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A Conserved CCAP-signaling Pathway Controlling Ecdysis in a hemimetabolous insect, Rhodnius prolixusLee, Do Hee 10 January 2014 (has links)
In insects, ecdysis is an important feature of growth and development and is tightly controlled by a variety of neuropeptides. In holometabolous insects, crustacean cardioactive peptide (CCAP) is one of many factors that regulate ecdysis behaviours; however, not much is known about the control of ecdysis in hemimetabolous insects. In this thesis, the CCAP-signaling pathway is shown to be essential for successful ecdysis in the hemimetabolous insect, Rhodnius prolixus. The cDNA sequence of the CCAP gene has been cloned from the R. prolixus central nervous system (CNS) and the functional role of CCAP as a neuromodulator/neurotransmitter demonstrated. Specifically, the expression of RhoprCCAP in CNS neurons producing extensive CCAP-like immunoreactive processes within the neuropile indicates that CCAP plays central roles in coordination of other neurons. RhoprCCAP also acts as a neurohomone/neuromodulator released peripherally to coordinate many tissues. Thus, CCAP-like immunoreactive processes are found in neurohemal sites and also on peripheral tissues. The RhoprCCAP receptor (RhoprCCAPR) has been cloned and shown to be a G-protein coupled receptor (GPCR). RhoprCCAPR expression is observed in the CNS and certain peripheral tissues of R. prolixus. Also, CCAP stimulates hindgut contractions and increases the heartbeat rate in a dose-dependent manner. The involvement of CCAP in R. prolixus ecdysis has been investigated. Up-regulation of the RhoprCCAP transcript in the CNS and the RhoprCCAP receptor (RhoprCCAPR) transcript in the CNS and specific peripheral tissues was observed immediately prior to ecdysis. Also, decreasing staining intensity of CCAP-like immunoreactivity in neurons immediately following ecdysis indicates the release of CCAP during ecdysis. The critical importance of the CCAP-signalling pathway was further demonstrated by knockdown of the RhoprCCAP and RhoprCCAPR transcripts utilizing double stranded RNA interference. Insects with these transcripts knocked down have high mortality (up to 84%), typically at the expected time of ecdysis, or have ecdysis extremely delayed. Taken together, this thesis demonstrates that RhoprCCAP plays a crucial role in regulating ecdysis behaviours in R. prolixus, and clearly shows the conserved nature of the CCAP-signaling pathway in ecdysis for both holometabolous and hemimetabolous insects.
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Role of the G protein-coupled receptor kinase 2 in mediating transforming growth factor beta and G protein-coupled receptor signaling and crosstalk mechanismsMancini, Johanna. January 2007 (has links)
Transforming growth factor beta (TGFbeta) and Angiotensin II (AngII) signaling occurs through two distinct receptor superfamilies, the serine/threonine kinase and G protein-coupled receptors (GPCRs). Through diametric actions, TGFbeta and AngII regulate various biological responses, including cell proliferation and migration. Previously, we identified the G protein-coupled receptor kinase 2 (GRK2), which acts through a negative feedback loop mechanism to terminate Smad signaling. To investigate the impact of TGFbeta-induced GRK2 expression on GPCR signaling, we examined its effect on AngII signaling in vascular smooth muscle cells (VSMCs). We show that activation of the TGFbeta signaling cascade results in increased GRK2 expression levels, consequently inhibiting AngII-induced ERK phosphorylation and antagonizing AngII-induced VSMC proliferation and migration. The inhibitory effect of TGFbeta on AngII signaling occurs at the MEK-ERK interface and is abrogated when an anti-sense oligonucleotide directed against GRK2 is used. Thus, we conclude that TGFbeta signaling antagonizes AngII-induced VSMC proliferation and migration through the inhibition of ERK phosphorylation. GRK2 is a key factor in mediating this crosstalk.
