Motor Dysfunction and Altered Synaptic Transmission at the Parallel Fiber-Purkinje Cell Synapse in Mice Lacking Potassium Channels Kv3.1 and Kv3.3
Micelacking both Kv3.1 and both Kv3.3 K+ channel alleles display severe motor deficits such as tremor, myoclonus, and ataxic gait. Micelacking one to three alleles at the Kv3.1 and Kv3.3 loci exhibit in an allele dose-dependent manner a modest degree of ataxia. Cerebellar granule cells coexpress Kv3.1 and Kv3.3 K+ channels and are therefore candidate neurons that might be involved in these behavioral deficits. Hence, we investigated the synaptic mechanisms of transmission in the parallel fiber-Purkinje cell system. Action potentials of parallel fibers were broader in mice lacking both Kv3.1 and both Kv3.3 alleles and in mice lacking both Kv3.1 and a single Kv3.3 allele compared with those of wild-type mice. The transmission of high-frequency trains of action potentials was only impaired at 200 Hz but not at 100 Hz in mice lacking both Kv3.1 and Kv3.3 genes. However, paired-pulse facilitation (PPF) at parallel fiber-Purkinje cell synapses was dramatically reduced in a gene dose-dependent manner in mice lacking Kv3.1 or Kv3.3 alleles. Normal PPF could be restored by reducing the extracellular Ca2+ concentration indicating that increased activity-dependent presynaptic Ca2+ influx, at least in part caused the altered PPF in mutant mice. Induction of metabotropic glutamate receptor-mediated EPSCs was facilitated, whereas longterm depression was not impaired but rather facilitated in Kv3.1/Kv3.3 double-knockout mice. These results demonstrate the importance of Kv3 potassium channels in regulating the dynamics of synaptic transmission at the parallel fiber-Purkinje cell synapse and suggest a correlation between short-term plasticity at the parallel fiber-Purkinje cell synapse and motor performance.
Activation of cerebellar parallel fibers monitored in transgenic mice expressing a fluorescent Ca2+ indicator protein
Genetically encoded fluorescent Ca2+ indicator proteins (FCIPs) are promising tools to study Ca2+ signaling in large assemblies of nerve cells. Currently, there are few examples of stable transgenic mouse lines that functionally express such sensors in well-defined neuronal cell populations. Here we report the generation and characterization of transgenic mice expressing an FCIP under the 5' regulatory sequences of the Kv3.1 potassium channel promoter. In the cerebellar cortex, expression was restricted to granule cells. We first demonstrated reliable measurements of Ca2+ transients from beams of parallel fibers and compared the FCIP signals with intrinsic autofluorescence signals. We demonstrate that, in a transgenic line that exhibits a high expression level of the FCIP, autofluorescence signals are negligible and stimulation-induced fluorescence transients represent FCIP signals. Using frontal cerebellar slices we imaged antidromic activation of granule cells following electrical stimulation of parallel fibers and orthodromic activation of beams of parallel fibers following electrical stimulation of granule cells. We found that paired pulse-induced presynaptic Ca2+ transients of parallel fibers are not affected by blockade of N-methyl-D-aspartate receptors.
Transgenic mice expressing a pH and Cl– sensing yellow‐fluorescent protein under the control of a potassium channel promoter
During the last few years a variety of genetically encodable optical probes that monitor physiological parameters such as local pH, Ca2+, Cl-, or transmembrane voltage have been developed. These sensors are based on variants of green-fluorescent protein (GFP) and can be synthesized by mammalian cells after transfection with cDNA. To use these sensor proteins in intact brain tissue, specific promoters are needed that drive protein expression at a sufficiently high expression level in distinct neuronal subpopulations. Here we investigated whether the promoter sequence of a particular potassium channel may be useful for this purpose. We produced transgenic mouse lines carrying the gene for enhanced yellow-fluorescent protein (EYFP), a yellow-green pH- and Cl- sensitive variant of GFP, under control of the Kv3.1 K+ channel promoter (pKv3.1). Transgenic mouse lines displayed high levels of EYFP expression, identified by confocal microscopy, in adult cerebellar granule cells, interneurons of the cerebral cortex, and in neurons of hippocampus and thalamus. Furthermore, using living cerebellar slices we demonstrate that expression levels of EYFP are sufficient to report intracellular pH and Cl- concentration using imaging techniques and conditions analogous to those used with conventional ion-sensitive dyes. We conclude that transgenic mice expressing GFP-derived sensors under the control of cell-type specific promoters, provide a unique opportunity for functional characterization of defined subsets of neurons.
