Sensitive genetically encoded sensors for population and subcellular imaging of cAMP in vivo.

Cyclic adenosine monophosphate (cAMP) signaling integrates information from diverse G-protein-coupled receptors, such as neuromodulator receptors, to regulate pivotal biological processes in a cellular-specific and subcellular-specific manner. However, in vivo cellular-resolution imaging of cAMP dynamics remains challenging. Here, we screen existing genetically encoded cAMP sensors and further develop the best performer to derive three improved variants, called cAMPFIREs. Compared with their parental sensor, these sensors exhibit up to 10-fold increased sensitivity to cAMP and a cytosolic distribution. cAMPFIREs are compatible with both ratiometric and fluorescence lifetime imaging and can detect cAMP dynamics elicited by norepinephrine at physiologically relevant, nanomolar concentrations. Imaging of cAMPFIREs in awake mice reveals tonic levels of cAMP in cortical neurons that are associated with wakefulness, modulated by opioids, and differentially regulated across subcellular compartments. Furthermore, enforced locomotion elicits neuron-specific, bidirectional cAMP dynamics. cAMPFIREs also function in Drosophila. Overall, cAMPFIREs may have broad applicability for studying intracellular signaling in vivo.

Roles for Countercharge in the Voltage Sensor Domain of Ion Channels.

Voltage-gated ion channels share a common structure typified by peripheral, voltage sensor domains. Their S4 segments respond to alteration in membrane potential with translocation coupled to ion permeation through a central pore domain. The mechanisms of gating in these channels have been intensely studied using pioneering methods such as measurement of charge displacement across a membrane, sequencing of genes coding for voltage-gated ion channels, and the development of all-atom molecular dynamics simulations using structural information from prokaryotic and eukaryotic channel proteins. One aspect of this work has been the description of the role of conserved negative countercharges in S1, S2, and S3 transmembrane segments to promote sequential salt-bridge formation with positively charged residues in S4 segments. These interactions facilitate S4 translocation through the lipid bilayer. In this review, we describe functional and computational work investigating the role of these countercharges in S4 translocation, voltage sensor domain hydration, and in diseases resulting from countercharge mutations.

NaV1.4 DI-S4 periodic paralysis mutation R222W enhances inactivation and promotes leak current to attenuate action potentials and depolarize muscle fibers.

Hypokalemic periodic paralysis is a skeletal muscle disease characterized by episodic weakness associated with low serum potassium. We compared clinical and biophysical effects of R222W, the first hNaV1.4 domain I mutation linked to this disease. R222W patients exhibited a higher density of fibers with depolarized resting membrane potentials and produced action potentials that were attenuated compared to controls. Functional characterization of the R222W mutation in heterologous expression included the inactivation deficient IFM/QQQ background to isolate activation. R222W decreased sodium current and slowed activation without affecting probability. Consistent with the phenotype of muscle weakness, R222W shifted fast inactivation to hyperpolarized potentials, promoted more rapid entry, and slowed recovery. R222W increased the extent of slow inactivation and slowed its recovery. A two-compartment skeletal muscle fiber model revealed that defects in fast inactivation sufficiently explain action potential attenuation in patients. Molecular dynamics simulations showed that R222W disrupted electrostatic interactions within the gating pore, supporting the observation that R222W promotes omega current at hyperpolarized potentials. Sodium channel inactivation defects produced by R222W are the primary driver of skeletal muscle fiber action potential attenuation, while hyperpolarization-induced omega current produced by that mutation promotes muscle fiber depolarization.

The sea anchor technique: a novel method to aid in stent-assisted embolization of giant cerebral aneurysms.

Endovascular navigation past some large or giant intracranial aneurysms for the purpose of stent deployment can be difficult. Some of these lesions have a morphology which compels the operator to navigate through the aneurysm dome in order to gain distal access, a step which requires straightening of the delivery microcatheter before a stent can be deployed. In most patients this can be achieved by simply retracting the microcatheter and reducing the loop within the aneurysm. However, in certain patients the acute angle formed between aneurysm inflow and outflow tracts as well as the dynamics of tension within the microcatheter act together to prevent this from happening. Instead of retracting and straightening across the aneurysm neck, the microcatheter withdraws leaving the intra-aneurysm loop intact. This challenge can thwart attempts at stent placement and subsequent embolization. The authors describe a simple and safe technique to circumvent this problem, a way of stabilizing the distal tip of the microcatheter which they term the 'sea anchor'.

Skull fractures through parietal foramina: report of two cases.

Enlarged parietal foramina are related to a condition in which defective intramembranous ossification of the parietal bones results in enlargement of the normal foramina. Although generally believed to be a benign variant, scalp defects, seizures, and structural brain abnormalities have been reported in a small percentage of affected patients. These 2 cases now present evidence that parietal foramina constitute structural weak spots in the calvarium that may potentially increase risk of skull fracture after trauma.