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Protein prenylation inhibitors reveal a novel role for rhoa and rhoc in trafficking of g protein-coupled receptors through recycling endosomesSalo, Paul David 24 August 2007 (has links)
LPA1 lysophosphatidic acid receptors (LPA1Rs) are normally present on the surface of the cell. Our initial findings were that HMG-CoA reductase inhibitors (atorvastatin and mevastatin) induce the sequestration of the G protein-coupled LPA1R in recycling endosomes, most likely by inhibiting the recycling of tonically internalized receptors. Whereas, co-addition of geranylgeranylpyrophosphate (GGPP) or geranylgeraniol (GGOH) prevented atorvastatin-induced sequestration of LPA1Rs, the geranylgeranyltransferase-I inhibitor, GGTI-298, mimicked atorvastatin and induced LPA1R sequestration. This suggested that statin-induced endosomal sequestration was caused by defective protein prenylation. The likely targets of atorvastatin and GGTI-298 are the Rho family GTPases, RhoC and RhoA, since both inhibitors greatly reduced the abundance of these GTPases and since knockdown of endogenous RhoC or RhoA with small interfering RNAs (siRNAs) led to endosomal sequestration of LPA1R. Knockdown of RhoC was much more potent at inducing endosomal sequestration than knockdown of either RhoA or RhoB. In contrast, atorvastatin, GGTI-298, siRNA against RhoA, B, or C did not alter the internalization or recycling of transferrin receptors, indicating that recycling of transferrin receptors is distinct from LPA1Rs. Thus, these results, for the first time, implicate RhoA and RhoC in endocytic recycling of LPA1Rs and identify atorvastatin and GGTI-298 as novel inhibitors of this process. / Per the request of the author and advisor, and with the approval of the Graduate Education office, the following changes were made to this thesis:
Replaced original page 1 with Errata Page 2.
Replaced original pages 3-28 with Errata Pages 3 – 16.
Replaced original pages 69-71 with Errata pages 17 – 19.
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Immunolocalization and in vivo Functional Analysis by RNAi of the Aedes Kinin Receptor in Female Mosquitoes of Aedes aegypti (L.) (Diptera, Culicidae)Kersch, Cymon 2011 December 1900 (has links)
The evolution of the blood feeding adaptation has required precise coordination of multiple physiological processes in the insect, such as reproduction, behavior, digestion and diuresis. These processes are under careful synchronous hormonal control. For rapid excretion, multiple diuretic hormones are known. Although originally described based on their ability to stimulate hindgut contractions, the Aedes kinins have been shown to stimulate fluid secretion in female mosquitoes of Aedes aegypti. Aedes kinins are leucokinin-like neuropeptides released from neurosecretory cells in the brain and abdominal ganglia. They act by binding to the Aedes kinin receptor, a G proteincoupled receptor (GPCR). The Aedes kinin receptor has been cloned, sequenced, functionally characterized, and immunolocalized to stellate cells in the Malpighian tubules of Ae. aegypti. In addition to their myotropic and diuretic roles, leucokinin-like peptides and/or their receptors have been also been discovered in the nervous, digestive, and reproductive systems of other arthropod species. Therefore, the Aedes kinins have the potential to function in several simultaneous physiological processes that are stimulated by blood feeding. This thesis aims to understand better their role in the whole mosquito by investigating the Aedes kinin receptor's global expression as well as its in vivo contribution to post-prandial diuresis.
Presence of the Aedes kinin receptor was investigated in the head, posterior midgut (stomach), hindgut, ovaries, and Malpighian tubules of both non blood-fed and blood-fed females by western blot using anti-receptor antibodies. The receptor was then immunolocalized in the posterior midgut and rectum. Finally, RNAi was employed to knock down kinin receptor expression, followed by measurement of in vivo urine excretion post blood feeding in a precision humidity chamber. Transcript and protein knockdown were confirmed by qPCR and immunohistochemistry, respectively.
Results indicate widespread expression of the Aedes kinin receptor protein in organs novel for hematophagous insects and demonstrate the receptor's fundamental role in rapid diuresis. These findings strongly point to the Aedes kinins as integrative signaling molecules that could coordinate multiple physiological systems. The Aedes kinins could therefore have contributed to the success of the blood feeding adapation in mosquitoes.
