Oligomerization of the alpha 1a- and alpha 1b-Adrenergic Receptor Subtypes: Potential Implications in Receptor Internalization

We combined biophys., biochem., and pharmacol. approaches to investigate the ability of the a1a- and a1b-adrenergic receptor (AR) subtypes to form homo- and hetero-oligomers. Receptors tagged with different epitopes (hemagglutinin and Myc) or fluorescent proteins (cyan and green fluorescent proteins) were transiently expressed in HEK-293 cells either individually or in different combinations. Fluorescence resonance energy transfer measurements provided evidence that both the a1a- and a1b-AR can form homo-oligomers with similar transfer efficiency of .apprx.0.10. Hetero-oligomers could also be obsd. between the a1b- and the a1a-AR subtypes but not between the a1b-AR and the b2-AR, the NK1 tachykinin, or the CCR5 chemokine receptors. Oligomerization of the a1b-AR did not require the integrity of its C-tail, of two glycophorin motifs, or of the N-linked glycosylation sites at its N terminus. In contrast, helix I and, to a lesser extent, helix VII were found to play a role in the a1b-AR homo-oligomerization. Receptor oligomerization was not influenced by the agonist epinephrine or by the inverse agonist prazosin. A constitutively active (A293E) as well as a signaling-deficient (R143E) mutant displayed oligomerization features similar to those of the wild type a1b-AR. Confocal imaging revealed that oligomerization of the a1-AR subtypes correlated with their ability to co-internalize upon exposure to the agonist. The a1a-selective agonist oxymetazoline induced the co-internalization of the a1a- and a1b-AR, whereas the a1b-AR could not co-internalize with the NK1 tachykinin or CCR5 chemokine receptors. Oligomerization might therefore represent an addnl. mechanism regulating the physiol. responses mediated by the a1a- and a1b-AR subtypes. [on SciFinder (R)]

Advanced Fluorescence Microscopy to Study Plasma Membrane Protein Dynamics

Joachim Piguet

Membrane protein dynamics is of great importance for living organisms. The precise localization of proteins composing a synapse on the membrane facing a nerve terminus is essential for proper functioning of the nervous system. In muscle fibers, the nicotinic acetylcholine is densely packed under the motor nerve termini. A receptor associated protein, rapsyn, acts as a linker between the receptor and the other components of the synaptic suramolecular assembly. Advances in fluorescence microscopy have allowed to measure the behavior of a single receptor in the cell membrane. In this work single-molecule microscopy was used to track the motion of ionotropic acetylcholine (nAChR) and serotonin (5HT3R) receptors in the plasma membrane of cells. We present methods for measuring single-molecule diffusion and their analysis. Single molecule tracking has shown a high dependence of acetylcholine receptors diffusion on its associated protein rapsyn. Comparing muscle cells that either express rapsyn or are devoid of it, we found that rapsyn plays an important role on receptor immobilization. A three-fold increase of receptor mobility was observed in muscle cells devoid of rapsyn. However, in these cells, a certain fraction of immobilized receptors was also found immobile. Furthermore, nAChR were strongly confined in membrane domains of few tens of nanometers. This showed that membrane composition and membrane associated proteins influence on receptor localization. During muscle cell differentiation, the fraction of immobile nAChR diminished along with the decreasing nAChR and stable rapsyn expression levels. The importance of rapsyn in nAChR immobilization has been further confirmed by measurements in HEK 293 cells, where co-expression of rapsyn increased immobilization of the receptor. nAChR is a ligand-gated ion-channel of the Cys-loop family. In mammals, members of this receptor family share general structural and functional features. They are homo- or hetero-pentamers and form a membrane-spanning ion channel. Subunits have three major regions, an extracellular ligand binding domain, a transmembrane channel and a large intracellular loop. 5HT3R was used as a model to study the effect of this loop on receptor mobility. Single-molecule tracking experiments on receptors with progressively larger deletions in the intracellular loop did not show a dependence of the size of the loop on the diffusion coefficient of mobile receptors. However, two regions were identified to play a role in receptor mobility by changing the fractions of immobile and directed receptors. Interestingly, a prokaryotic homologue of cys-loop receptors, ELIC, devoid of a large cytoplasmic loop was found to be immobile or to show directed diffusion similar as the wild-type 5HT3R. The scaffolding protein rapsyn stabilizes nAChR clusters in a concentration dependent manner. We have measured the density and self-interactions of rapsyn using FRET microscopy. Point-mutations of rapsyn, known to provoke myopathies, destabilized rapsyn self-interactions. Rapsyn-N88K, and R91L were found at high concentration in the cytoplasm suggesting that this modification disturbs membrane association of rapsyn. A25V was found to accumulate in the endoplasmic reticulum. Fluorescent tools to measure intracellular concentration of calcium ions are of great value to study the function of neurons. Rapsyn is highly abundant at the neuromuscular junction and thus is a genuine synaptic marker. A fusion protein of rapsyn with a genetically encoded ratiometric calcium sensor has been made to probe synapse activity. This thesis has shown that the combined use of biologically relevant system and modern fluorescence microscopy techniques deliver important information on pLGIC behaviour in the cell membrane.

