Cloning of the cDNA and Genes for the Hamster and Human β2-Adrenergic Receptors

Abstract

The adenylate cyclase-stimulatory β₂-adrenergic receptor has been purified to apparent homogeneity from hamster lung. Partial amino acid sequence obtained from isolated CNBr peptides was used to clone the gene and cDNA for this receptor. The predicted amino acid sequence for the hamster β₂-adrenergic receptor revealed that the protein consists of a single polypeptide chain of 418 aa with consensus N-glycosylation and phosphorylation sites predicted by previous in vitro data. The most striking feature of the receptor protein however, is that it contains seven stretches of hydrophobic residues similar to the proposed seven transmembrane segments of the light receptor rhodopsin. Significant amino acid homology (30-35%) can be found between the hamster β₂-adrenergic receptor and rhodopsin within these putative membrane spanning regions. Using a hamster β₂-adrenergic receptor probe, the gene and cDNA for the human β₂-adrenergic receptor were isolated, revealing a high degree of homology (87%) between the two proteins from different species. Unlike the genes encoding the family of opsin pigments, of which rhodopsin is a member, the genes encoding both hamster and human β₂-adrenergic receptors are devoid of introns in their coding as well as 5′ and 3′ untranslated nucleotide sequences. The cloning of the genes and the elucidation of the aa sequences for these G-protein coupled receptors should help to determine the structure-function as well as the evolutionary relationship of these proteins.     

The kinetics and mechanism of the reaction of 2′-deoxy-5′-guanosinemonophosphoric acid and the diaqua form of cis-platin

2′-Deoxy-5′-guanosinemonosphoric acid (B) reacts with cis-[Pt(NH₃)₂(OH₂)₂]²⁺ in two steps to form the cis-[Pt(NH₃)₂B₂]^y+ ion. In the first step 2′-d-5′- GMPH₂ reacts some ten times faster than 5′-GMPH₂ does. Rate constants, ΔH^#, ΔS^# and ΔV^# are very similar for the two bases in the second reaction. It is proposed that the product in the first step contains no water and is cis-[Pt(NH₃)₂B]^x+ in which the nucleobase is bidentate bonding through both N(7) of guanine and an oxygen atom of the phosphate group.     

Investigations on the genetics and population genetics of the β2 polymorphism

Summary The results of studies on 49 families with 107 children and various populations of Caucasoid, Negroid and Mongoloid origin concerning the genetics and population genetics of the ₂-glycoprotein I polymorphism are reported. In general the genetical model proposed by Cleve (1968) is confirmed: two autosomal alleles Bg^N and Bg^D controlling the phenotypes Bg N-N, Bg N-D and Bg D-D. However, divergences from this model were found in two families. They indicate the assumption of non-genetic factors influencing the phenotype expression rather than more complicated genetical control mechanisms. Within Caucasoid populations phenotype and gene frequencies show almost a homogeneous distribution. This racial stock is striking due to a significant higher ₂-glycoprotein I concentration in serum as compared to Negroids and Mongoloids. In connection with this, these racial stocks differ obviously in the gene frequencies: Caucasoids Bg^N=0.937, Negroids=0.742, Mongoloids =0.780; resp. Bg^D=0.063, 0.258, 0.220.Supported by the Deutsche Forschungsgemeinschaft.D 77.     

Physical and functional interaction of the active zone protein CAST/ERC2 and the β-subunit of the voltage-dependent Ca(2+) channel

In the nerve terminals, the active zone protein CAST/ERC2 forms a protein complex with the other active zone proteins ELKS, Bassoon, Piccolo, RIM1 and Munc13-1, and is thought to play an organizational and functional role in neurotransmitter release. However, it remains obscure how CAST/ERC2 regulates the Ca(2+)-dependent release of neurotransmitters. Here, we show an interaction of CAST with voltage-dependent Ca(2+) channels (VDCCs), which are essential for regulating neurotransmitter release triggered by depolarization-induced Ca(2+) influx at the active zone. Using a biochemical assay, we showed that CAST was coimmunoprecipitated with the VDCC β(4)-subunit from the mouse brain. A pull-down assay revealed that the VDCC β(4)-subunit interacted directly with at least the N- and C-terminal regions of CAST. The II-III linker of VDCC α(1)-subunit also interacted with C-terminal regions of CAST; however, the interaction was much weaker than that of β(4)-subunit. Furthermore, coexpression of CAST and VDCCs in baby hamster kidney cells caused a shift in the voltage dependence of activation towards the hyperpolarizing direction. Taken together, these results suggest that CAST forms a protein complex with VDCCs, which may regulate neurotransmitter release partly through modifying the opening of VDCCs at the presynaptic active zones.     

