SUMMARY Mitochondrial Ca2+ Uniporter (MCU)-dependent mitochondrial Ca2+ uptake is the primary mechanism for increasing matrix Ca2+ in most cell types. However, a limited understanding of the MCU complex assembly impedes the comprehension of the precise mechanisms underlying MCU activity. Here we report that mouse cardiomyocytes and endothelial cells lacking MCU regulator 1, MCUR1, have severely impaired [Ca2+]m uptake and IMCU current. MCUR1 binds to MCU and EMRE and function as a scaffold factor. Our protein binding analyses identified the minimal, highly conserved regions of coiled-coil domain of both MCU and MCUR1 that are necessary for heterooligomeric complex formation. Loss of MCUR1 perturbed MCU heterooligomeric complex and functions as a scaffold factor for the assembly of MCU complex. Vascular endothelial deletion of MCU and MCUR1 impaired mitochondrial bioenergetics, cell proliferation and migration but elicited autophagy. These studies establish the existence of a MCU complex which assembles at the mitochondrial integral membrane and regulates Ca2+-dependent mitochondrial metabolism.
SummaryYeast prions require a core set of chaperone proteins including Sis1, Hsp70 and Hsp104 to generate new amyloid templates for stable propagation, yet emerging studies indicate that propagation of some prions requires additional chaperone activities, demonstrating chaperone specificity beyond the common amyloid requirements. To comprehensively assess such prion‐specific requirements for the propagation of the [URE 3] prion variant [URE 3‐1], we screened 12 yeast cytosolic J‐proteins, and here we report a novel role for the J‐protein Swa2/Aux1. Swa2 is the sole yeast homolog of the mammalian protein auxilin, which, like Swa2, functions in vesicle‐mediated endocytosis by disassembling the structural lattice formed by the protein clathrin. We found that, in addition to Sis1, [URE 3‐1] is specifically dependent upon Swa2, but not on any of the 11 other J‐proteins. Further, we show that [URE 3‐1] propagation requires both a functional J‐domain and the tetratricopeptide repeat (TPR) domain, but surprisingly does not require Swa2‐clathrin binding. Because the J‐domain of Swa2 can be replaced with the J‐domains of other proteins, our data strongly suggest that prion‐chaperone specificity arises from the Swa2 TPR domain and supports a model where Swa2 acts through Hsp70, most likely to provide additional access points for Hsp104 to promote prion template generation.
Large-conductance Ca2+-activated K+ channels (BK channels) are activated by cytosolic calcium and depolarized membrane potential under physiological conditions. Thus, these channels control electrical excitability in neurons and smooth muscle by gating K+ efflux and hyperpolarizing the membrane in response to Ca2+ signaling. Altered BK channel function has been linked to epilepsy, dyskinesia, and other neurological deficits in humans, making these channels a key target for drug therapies. To gain insight into mechanisms underlying pharmacological modulation of BK channel gating, here we studied mechanisms underlying activation of BK channels by the biarylthiourea derivative, NS11021, which acts as a smooth muscle relaxant. We observe that increasing NS11021 shifts the half-maximal activation voltage for BK channels toward more hyperpolarized voltages, in both the presence and nominal absence of Ca2+, suggesting that NS11021 facilitates BK channel activation primarily by a mechanism that is distinct from Ca2+ activation. 30 µM NS11021 slows the time course of BK channel deactivation at −200 mV by ∼10-fold compared with 0 µM NS11021, while having little effect on the time course of activation. This action is most pronounced at negative voltages, at which the BK channel voltage sensors are at rest. Single-channel kinetic analysis further shows that 30 µM NS11021 increases open probability by 62-fold and increases mean open time from 0.15 to 0.52 ms in the nominal absence of Ca2+ at voltages less than −60 mV, conditions in which BK voltage sensors are largely in the resting state. We could therefore account for the major activating effects of NS11021 by a scheme in which the drug primarily shifts the pore-gate equilibrium toward the open state.