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Pairing Form with Function: The Oligomeric Size and Configuration of G Protein-coupled ReceptorsPisterzi, Luca Francis 19 June 2014 (has links)
The quaternary status of G protein-coupled receptors (GPCRs) is important, unknown and
controversial. Estimates of size from numerous pharmacological, biochemical and biophysical
studies range from monomers to octamers. Accounts of stability vary from constitutive oligomers
to a spontaneous, ligand-regulated interconversion between monomers and dimers. In the present
investigation, the oligomeric size of GPCRs in live Chinese hamster ovary (CHO) cells has been
examined by two methods. Both are based on the efficiency of Förster resonance energy transfer
(FRET) between fluorophore-tagged receptors, as determined from emission spectra via spectral
deconvolution. In the first, the apparent FRET efficiency (Eapp) was measured for cells expressing
eGFP- and eYFP-tagged M2 muscarinic receptors at different ratios of acceptor to donor. Eapp then
was related to the pair-wise efficiency (Ep) according to a model that enumerates all pathways for
the transfer of energy between single donors and acceptors within an oligomer of given size (n).
Each value n returned a distinct and well-defined value of Ep. Fluorescence lifetime imaging
provided an independent estimate of Ep that was in close agreement with the model-based value
when n = 4, identifying the M2 receptor as a tetramer. In the second approach, the M1 and M2
muscarinic receptors and the β1 and β2 adrenergic receptors were tagged with GFP2 and eYFP, and
the value of Eapp was estimated for each pixel in the image of a cell. The distributions of Eapp from
34–40 cells expressing each receptor were compared with those predicted for populations of dimers,
trimers and tetramers, the latter configured as a square and a rhombus. In each case, the combined
data were well described in terms of a rhombus. Distributions obtained for the M2 and β2 receptors
were not affected by agonists or inverse agonists, nor was there evidence for appreciable numbers
of dimers or larger oligomers. Taken together, the results suggest that GPCRs of Family 1 exist
largely or wholly as constitutive tetramers.
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Pairing Form with Function: The Oligomeric Size and Configuration of G Protein-coupled ReceptorsPisterzi, Luca Francis 19 June 2014 (has links)
The quaternary status of G protein-coupled receptors (GPCRs) is important, unknown and
controversial. Estimates of size from numerous pharmacological, biochemical and biophysical
studies range from monomers to octamers. Accounts of stability vary from constitutive oligomers
to a spontaneous, ligand-regulated interconversion between monomers and dimers. In the present
investigation, the oligomeric size of GPCRs in live Chinese hamster ovary (CHO) cells has been
examined by two methods. Both are based on the efficiency of Förster resonance energy transfer
(FRET) between fluorophore-tagged receptors, as determined from emission spectra via spectral
deconvolution. In the first, the apparent FRET efficiency (Eapp) was measured for cells expressing
eGFP- and eYFP-tagged M2 muscarinic receptors at different ratios of acceptor to donor. Eapp then
was related to the pair-wise efficiency (Ep) according to a model that enumerates all pathways for
the transfer of energy between single donors and acceptors within an oligomer of given size (n).
Each value n returned a distinct and well-defined value of Ep. Fluorescence lifetime imaging
provided an independent estimate of Ep that was in close agreement with the model-based value
when n = 4, identifying the M2 receptor as a tetramer. In the second approach, the M1 and M2
muscarinic receptors and the β1 and β2 adrenergic receptors were tagged with GFP2 and eYFP, and
the value of Eapp was estimated for each pixel in the image of a cell. The distributions of Eapp from
34–40 cells expressing each receptor were compared with those predicted for populations of dimers,
trimers and tetramers, the latter configured as a square and a rhombus. In each case, the combined
data were well described in terms of a rhombus. Distributions obtained for the M2 and β2 receptors
were not affected by agonists or inverse agonists, nor was there evidence for appreciable numbers
of dimers or larger oligomers. Taken together, the results suggest that GPCRs of Family 1 exist
largely or wholly as constitutive tetramers.