Roles of yeast eIF2α and eIF2β subunits in the binding of the initiator methionyl-tRNA

Heterotrimeric eukaryotic/archaeal translation initiation factor 2 (e/aIF2) binds initiator methionyl-tRNA and plays a key role in the selection of the start codon on messenger RNA. tRNA binding was extensively studied in the archaeal system. The γ subunit is able to bind tRNA, but the α subunit is required to reach high affinity whereas the β subunit has only a minor role. In Saccharomyces cerevisiae however, the available data suggest an opposite scenario with β having the most important contribution to tRNA-binding affinity. In order to overcome difficulties with purification of the yeast eIF2γ subunit, we designed chimeric eIF2 by assembling yeast α and β subunits to archaeal γ subunit. We show that the β subunit of yeast has indeed an important role, with the eukaryote-specific N- and C-terminal domains being necessary to obtain full tRNA-binding affinity. The α subunit apparently has a modest contribution. However, the positive effect of α on tRNA binding can be progressively increased upon shortening the acidic C-terminal extension. These results, together with small angle X-ray scattering experiments, support the idea that in yeast eIF2, the tRNA molecule is bound by the α subunit in a manner similar to that observed in the archaeal aIF2–GDPNP–tRNA complex.     

Effects of pH and temperature on the survival of coliphages MS2 and Qβ

The RNA F-specific coliphages, MS2 and Q, have been used as virus indicators in water and wastewater studies. It is therefore useful to have a good understanding concerning the effects of environmental factors on their survival in order to choose an appropriate candidate for assessing microbial safety in relation to water quality management. The effects of pH and temperature on the survival of these two coliphages were investigated. MS2 survived better in acidic conditions than in an alkaline environment. In contrast, Q had a better survival rate in alkaline conditions than in an acidic environment. The inactivation rates of both coliphages were lowest within the pH range 6–8 and the temperature range 5–35°C. The inactivation rates of both coliphages increased when the pH was decreased to below 6 or increased to above 8. The inactivation rates of both coliphages increased with increasing temperature. Q behaved peculiarly in extreme pH buffers, i.e. it was inactivated very rapidly initially when subjected to an extreme pH environment, although the inactivation rate subsequently decreased. In general, MS2 was a better indicator than Q. However, within the pH range 6–9 and at temperatures not above 25°C, either MS2 or Q could be used as a viral indicator.     

Both Intra- and Extracellular Ca2+ Participate in the Regulation of the Lateral Diffusion of the PDGF-β2 Receptor

When the receptors for platelet-derived growth factor (PDGF) are activatedthey aggregate, become tyrosine-phosphorylated and elicit a cascade ofdown-stream signals, including mobilization of Ca²⁺ from intra- andextracellular stores. Receptor mobility in the plane of the membrane isa prerequisite for receptor aggregation and further signalling. Using humanforeskin fibroblasts (AG 1523) and fluorescence recovery afterphotobleaching (FRAP), we therefore assessed the lateral mobilitycharacteristics of PDGF-2 receptors by their diffusioncoefficient (D), and fraction of mobile receptors (R). This was done oncells stimulated with either normal human serum (NHS) or PDGF underdifferent Ca²⁺-conditions.The results suggest that both intra- and extracellular free Ca²⁺influence the mobility characteristics of the PDGF-2receptor. Interestingly, the extracellular Ca²⁺ seems to imposegeneral restrictions on the mobility of receptors, since R increased whenextracellular Ca²⁺ was quenched with EGTA, whereas intracellularclamping of Ca²⁺ transients with MABTAM (BAPT/AM) primarily affectedD. When both intra- and extracellular Ca²⁺ were quenced, D remainedlow and R high, further supporting the proposition that they achievedistinct effects. Inhibition of tyrosine phosphorylation with Erbstatin,partly inhibited the NHS effects and released PDGF-induced receptorimmobilization. Ratio imaging with Fura-2 displayed that both NHS and PDGFinduced changes in intracellular free [Ca²⁺]. In view of the presentdata it might have important effects on the state of the receptor in themembrane, for instance by regulating its lateral mobility, communicationwith other receptors and signalling functions in the membrane.     

