The role of the calcium transporter protein plasma membrane calcium ATPase PMCA2 in cerebellar Purkinje neuron function.

Genetic deletion of the plasma membrane calcium ATPase type 2 (PMCA2), a calcium transporter protein, is associated with an overtly ataxic phenotype in mice. PMCA2 is expressed at high levels in cerebellar Purkinje neurons (PNs) where functional integrity is essential for normal cerebellar function. Indeed, loss of PN function accompanies cerebellar ataxia in humans and mouse models. In the ataxic PMCA2 knockout (PMCA2-/-) mouse the ability of the PNs to control their cytosolic calcium levels was severely impaired; basal calcium levels were high and calcium recovery kinetics slow. Whole cell patch clamp recordings from PMCA2-/- PNs revealed that they possessed hyperpolarised membrane potentials, reduced frequency and increased irregularity of spontaneous action potential firing, curtailed complex spikes and sustained calcium-dependent outward K+ currents. We propose that these alterations limit pathological excursions in PN cytosolic calcium as an aid to survival but that they are insufficient to prevent loss of functional cerebellar output.

Genetically encoded fluorescent sensors of membrane potential.

Imaging activity of neurons in intact brain tissue was conceived several decades ago and, after many years of development, voltage-sensitive dyes now offer the highest spatial and temporal resolution for imaging neuronal functions in the living brain. Further progress in this field is expected from the emergent development of genetically encoded fluorescent sensors of membrane potential. These fluorescent protein (FP) voltage sensors overcome the drawbacks of organic voltage sensitive dyes such as non-specificity of cell staining and the low accessibility of the dye to some cell types. In a transgenic animal, a genetically encoded sensor could in principle be expressed specifically in any cell type and would have the advantage of staining only the cell population determined by the specificity of the promoter used to drive expression. Here we critically review the current status of these developments.

Functional characterization of permuted enhanced green fluorescent proteins comprising varying linker peptides.

New variants of green fluorescent protein (GFP) can be engineered by circular permutation of their amino acid sequence. We characterized a series of permuted enhanced GFP (PEGFP) with new termini introduced at N144-Y145 and linkers of 1, 3, 5 and 6 residues inserted between G232 and M1, as well as a variant with an extended 7-residues linker between K238 and M1. A minimum linker length of 3 residues was necessary for a functional chromophore to be formed, and linkers exceeding 4 residues yielded almost the same fluorescence quantum yield as enhanced GFP (EGFP). PEGFP exhibited dual-wavelength absorption and fluorescence excitation with peaks at 395 and 490 nm but single-wavelength emission at 512 nm. Fluorescence emission increased with increasing pH for all excitation wavelengths with a pKa of 7.7. Between the pH values of 6 and 8 optical absorption showed an isobestic point at 445 nm. PEGFP rapidly denatured in urea between 50 and 60 degrees C. Renaturation proceeded with a short (approximately 29 s) and a longer (> 150 s) time constant. Transient transfection of HEK293 and HeLa cells revealed the expression dynamics of PEGFP to be similar to that of EGFP. Laser-scanning microscopy of HeLa cells demonstrated that the PEGFP are particularly well suited as fluorescent indicators in two-photon imaging.