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Evolutionary genomics of odorant receptors: identification and characterization of orthologs in an echinoderm, a cephalochordate and a cnidarian.Churcher, Allison Mary 17 August 2011 (has links)
Animal chemosensation involves several families of G protein-coupled receptors (GPCRs) and, though some of these families are well characterized in vertebrates and nematode worms, receptors have not been identified for most metazoan lineages. In this dissertation, I use a combination of bioinformatics approaches to identify candidate chemosensory receptors in three invertebrates that occupy key positions in the metazoan phylogeny. In the sea urchin Strongylocentrotus purpuratus, I uncovered 192 candidate chemosensory receptors many of which are expressed in sensory structures including pedicellariae and tube feet. In the cephalochordate Branchiostoma floridae, my survey uncovered 50 full-length and 11 partial odorant receptors (OR). No ORs were identified in the urochordate Ciona intestinalis. By exposing conserved amino acid motifs and testing the ability of those motifs to discriminate between ORs and non-OR GPCRs, I identified three OR-specific amino acid motifs that are common in cephalochordate, fish and mammalian ORs and are found in less than 1% of non-ORs from the rhodopsin-like GPCR family. To further investigate the antiquity of vertebrate ORs, I used the OR-specific motifs as probes to search for orthologs among the protein predictions from 12 invertebrates. My search uncovered a novel group of genes in the cnidarian Nematostella vectensis. Phylogenetic analysis that included representatives from the major subgroups of rhodopsin-like GPCRs showed that the cnidarian genes, the cephalochordate and vertebrate ORs, and a subset of genes S. purpuratus from my initial survey, form a monophyletic clade. The taxonomic distribution of these genes indicates that the formation of this clade began at least 700 million years ago, prior to the divergence of cnidarians and bilaterians. Furthermore, my phylogenetic analyses show that three of the four major subgroups of rhodopsin-like GPCRs existed in the ancestor of cnidarians and bilaterians. The utility of the new genes I describe here is that they can be used to identify candidate olfactory cells and organs in cnidarians, echinoderms and cephalochordates that can be tested for function. These genes also provide the raw material for surveys of other metazoans as their genomes become available. My sequence level comparison between chordates, echinoderms and cnidarians exposed several conserved amino acid positions that may be useful for understanding receptor mediated signal transduction. ORs and other rhodopsin-like GPCRs have roles in cell migration, axon guidance and neurite growth; therefore duplication and divergence in the rhodopsin-like gene family may have played a key role in the evolution of cell type diversity (including the emergence of complex nervous systems) and in the evolution of metazoan body plan diversity. / Graduate
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Alternative rownstream roles for Ste2p and an α-arrestin in sacccharomyces cerevisiae mating2014 November 1900 (has links)
Ste2p and Ste3p are well-characterized yeast pheromone G-protein Coupled Receptors (GPCR) those are involved in the signaling of mating responses that lead to cell fusion. Their signaling–associated interactions with G-protein/MAPK signal transduction machinery are well established, homologous to those in mammalian systems, and serve as a simplified model system in GPCR research. While the arrestin- mediated biased signaling mechanism of mammalian GPCR has not been discovered for the pheromone receptors, a recent demonstration of α-arrestins being involved in the internalization of the pheromone GPCR, Ste2p was reported. The present study was designed to reevaluate and extend the alternate functionality for pheromone receptors and to determine the role of yeast arrestins in the yeast mating. Specific residues in the TM6 of Ste2p exhibiting strong mating and constitutive MAPK signaling were combined and investigated in terms of their effect on MAPK signal transduction leading to cell cycle arrest as well as their impact on downstream mating projection formation and zygote formation events. Our findings indicate that Ste2p possess as specific residues that govern its relative bias for mediating MAPK signaling or mating events. Relative dose response experiments accounting for systemic and observation bias for these mutations yielded evidence of mutational-derived functional biases for Ste2p and further validated the alternate pheromone dependent functionalities for Ste2p.