Large-conductance Ca2+-activated K+ (BK) channels control a range of physiological functions, and their dysfunction is linked to human disease. We have found that the widely used drug loperamide (LOP) can inhibit activity of BK channels composed of either α-subunits (BKα channels) or α-subunits plus the auxiliary γ1-subunit (BKα/γ1 channels), and here we analyze the molecular mechanism of LOP action. LOP applied at the cytosolic side of the membrane rapidly and reversibly inhibited BK current, an effect that appeared as a decay in voltage-activated BK currents. The apparent affinity for LOP decreased with hyperpolarization in a manner consistent with LOP behaving as an inhibitor of open, activated channels. Increasing LOP concentration reduced the half-maximal activation voltage, consistent with relative stabilization of the LOP-inhibited open state. Single-channel recordings revealed that LOP did not reduce unitary BK channel current, but instead decreased BK channel open probability and mean open times. LOP elicited use-dependent inhibition, in which trains of brief depolarizing steps lead to accumulated reduction of BK current, whereas single brief depolarizing steps do not. The principal effects of LOP on BK channel gating are described by a mechanism in which LOP acts as a state-dependent pore blocker. Our results suggest that therapeutic doses of LOP may act in part by inhibiting K+ efflux through intestinal BK channels.
affinity and specificity for each NBS, the interactions between the various NBSs, and the mechanism whereby nucleotide binding events are transmitted to the channel pore are largely unknown. To fully understand the nucleotide effects on K ATP , we have labelled each NBS (one at a time) with the fluorescent, non-canonical amino acid ANAP and measured nucleotide binding at each site using FRET between ANAP and trinitrophenyl (TNP) nucleotide derivatives in unroofed membrane fragments. This has allowed us to dissect nucleotide binding to each site, evaluate mechanistically mutations expected to affect nucleotide binding (e.g. SUR1-K1384A, Kir6.2-G334D) or channel gating (e.g. Kir6.2-C166S), and investigate the action of clinically important drugs that inhibit or potentiate K ATP (sulfonylureas and K þ channel openers). We have also combined this method with patch-clamp electrophysiology (either in separate experiments or simultaneously with patch-clamp fluorometry) to determine the functional consequences of binding at each NBS. This method will not only yield insights into K ATP channel activity, but is readily extended to other channels, ABC transporters, and virtually any protein with a suitable fluorescent ligand. 543-Pos Single Molecule FRET Reveals Lipid Induced Conformational Changes inCytoplasmic Domain of Kir2.1 Anionic phospholipids are common regulators of ion channel activity, including Kir2.1, an inward rectifying potassium channel crucial for setting and maintaining resting membrane potential in many tissues, which is activated specifically by PIP2 and phosphatidyl glycerol (PG). Crystal structures indicate that a simple upward translocation of the cytoplasmic Kir domain is induced by PIP2 and PG binding. However, recent computational and single-molecule FRET experiments show more complex intra-domain movements and rotation in the Kir domain of prokaryotic KirBac1.1 upon PIP2 binding. Single molecule FRET measurements on eukaryotic human Kir2.1 indicate similar complex motions that are not detected in static crystal structures. Our measurements indicate dynamic conformational 'breathing' throughout the Kir domain, suggesting greater flexibility in the intracellular domain of ion channels than may be apparent in structural studies. Specifically, our data indicate a PIP2 dependent shifts in average single molecule FRET (smFRET) distributions, with outward motions seen prior to the slide helix (residue 59) and an inward motion seen at the base (residues 286 and 288) consistent with a twisting motion of the Kir domain that was previously shown to be associated with opening in KirBac1.1. In the absence of PIP2, smFRET signals are very dynamic with relatively large (>20A) motions at specific residues. PIP2 stabilizes the conformational dynamics of the Kir domain, with less transitions between structural states, and reduction in the occurrence of large conformational transitions. Potassium (K) channels play a critical role in bacterial electrolyte homeostasis and control of membrane potential, and are thus im...
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