bThe type II transmembrane serine proteases TMPRSS2 and HAT can cleave and activate the spike protein (S) of the severe acute respiratory syndrome coronavirus (SARS-CoV) for membrane fusion. In addition, these proteases cleave the viral receptor, the carboxypeptidase angiotensin-converting enzyme 2 (ACE2), and it was proposed that ACE2 cleavage augments viral infectivity. However, no mechanistic insights into this process were obtained and the relevance of ACE2 cleavage for SARS-CoV S protein (SARS-S) activation has not been determined. Here, we show that arginine and lysine residues within ACE2 amino acids 697 to 716 are essential for cleavage by TMPRSS2 and HAT and that ACE2 processing is required for augmentation of SARS-S-driven entry by these proteases. In contrast, ACE2 cleavage was dispensable for activation of the viral S protein. Expression of TMPRSS2 increased cellular uptake of soluble SARS-S, suggesting that protease-dependent augmentation of viral entry might be due to increased uptake of virions into target cells. Finally, TMPRSS2 was found to compete with the metalloprotease ADAM17 for ACE2 processing, but only cleavage by TMPRSS2 resulted in augmented SARS-S-driven entry. Collectively, our results in conjunction with those of previous studies indicate that TMPRSS2 and potentially related proteases promote SARS-CoV entry by two separate mechanisms: ACE2 cleavage, which might promote viral uptake, and SARS-S cleavage, which activates the S protein for membrane fusion. These observations have interesting implications for the development of novel therapeutics. In addition, they should spur efforts to determine whether receptor cleavage promotes entry of other coronaviruses, which use peptidases as entry receptors. C oronaviruses are enveloped RNA viruses which cause enteric, respiratory, and central nervous system diseases in a variety of animals and humans (1). The coronaviruses NL63, 229E, and OC43 are adapted to spread in humans, and infection is usually associated with mild respiratory symptoms (2-8). In contrast, the zoonotic transmission of animal coronaviruses to humans can result in novel, severe diseases. The severe acute respiratory syndrome coronavirus (SARS-CoV), which is believed to have been transmitted from bats via an intermediate host to humans (9-11), is the causative agent of the respiratory disease SARS, which claimed more than 700 lives in 2002-2003 (12). Similarly, the recently emerged Middle East respiratory syndrome coronavirus (MERS-CoV) induces a severe, SARS-related respiratory disease, and its spread is at present responsible for 64 deaths (13,14). The elucidation of the molecular processes underlying the spread and pathogenesis of highly pathogenic coronaviruses is required to devise effective antiviral strategies and is therefore the focus of current research efforts.The coronavirus surface protein spike (S) mediates entry into target cells by binding to a cellular receptor and by subsequently fusing the viral envelope with a host cell membrane (15, 16). The receptor bin...
The differential modulation of learning and anxiety by corticotropin-releasing factor (CRF) through CRF receptor subtypes 1 (CRFR1) and 2 (CRFR2) is demonstrated. As learning paradigm, context- and tone-dependent fear conditioning of the mouse was used. Injection of CRF into the dorsal hippocampus before training enhanced learning through CRFR1 as demonstrated by the finding that this effect was prevented by the local injection of the unselective CRFR antagonist astressin, but not by the CRFR2-specific antagonist antisauvagine-30 (anti-Svg-30). In contrast, injection of CRF into the lateral intermediate septum impaired learning through CRFR2, as demonstrated by the ability of antisauvagine-30 to block this effect. When antisauvagine-30 was injected alone into the lateral intermediate septum, learning was enhanced. Such tonic control of learning was not observed when astressin or antisauvagine-30 was injected into the dorsal hippocampus. Injection of CRF after the training into the dorsal hippocampus and the lateral intermediate septum also enhanced and impaired learning, respectively. Thus, it was indicated that CRF acted on memory consolidation. It was concluded that the observed effects reflected changes of associative learning and not arousal, attention, or motivation. Although a dose of 20 pmol human/rat CRF was sufficient to affect learning significantly, a fivefold higher dose was required to induce anxiety by injection into the septum. Immobilization for 1 hr generated a stress response that included the induction of anxiety through septal CRFR2 and the subsequent enhancement of learning through hippocampal CRFR1. The involvement of either receptor subtype was demonstrated by region-specific injections of astressin and antisauvagine-30.