Kinetics of renaturation and self-assembly of intermediates on the pathway of folding of the β2-subunit of Escherichia coli tryptophan-synthetase

The kinetics of renaturation of the β₂-subunit of Escherichia coli tryptophan-synthetase (l-serine hydrolyase (adding indole) E.C. 4.2.1.20) and those of its two proteolytic fragments F₁ and F₂ are studied and compared. Steps corresponding to the refolding of F₁, to the association of the folded F₁ and F₂ fragments, and to an isomerization of the associated protein are identified. These steps are ordered on the pathway of renaturation and some of their kinetic parameters are determined. This leads to a tentative kinetic model for the renaturation of nicked-β₂ starting from the denatured F₁ and F₂ fragments.The step corresponding to the refolding of the F₁ domain, as well as that corresponding to the last rate-limiting isomerization leading to the native protein, is shown to be the same in the refolding of the entire, uncleaved β₂-protein. It is concluded that the refolded F₁ fragment corresponds to a folding intermediate on the pathway of renaturation of the β₂-subunit.     

Ubiquitylation of ε-COP by PIRH2 and regulation of the secretion of PSA

Ubiquitylation appears to be involved in the membrane trafficking system including endocytosis, exocytosis, and ER-to-Golgi transport. We found that PIRH2, which was identified as an interacting protein for androgen receptor or p53, interacts with and ubiquitylates the ε-subunit of coatmer complex, ε-COP. PIRH2 promotes the ubiquitylation of ε-COP in vitro and in vivo and consequently promotes the degradation of ε-COP. The interaction between PIRH2 and ε-COP is affected by the presence of androgen, and PIRH2 in the presence of androgen promotes ubiquitylation of ε-COP in vivo. Furthermore, overexpression of the wild type of PIRH2 in prostate cancer cells causes downregulation of the secretion of prostate-specific antigen (PSA), a secretory protein in prostate epithelial cells and one of diagnostic markers for prostate cancer. Our results indicate that PIRH2 functions as a regulator for COP I complex.     

Molecular dynamics simulations of the effect of the G-protein and diffusible ligands on the β2-adrenergic receptor

G-protein-coupled receptors have extraordinary therapeutic potential as targets for a broad spectrum of diseases. Understanding their function at the molecular level is therefore essential. A variety of crystal structures have made the investigation of the inactive receptor state possible. Recently released X-ray structures of opsin and the β₂-adrenergic receptor (β₂AR) have provided insight into the active receptor state. In addition, we have contributed to the crystal structure of an irreversible agonist-β₂ adrenoceptor complex. These extensive studies and biophysical investigations have revealed that agonist binding leads to a low-affinity conformation of the active state that is suggested to facilitate G-protein binding. The high-affinity receptor state, which promotes signal transduction, is only formed in the presence of both agonist and G-protein. Despite numerous crystal structures, it is not yet clear how ligands tune receptor dynamics and G-protein binding. We have now used molecular dynamics simulations to elucidate the distinct impact of agonist and inverse agonist on receptor conformation and G-protein binding by investigating the influence of the ligands on the structure and dynamics of a complex composed of β₂AR and the C-terminal end of the Gα_s subunit (GαCT). The simulations clearly showed that the agonist isoprenaline and the inverse agonist carazolol influence the ligand-binding site and the interaction between β₂AR and GαCT differently. Isoprenaline induced an inward motion of helix 5, whereas carazolol blocked the rearrangement of the extracellular part of the receptor. Moreover, in the presence of isoprenaline, β₂AR and GαCT form a stable interaction that is destabilized by carazolol.     

Structural and functional analysis of the flexible regions of the catalytic α-subunit of protein kinase CK2

CK2 is a Ser/Thr protein kinase essential for cell viability. Its activity is anomalously high in several solid (prostate, mammary gland, lung, kidney and head and neck) and haematological tumours (AML, CML and PML), creating conditions favouring the onset of cancer. Cancer cells become addicted to high levels of CK2 activity and therefore this kinase is a remarkable example of "non-oncogene addiction". CK2 is a validated target for cancer therapy with one inhibitor in phase I clinical trials. Several crystal structures of CK2 are available, many in complex with ATP-competitive inhibitors, showing the presence of regions with remarkable flexibility. We present the structural characterisation of these regions by means of seven new crystal structures, in the apo form and in complex with inhibitors. We confirm previous findings about the unique flexibility of the CK2α catalytic subunit in the hinge/αD region, the p-loop and the β4β5 loop, and show here that there is no clear-cut correlation between the conformations of these flexible zones. Our findings challenge some of the current interpretations on the functional role of these regions and dispute the hypothesis that small ligands stabilize an inactive state. The mobility of the hinge/αD region in the human enzyme is unique among protein kinases, and this can be exploited for the development of more selective ATP-competitive inhibitors. The identification of different ligand binding modes to a secondary site can provide hints for the design of non-ATP-competitive inhibitors targeting the interaction between the α catalytic and the β regulatory subunits.     

