Objective: It is unclear if a low or high-volume intravenous (IV) fluid resuscitation strategy is better for patients with severe sepsis and septic shock. Design: Prospective randomized controlled trial. Setting: Two adult acute care hospitals within a single academic system. Patients: Patients with severe sepsis and septic shock admitted from the emergency department to the intensive care unit (ICU) from November 2016 to February 2018. Interventions: Patients were randomly assigned to a restrictive IV fluid resuscitation strategy (≤ 60ml/kg of IV fluid) or usual care for the first 72 hours of care. Measurements and Main Results: We enrolled 109 patients, of whom 55 were assigned to the restrictive resuscitation group and 54 to the usual care group. The restrictive group received
N-methyl-d-aspartate receptors (NMDARs) are ligand-gated ion channels that contribute to fundamental physiological processes such as learning and memory and, when dysfunctional, to pathophysiological conditions such as neurodegenerative diseases, stroke, and mental illness. NMDARs are obligate heteromultimers typically composed of NR1 and NR2 subunits with the different subunits underlying the functional versatility of NMDARs. To study the contribution of the different subunits to NMDAR channel structure and gating, we compared the effects of cysteine-reactive agents on cysteines substituted in and around the M1, M3, and M4 segments of the NR1 and NR2C subunits. Based on the voltage dependence of cysteine modification, we find that, both in NR1 and NR2C, M3 appears to be the only transmembrane segment that contributes to the deep (or voltage dependent) portion of the ion channel pore. This contribution, however, is subunit specific with more positions in NR1 than in NR2C facing the central pore. Complimentarily, NR2C makes a greater contribution than NR1 to the shallow (or voltage independent) portion of the pore with more NR2C positions in pre-M1 and M3-S2 linker lining the ion-conducting pathway. Substituted cysteines in the M3 segments in NR1 and NR2C showed strong, albeit different, state-dependent reactivity, suggesting that they play central but structurally distinct roles in gating. A weaker state dependence was observed for the pre-M1 regions in both subunits. Compared to M1 and M3, the M4 segments in both NR1 and NR2C subunits had limited accessibility and the weakest state dependence, suggesting that they are peripheral to the central pore. Finally, we propose that Lurcher mutation-like effects, which were identified in and around all three transmembrane segments, occur for positions located at dynamic protein–protein or protein–lipid interfaces that have state-dependent accessibility to methanethiosulfonate (MTS) reagents and therefore can affect the equilibrium between open and closed states following reactions with MTS reagents.
Ionotropic glutamate receptors (iGluRs), including the NMDA receptor subtype, are ligand-gated ion channels critical to fast signaling in the central nervous system. NMDA receptors are obligate heterotetramers composed of two GluN1 and typically two GluN2 subunits. However, the arrangement of GluN subunits in functional receptors—whether like subunits are adjacent to (N1/N1/N2/N2) or diagonal to (N1/N2/N1/N2) one another—remains unclear. Recently, a crystal structure of a homomeric AMPA receptor revealed that the four identical subunits adopt two distinct and subunit-specific conformations termed A/C and B/D with subunits of like conformations (e.g., A/C) diagonal to one another. In the structure, the two conformers were notable at the level of the linkers (S1-M1, M3-S2, and S2-M4) that join the ligand-binding domain to the transmembrane ion channel with the M3-S2 linker positioned more proximal to the central axis of the channel pore in the A/C conformation and S2-M4 more proximal in the B/D conformation. Using immunoblots and functional assays, we show that introduced cysteines in the M3/M3-S2 linker of GluN1, but not GluN2, show dimer formation and oxidation-induced changes in current amplitudes predictive of the A/C conformation. Conversely, introduced cysteines in the S2-M4 linker of GluN2, but not GluN1, showed similar functional effects suggesting that the GluN2 subunit adopts the B/D conformation. Thus, we show that NMDA receptors, like AMPA receptors, possess distinct subunit-specific conformations with GluN1 approximating the A/C and GluN2 the B/D conformation. GluN subunits are therefore positioned in a N1/N2/N1/N2 arrangement in functional NMDA receptors.
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