Further, arrestin knockout and knock-in studies showed that Art1 (Ldb19) is selectively involved in the regulation of zygote formation but not MAPK signal transduction following the binding of ligand to Ste2p receptors. In addition, ligand stimulated selective localization of Art1 (Ldb19) to the mating projection, implicating it in the regulation of downstream mating functionalities. Overall, while leaving the full mechanism of alternate/biased Ste2p signaling to be elucidated, these results highlight the possibility of continued relevance of the yeast pheromone-mating pathway as a simplified model for GPCR research in the context of arrestin-mediated biased GPCR signaling.
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The physiological relevance of the G protein-coupled receptor P2Y14Meister, Jaroslawna 01 December 2014 (has links) (PDF)
UDP-sugars were identified as extracellular signaling molecules, assigning a new function to these compounds in addition to their well-defined role in intracellular substrate metabolism and storage. Previously regarded as an orphan receptor, the G protein-coupled receptor (GPCR) P2Y14 (GPR105) was found to bind extracellular UDP and UDP-sugars. Little is known about the physiological functions of this GPCR. To study its physiological role a gene-deficient
(KO) mouse strain expressing the bacterial LacZ reporter gene was used to monitor the physiological expression pattern of P2Y14. P2Y14 is mainly expressed in pancreas and salivary glands and in subpopulations of smooth muscle cells of the gastrointestinal tract,
bronchioles, blood vessels and uterus. Among other phenotypical differences KO mice showed a significantly impaired glucose tolerance following oral and intraperitoneal glucose application. An unchanged insulin tolerance points towards an altered pancreatic islet function. Transcriptome analysis of pancreatic islets showed that P2Y14 deficiency
significantly changed expression of components involved in insulin secretion. Insulin secretion tests revealed a reduced insulin release from P2Y14-deficient islets highlighting P2Y14 as a previously unappreciated modulator of proper insulin secretion.
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Nature and Function of the Signaling Complex Formed by the M2 Muscarinic Cholinergic ReceptorMa, Amy Wing-Shan 05 December 2012 (has links)
G protein-coupled receptors (GPCRs) are known to exist as oligomers, but there is much uncertainty over the oligomeric size, the number of interacting G proteins and the stability of that interaction. The present approach to these questions has been threefold. Monomers of the M2 muscarinic receptor were purified from Spodoptera frugiperda (Sf9) cells and reconstituted in phospholipid vesicles, where they spontaneously formed tetramers. The size of the reconstituted complex was determined from its electrophoretic mobility after cross-linking and inferred from a quantitative, model-based assessment of cooperative effects in the binding of two muscarinic antagonists: N-methylscopolamine and quinuclidinylbenzilate. Binding of the agonist oxotremorine-M to receptor reconstituted with purified G proteins revealed at least three classes of sites that interconverted from higher to lower affinity upon the addition of guanylylimidotriphosphate (GMP-PNP). The binding properties resemble those of muscarinic receptors in myocardial preparations, thereby implying the existence of tetramers in native tissues. G proteins that copurify with the M2 receptor from cardiac membranes also were found to exist as oligomers, some of which contain both alpha(o) and alpha(i2), and the purified complexes contained receptor and G protein in near-equal amounts. A tetrameric receptor implies a tetramer of G proteins, a conclusion that is supported by the distribution of sites between different states identified in the binding of [35S]GTPgammaS to the purified complex. Covalent adducts of a GPCR fused to a Galpha-subunit provide a model system in which the relationship between receptor and G protein complex is defined with respect to stability and composition. Such a fusion of the M2 receptor and Galpha(i1) underwent a cleavage near the amino terminus of the alpha-subunit, however, flagging the likelihood of similar effects in other such adducts. Truncation of the amino terminus prior to fusion generated a stable product that revealed GMP-PNP-sensitive, biphasic binding of oxotremorine-M and noncompetitive interactions between N-methylscopolamine and quinuclidinylbenzilate. A covalent RG complex therefore exhibits the functional properties of M2 receptors in native systems. These observations are consistent with the notion that signaling through the M2 receptor occurs via cooperative interactions within a stable complex that comprises four receptors and four G proteins.
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