The voltage-gated potassium channels Kv3.1 and Kv3.3 are expressed in several distinct neuronal subpopulations in brain areas known to be involved in motor control such as cortex, basal ganglia and cerebellum. Depending on the lack of Kv3.1 or Kv3.3 channel subunits, mutant mice show different Kv3-null allele-dependent behavioral alterations that include constitutive hyperactivity, sleep loss, impaired motor performance and, in the case of the Kv3.1/Kv3.3 double mutant, also severe ataxia, tremor and myoclonus (Espinosa et al. 2001, J Neurosci 21, 6657-6665, Genes, Brain Behav 3, 90-100). The lack of Kv3.1 channel subunits is mainly responsible for the constitutively increased locomotor activity and for sleep loss, whereas the absence of Kv3.3 subunits affects cerebellar function, in particular Purkinje cell discharges and olivocerebellar system properties (McMahon et al. 2004, Eur J Neurosci 19, 3317-3327). Here, we describe two sensitive and non-invasive tests to reliably quantify normal and abnormal motor functions, and we apply these tests to characterize motor dysfunction in Kv3-mutant mice. In contrast to wildtype and Kv3.1-single mutants, Kv3.3-single mutants and Kv3 mutants lacking three and four Kv3 alleles display Kv3-null allele-dependent gait alterations. Although the Kv3-null allele-dependent gait changes correlate with reduced motor performance, they appear to not affect the training-induced improvement of motor performance. These findings suggest that altered cerebellar physiology in the absence of Kv3.3 channels is responsible for impaired motor task execution but not motor task learning.
Palmitate-induced Down-regulation of Sortilin and Impaired GLUT4 Trafficking in C2C12 Myotubes
Elevated saturated FFAs including palmitate (C16:0) are a primary trigger for peripheral insulin resistance characterized by impaired glucose uptake/disposal in skeletal muscle, resulting from impaired GLUT4 translocation in response to insulin. We herein demonstrate that palmitate induces down-regulation of sortilin, a sorting receptor implicated in the formation of insulin-responsive GLUT4 vesicles, via mechanisms involving PKC and TNF-␣-converting enzyme, but not p38, JNK, or mitochondrial reactive oxygen species generation, leading to impaired GLUT4 trafficking in C2C12 myotubes. Intriguingly, unsaturated FFAs such as palmitoleate (C16:1) and oleate (C18:1) had no such detrimental effects, appearing instead to effectively reverse palmitate-induced impairment of insulin-responsive GLUT4 recycling along with restoration of sortilin abundance by preventing aberrant PKC activation. On the other hand, shRNA-mediated reduction of sortilin in intact C2C12 myotubes inhibited insulin-induced GLUT4 recycling without dampening Akt phosphorylation. We found that the peroxisome proliferator-activated receptor ␥ agonist troglitazone prevented the palmitate-induced sortilin reduction and also ameliorated insulin-responsive GLUT4 recycling without altering the palmitate-evoked insults on signaling cascades; neither highly phosphorylated PKC states nor impaired insulin-responsive Akt phosphorylation was affected. Taken together, our data provide novel insights into the pathogenesis of PKC-dependent insulin resistance with respect to insulin-responsive GLUT4 translocation, which could occur not only through defects of insulin signaling but also via a reduction of sortilin, which directly controls trafficking/sorting of GLUT4 in skeletal muscle cells. In addition, our data suggest the insulin-sensitizing action of peroxisome proliferator-activated receptor ␥ agonists to be at least partially mediated through the restoration of proper GLUT4 trafficking/sorting events governed by sortilin.Skeletal muscle cells as well as adipocytes exhibit the highest levels of insulin-stimulated glucose uptake, which is achieved by translocation of the insulin-responsive glucose transporter (GLUT4) from intracellular storage compartment(s) to the plasma membrane (1). It has become increasingly apparent that sortilin, a type I transmembrane protein originally identified as a major component of GLUT4-containing vesicles from rat adipocytes (2, 3), plays crucial roles in the development of the insulin-responsive GLUT4 translocation system not only in adipocytes (4, 5) but also in skeletal muscle cells (6). Evidence available thus far indicates sortilin to be directly involved in the biogenesis of insulin-responsive GLUT4 storage vesicles by regulating sorting events of GLUT4 protein between the transGolgi network and endosomes (4, 5, 7), and experimental suppression of sortilin in adipocytes has been shown to inhibit insulin-responsive GLUT4 translocation (4).Intriguingly, a recent report demonstrated sortilin expression to be significantly reduce...
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