Myelin membranes are dominated by lipids while the complexity of their protein composition has long been considered to be low. However, numerous additional myelin proteins have been identified since. Here we revisit the proteome of myelin biochemically purified from the brains of healthy c56Bl/6N-mice utilizing complementary proteomic approaches for deep qualitative and quantitative coverage. By gel-free, label-free mass spectrometry, the most abundant myelin proteins PLP, MBP, CNP, and MOG constitute 38, 30, 5, and 1% of the total myelin protein, respectively. The relative abundance of myelin proteins displays a dynamic range of over four orders of magnitude, implying that PLP and MBP have overshadowed less abundant myelin constituents in initial gel-based approaches. By comparisons with published datasets we evaluate to which degree the CNS myelin proteome correlates with the mRNA and protein abundance profiles of myelin and oligodendrocytes. Notably, the myelin proteome displays only minor changes if assessed after a post-mortem delay of 6 h. These data provide the most comprehensive proteome resource of CNS myelin so far and a basis for addressing proteomic heterogeneity of myelin in mouse models and human patients with white matter disorders.
Regulation of Corticotropin‐Releasing Factor Receptor Function in Human Y‐79 Retinoblastoma Cells: Rapid and Reversible Homologous Desensitization but Prolonged Recovery
Abstract:Homologous receptor desensitization is an Important regulatory response to continuous activation by agonist that involves the uncoupling of a receptor from its G protein. When human retinoblastoma Y-79 cells expressing corticotropin-releasing factor (CRF) receptors were preincubated with CAF for 10 min-4 h, a time-dependent reduction in both the peak and sensitivity of OAF-stimulated intracellular cyclic AMP (cAMP) accumulation developed with a t 112 of 38 min and an EC50 of 6-7 nM OAF. OAF receptor desensitization was slowly reversible after a 4-h OAF preincubation with a t1,2 of 13 h and a full restoration of cAMP responsiveness to OAF at 24 h following the removal of 10 nM OAF. Because the ability of vasoactive intestinal peptide, forskolin, or (-)-isoproterenol to stimulate cAMP accumulation was not diminished in Y-79 cells desensitized with 10 nM ORF, the observed desensitization was considered to be a specific homologous action of OAF. OAF receptor desensitization was markedly attenuated by OAF receptor antagonists, which alone did not produce any appreciable reduction in OAF-stimulated cAMP accumulation. Although recent reports have demonstrated a rapid decline in steady-state levels of ORF receptor type 1 (OAF-Al) mRNA in anterior pituitary cells during several hours of exposure to OAF, there was no observed reduction in OAF-Al mANA levels when Y-79 cells were preincubated with 10 nM OAF for 10 min-24 h despite a rapid timeand concentration-dependent loss of OAF receptors from the retinoblastoma cell surface.
Munc13 proteins are essential regulators of synaptic vesicle priming and play a key role in adaptive synaptic plasticity phenomena. We recently identified and characterized the Ca(2+)-dependent interaction of Munc13 and calmodulin (CaM) as the molecular mechanism linking changes in residual Ca(2+) concentrations to presynaptic vesicle priming and short-term plasticity. Here, we used peptidic photoprobes covering the established CaM-binding motif of Munc13 for photoaffinity labeling (PAL) of CaM, followed by structural characterization of the covalent photoadducts. Our innovative analytical workflow based on isotopically labeled CaM and mass spectrometry revealed that, in the bound state, the hydrophobic anchor residue of the CaM-binding motif in Munc13s contacts two distinct methionine residues in the C-terminal domain of CaM. To address the orientation of the peptide during binding, we obtained additional distance constraints from the mass spectrometric analysis of chemically cross-linked CaM-Munc13 peptide adducts. The constraints from both complementary cross-linking approaches were integrated into low-resolution three-dimensional structure models of the CaM-Munc13 peptide complexes. Our experimental data are best compatible with the structure of the complex formed by CaM and a CaM-binding peptide derived from neuronal NO synthase and show that Munc13-1 and ubMunc13-2 bind to CaM in an antiparallel orientation through a 1-5-8 motif. The structural information about the CaM-Munc13 peptide complexes will facilitate the design of Munc13 variants with altered CaM affinity and thereby advance the detailed functional analysis of the role of Munc13 proteins in synaptic transmission and plasticity.
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