Mitochondrial Ca2+, the secret behind the function of uncoupling proteins 2 and 3?

The underlying molecular action of the novel uncoupling proteins 2 and 3 (UCP2 and UCP3) is still under debate. The proteins have been implicated in many cell functions, including the regulation of insulin secretion and regulation of reactive oxygen species (ROS) generation. These effects have mainly been explained by suggesting that the proteins establish a proton leak through the inner mitochondrial membrane (IMM). However, accumulating data question this mechanism and suggest that UCP2 and UCP3 may play other roles, including carrying free fatty acids from the matrix towards the intermembrane space, or contributing to the mitochondrial Ca(2+) uniport. Accordingly, in this review we reflect on these actions of UCP2/UCP3 and discuss alternative explanations for the molecular mechanisms by which UCP2/UCP3 might contribute to aspects of cell function. Based on the potential role of UCP2/UCP3 in regulating mitochondrial Ca(2+) uptake, we propose a scheme whereby these proteins integrate Ca(2+)-dependent signal transduction and energy metabolism in order to meet the energy demand of the cell for its continuous response, adaptation, and stimulation to environmental input.     

Penam Sulfones and β-Lactamase Inhibition: SA2-13 and the Importance of the C2 Side Chain Length and Composition

β-Lactamases are the major reason β-lactam resistance is seen in Gram-negative bacteria. To combat this resistance mechanism, β-lactamase inhibitors are currently being developed. Presently, there are only three that are in clinical use (clavulanate, sulbactam and tazobactam). In order to address this important medical need, we explored a new inhibition strategy that takes advantage of a long-lived inhibitory trans-enamine intermediate. SA2-13 was previously synthesized and shown to have a lower k _react than tazobactam. We investigated here the importance of the carboxyl linker length and composition by synthesizing three analogs of SA2-13 (PSR-4-157, PSR-4-155, and PSR-3-226). All SA2-13 analogs yielded higher turnover numbers and k _react compared to SA2-13. We next demonstrated using protein crystallography that increasing the linker length by one carbon allowed for better capture of a trans-enamine intermediate; in contrast, this trans-enamine intermediate did not occur when the C2 linker length was decreased by one carbon. If the linker was altered by both shortening it and changing the carboxyl moiety into a neutral amide moiety, the stable trans-enamine intermediate in wt SHV-1 did not form; this intermediate could only be observed when a deacylation deficient E166A variant was studied. We subsequently studied SA2-13 against a relatively recently discovered inhibitor-resistant (IR) variant of SHV-1, SHV K234R. Despite the alteration in the mechanism of resistance due to the K→R change in this variant, SA2-13 was effective at inhibiting this IR enzyme and formed a trans-enamine inhibitory intermediate similar to the intermediate seen in the wt SHV-1 structure. Taken together, our data reveals that the C2 side chain linker length and composition profoundly affect the formation of the trans-enamine intermediate of penam sulfones. We also show that the design of SA2-13 derivatives offers promise against IR SHV β-lactamases that possess the K234R substitution.     

Autophosphorylation of heme-regulated eukaryotic initiation factor 2α kinase and the role of the modification in catalysis

Heme-regulated eukaryotic initiation factor 2α (eIF2α) kinase (HRI), functions in response to heme shortage in reticulocytes and aids in the maintenance of a heme:globin ratio of 1:1. Under normal conditions, heme binds to HRI and blocks its function. However, during heme shortage, heme dissociates from the protein and autophosphorylation subsequently occurs. Autophosphorylation comprises a preliminary critical step before the execution of the intrinsic function of HRI; specifically, phosphorylation of Ser-51 of eIF2α to inhibit translation of the globin protein. The present study indicates that dephosphorylated mouse HRI exhibits strong intramolecular interactions (between the N-terminal and C-terminal domains) compared to phosphorylated HRI. It is therefore suggested that autophosphorylation reduces the intramolecular interaction, which induces irreversible catalytic flow to the intrinsic eIF2α kinase activity after heme dissociates from the protein. With the aid of MS, we identified 33 phosphorylated sites in mouse HRI overexpressed in Escherichia coli. Phosphorylated sites at Ser, Thr and Tyr were predominantly localized within the kinase insertion region (16 sites) and kinase domain (12 sites), whereas the N-terminal domain contained five sites. We further generated 30 enzymes with mutations at the phosphorylated residues and examined their catalytic activities. The activities of Y193F, T485A and T490A mutants were significantly lower than that of wild-type protein, whereas the other mutant proteins displayed essentially similar activity. Accordingly, we suggest that Tyr193, Thr485 and Thr490 are essential residues in the catalysis.     

