable even under conditions optimal for that of beta2AR. Moreover, in cells expressing betaAR chimeras in which the C termini have been switched, the chimeric beta1AR with beta2AR C-tail underwent ubiquitination and down-regulation, but the chimeric beta2AR with beta1AR C-tail did not. Our results demonstrate for the first time that beta1AR and beta2AR differ in the ability to be ubiquitinated. Because ubiquitin serves as a signal for sorting membrane receptors to lysosomes, the lack of agonist-mediated ubiquitination of beta1AR may prevent its extensive trafficking to lysosomes and, thus, account for its resistance to down-regulation.     

Isolation and characterization of the third complement component of axolotl (Ambystoma mexicanum)

1. Using a monoclonal anti-human C3 antibody and a polyclonal anti-cobra venom factor antibody as probes, a protein homologous to the mammalian third complement component (C3) was purified from axolotl plasma and found to be axolotl C3. 2. Axolotl C3 consists of two polypeptide chains (Mr = 110,000 and 73,000) linked by disulfide bonds. An internal thiolester bond in the alpha chain was identified by the incorporation of [14C]methylamine and NH2-terminal sequence from the C3d fragment of C3. 3. Digestion of C3 by trypsin resulted in the cleavage of both the alpha and beta chains, generating fragments with a cleavage pattern similar to that of human C3. 4. The amino acid composition of axolotl C3 and the amino acid sequences of the thiolester site (and the surrounding amino acids), the cleavage site for the C3-convertase, and one of the factor I cleavage sites are similar to C3 from other vertebrates. 5. In contrast to human C3, which has concanavalin A binding carbohydrates on both the alpha and beta chains, only the beta chain of axolotl C3 contains such carbohydrates.     

Cadmium effects on ros production and DNA damage via adrenergic receptors stimulation: role of Na+/H+ exchanger and PKC

The objective of the present study was to elucidate the events that are involved in reactive oxygen species (ROS) production and DNA damage after adrenergic receptors stimulation by cadmium, in relation to cAMP, protein kinase C (PKC) and Na+/H+ exchanger (NHE). Cadmium (50 microM) caused increased levels of ROS with a concomitant increase in DNA damage in digestive gland of Mytilus galloprovincialis. Either the use of EIPA, a NHE blocker, or calphostin C, the inhibitor of PKC, reduced cadmium effects. Cells treated with alpha1-, alpha2-, beta- and beta1- adrenergic antagonists together with cadmium reversed cadmium alone effects, while the respective adrenergic agonists, phenylephrine and isoprenaline, mimic cadmium effects. Moreover, cadmium caused an increase in the levels of cAMP in digestive gland cells that were reversed after NHE and PKC inhibition as well as in the presence of each type of adrenergic antagonist. The different sensitivity of alpha1-, alpha2-, beta-, beta1- adrenergic receptors on ROS, cAMP production and DNA damage possibly leads to the induction of two signaling pathways that may be interacting or to the presence of a compensatory pathway that acts in concert with the alpha- and beta- adrenergic receptors. In these signaling pathways PKC and NHE play significant role.     

Heterodimerization of alpha 2A- and beta 1-adrenergic receptors

beta- and alpha(2)-adrenergic receptors are known to exhibit substantial cross-talk and mutual regulation in tissues where they are expressed together. We have found that the beta(1)-adrenergic receptor (beta(1)AR) and alpha(2A)-adrenergic receptor (alpha(2A)AR) heterodimerize when coexpressed in cells. Immunoprecipitation studies with differentially tagged beta(1)AR and alpha(2A)AR expressed in HEK-293 cells revealed robust co-immunoprecipitation of the two receptors. Moreover, agonist stimulation of alpha(2A)AR was found to induce substantial internalization of coexpressed beta(1)AR, providing further evidence for a physical association between the two receptors in a cellular environment. Ligand binding assays examining displacement of [(3)H]dihydroalprenolol binding to the beta(1)AR by various ligands revealed that beta(1)AR pharmacological properties were significantly altered when the receptor was coexpressed with alpha(2A)AR. Finally, beta(1)AR/alpha(2A)AR heterodimerization was found to be markedly enhanced by a beta(1)AR point mutation (N15A) that blocks N-linked glycosylation of the beta(1)AR as well as by point mutations (N10A/N14A) that block N-linked glycosylation of the alpha(2A)AR. These data reveal an interaction between beta(1)AR and alpha(2A)AR that is regulated by glycosylation and that may play a key role in cross-talk and mutual regulation between these receptors.