EPFL2010

Molecular Mechanisms Underlying Hyaline Fibromatosis Syndrome

Julie Deuquet Ariosa

Hyaline Fibromatosis Syndrome (HFS) is a rare inherited disease that is characterized by an accumulation of an unidentified hyaline material, largely affecting connective tissues. Patients afflicted with HFS present a wide range of clinical symptoms such as nodules, papules, hyperplasia of the gingiva, joint contractions, thickness and hyperpigmentation of the skin, and osteopenia. Depending of the severity and the delay of appearance of these symptoms, the life expectancy varies between 2 years and > 30 years. Death earlier in life is due to recurrent diarrhea and chest infections of unknown origin. In 2003, the gene responsible for HFS was identified to be Capillary Morphoqenesis Gene 2 (CMG2), a gene upregulated during capillary morphogenesis in three-dimensional collagen matrices. This gene encodes a type I transmembrane glycoprotein composed of a von Willebrand (vWA) domain followed by an immunoglobulin (Ig)-like domain in its extracellular part, a single α-helix spanning transmembrane domain, and a 148 amino acids cytoplasmic tail predicted as unstructured. Even though the physiological function of CMG2 remains to be elucidated, it has been shown that this protein induces endothelial proliferation, and dictates cell polarization during embryogenesis in a zebrafish model. Besides its physiological function, CMG2 was found to be an anthrax toxin receptor, thus its alternative name ANTXR2, and has been extensively studied in this context. Genetic analysis has led to the identification of 34 CMG2 mutations in HFS patients. The molecular mechanisms underlying the disease have however not yet been identified. During the five years of my thesis, we were interested in understanding the cellular consequences of these mutations and in getting a better understanding of the physiological function of CMG2. I first showed that most of the HFS mutations in the vWA domain lead to alterations in folding of the domain, either in terms of kinetics or of structure, leading to recognition of the protein by the ER quality control (ERQC) and subsequent degradation by the ERAD pathway. A direct consequence of this retention is the loss of function at the cell surface or other cellular sites. In a second study, I studied the effect of novel HFS mutations that our collaborators and we identified in the CMG2 Ig-like domain. Since the structure of this domain was uncharacterized, we first generated a model of the domain and found that it has an Ig-like fold, despite the very low sequence homology, and harbors two disulfide bonds essential for folding and stabilization of the domain. HFS mutations localized to this domain led to aberrant intermolecular disulfide binding, ER retention and enhanced ERAD when compared to the vWA domain HFS mutations as shown in patients fibroblasts. The consequential loss of CMG2 could be partly alleviated by treating cells with proteasome inhibitor, such as Bortezomib, illustrating that ERAD components are potential therapeutic targets for HFS. As most of the HFS mutations in the ectodomain of CMG2 trigger this ER retention during the CMG2 biosynthesis, we then addressed this process by studying one of the most described post-translational modifications occurring in the ER for protein folding, namely the N-glycosylation. We found that the two potential CMG2 N-glycosylation sites, N250 and N260, are both occupied. Neither of the two sites is essential for ER exit. Glycosylation of CMG2 on N260 is however important since the expression levels of the N260A mutant were significant lower that for the WT protein, despite equivalent or higher synthesis, suggesting that glycosylation at this site is important for efficient folding. Finally, in order to better understand the CMG2 function, we investigated what the physiological ligands could be, assuming it is a receptor as suggested by its role in anthrax infection. We identified type VI collagen as a potential ligand in-vitro that activates CMG2 in-vivo, by phosphorylation of CMG2 cytoplasmic tail. This CMG2 activation upon type VI collagen binding could be a signal for ligand-triggered endocytosis, as is has been described with the protective antigen (PA) of anthrax toxin. The results of this work allow us to gain insights in the molecular mechanisms underlying HFS. Our studies indicate that the identification of the genotype-phenotype correlation of this disease is important for proper diagnosis and clinical approaches, and also that a therapeutic strategy based on proteasome inhibitors, such as Bortezomib, could be envisioned to treat some HFS symptoms in order to improve the life conditions of the patients.

EPFL2011

Glycan variability on a recombinant IgG antibody transiently produced in HEK-293E cells

Lucia Baldi Unser, Luca Fornelli, Sophie Nallet, Julien Parra, Simone Schmitt, Yury Tsybin, Florian Maria Wurm

In this study, a recombinant monoclonal IgG antibody was produced by transient gene expression (TGE) in suspension-adapted HEK-293E cells. The objective of the study was to determine the variation in recombinant IgG yield and glycosylation in ten independent transfections. In a ten-day batch process, the variation in transient IgG yield in the ten batches was less than 30% with the specific productivity averaging 20.2 +/- 2.6 pg/cell/day. We characterized the N-glycosylation profile of each batch of affinity-purified IgG by intact protein and bottom-up mass spectrometry. Four major glycans were identified at Asn(297) in the ten batches with the maximum relative deviation for a single glycoform being 2.5%. In addition, within any single transfection there was little variation in glycoforms over the ten-day culture. Our experimental data indicate that with TGE, the production of recombinant IgG with little batch-to-batch variation in volumetric yield and protein glycosylation is feasible, even in a non-instrumented cultivation system as described here.