Isograft and xenograft of the subcommissural organ into the lateral ventricle of the rat and the formation of Reissner’s fiber

The subcommissural organ (SCO) secretes glycoproteins into the cerebrospinal fluid (CSF) that aggregate and form Reissner's fiber (RF). The factors involved in this aggregation are not known. One factor may be the hydrodynamics of the CSF when flowing through the aqueduct. This hypothesis was tested by isografting rat SCO and xenografting bovine SCO into the lateral ventricle of rats. Xenografts were either fresh bovine SCO or explants cultured for 30 days before transplantation. The grafts were investigated by electron microscopy and immunocytochemistry using antibodies against RF glycoproteins, serotonin and the glucose transporter I. Maximal time of transplantation was 43 days for isografts and 14 days for xenografts. The isografts were not reinnervated but were revascularized; they secreted into the ventricle RF glycoproteins that became progressively packed into pre-RF and RF structures identical to those formed by the SCO in situ. RF was confined to the host ventricle and at its distal end the constituent proteins disassembled. Xenografts were neither reinnervated nor revascularized and secreted into the host ventricle a material that never formed an RF. These findings indicate that the CSF factor responsible for the formation of RF is species specific, and that this process does not depend on the hydrodynamics of the CSF. The blood vessels revascularizing the isografted SCO acquired the characteristics of the vessels irrigating the SCO in situ, namely, a tight endothelium displaying glucose transporter I, and a perivascular space containing long-spacing collagen, thus indicating that basal release of glycoproteins may also occur in the grafted SCO.     

Hydroxylysine in the N-terminal regions of the α1- and α2-chains of various collagens

The degree of hydroxylation of the lysine residue located in both alpha(1)- and alpha(2)-chains of collagen in the N-terminal, non-helical telopeptide region of the molecule has been determined in collagen from various sources after isolation of the peptides (alpha(1)- and alpha(2)-CB1) that contain the lysine residue in question and are obtained by cyanogen bromide cleavage of collagen alpha(1)- and alpha(2)-chains respectively. As with collagen from chick tibia, bone collagens from rat tibia and femur and embryonic chick frontal bone, have a high degree of hydroxylation (approx. 50% or more) of the lysine residue in both alpha(1)- and alpha(2)-CB1 peptides. This is in contrast with the lack of hydroxylation of this residue in both alpha(1)- and alpha(2)-chains of all skin collagens so far examined. The presence of hydroxylysine in alpha(1)- and alpha(2)-CB1 peptides from tendon collagen is also indicated. In rat tail tendon collagen the amount of hydroxylation is only slight but in the much less soluble tendon collagen from embryonic chick leg tendons, approximately one-third of the lysine is hydroxylated.     

Phylogeography of the harlequin beetle-riding pseudoscorpion and the rise of the Isthmus of Panamá

Molecular and geological evidence indicates that the emergence of the Isthmus of Panamá influenced the historical biogeography of the Neotropics in a complex, staggered manner dating back at least 9 Myr bp. To assess the influence of Isthmus formation on the biogeography of the harlequin beetle-riding pseudoscorpion, Cordylochernes scorpioides, we analysed mitochondrial COI sequence data from 71 individuals from 13 locations in Panamá and northern South America. Parsimony and likelihood-based phylogenies identified deep divergence between South American and Panamanian clades. In contrast to low haplotype diversity in South America, the Panamanian Cordylochernes clade is comprised of three highly divergent lineages: one clade consisting predominantly of individuals from central Panamá (PAN A), and two sister clades (PAN B1 and PAN B2) of western Panamanian pseudoscorpions. Breeding experiments demonstrated a strictly maternal mode of inheritance, indicating that our analyses were not confounded by nuclear-mitochondrial pseudogenes. Haplotype diversity is striking in western Atlantic Panamá, where all three Panamanian clades can occur in a single host tree. This sympatry points to the existence of a cryptic species hybrid zone in western Panamá, a conclusion supported by interclade crosses and coalescence-based migration rates. Molecular clock estimates yield a divergence time of approximately 3 Myr between the central and western Panamanian clades. Taken together, these results are consistent with a recent model in which a transitory proto-Isthmus enabled an early wave of colonization out of South America at the close of the Miocene, followed by sea level rise, inundation of the terrestrial corridor and then a second wave of colonization that occurred when the Isthmus was completed approximately 3 Myr bp.