The relation of a-synuclein (aS) aggregation to Parkinson's disease (PD) has long been recognized, but the mechanism of toxicity, the pathogenic species and its molecular properties are yet to be identified. To obtain insight into the function different aggregated aS species have in neurotoxicity in vivo, we generated aS variants by a structurebased rational design. Biophysical analysis revealed that the aS mutants have a reduced fibrillization propensity, but form increased amounts of soluble oligomers. To assess their biological response in vivo, we studied the effects of the biophysically defined pre-fibrillar aS mutants after expression in tissue culture cells, in mammalian neurons and in PD model organisms, such as Caenorhabditis elegans and Drosophila melanogaster. The results show a striking correlation between aS aggregates with impaired b-structure, neuronal toxicity and behavioural defects, and they establish a tight link between the biophysical properties of multimeric aS species and their in vivo function.
The signaling phosphoinositide phosphatidylinositol 4,5-bisphosphate (PIP2) is synthesized in two steps from phosphatidylinositol by lipid kinases. It then interacts with KCNQ channels and with pleckstrin homology (PH) domains among many other physiological protein targets. We measured and developed a quantitative description of these metabolic and protein interaction steps by perturbing the PIP2 pool with a voltage-sensitive phosphatase (VSP). VSP can remove the 5-phosphate of PIP2 with a time constant of τ <300 ms and fully inhibits KCNQ currents in a similar time. PIP2 was then resynthesized from phosphatidylinositol 4-phosphate (PIP) quickly, τ = 11 s. In contrast, resynthesis of PIP2 after activation of phospholipase C by muscarinic receptors took ∼130 s. These kinetic experiments showed that (1) PIP2 activation of KCNQ channels obeys a cooperative square law, (2) the PIP2 residence time on channels is <10 ms and the exchange time on PH domains is similarly fast, and (3) the step synthesizing PIP2 by PIP 5-kinase is fast and limited primarily by a step(s) that replenishes the pool of plasma membrane PI(4)P. We extend the kinetic model for signaling from M1 muscarinic receptors, presented in our companion paper in this issue (Falkenburger et al. 2010. J. Gen. Physiol. doi:10.1085/jgp.200910344), with this new information on PIP2 synthesis and KCNQ interaction.
Neuroligins (NL1-NL4) are postsynaptic adhesion proteins that control the maturation and function of synapses in the central nervous system (CNS). Loss-of-function mutations in NL4 are linked to rare forms of monogenic heritable autism, but its localization and function are unknown. Using the retina as a model system, we show that NL4 is preferentially localized to glycinergic postsynapses and that the loss of NL4 is accompanied by a reduced number of glycine receptors mediating fast glycinergic transmission. Accordingly, NL4-deficient ganglion cells exhibit slower glycinergic miniature postsynaptic currents and subtle alterations in their stimuluscoding efficacy, and inhibition within the NL4-deficient retinal network is altered as assessed by electroretinogram recordings. These data indicate that NL4 shapes network activity and information processing in the retina by modulating glycinergic inhibition. Importantly, NL4 is also targeted to inhibitory synapses in other areas of the CNS, such as the thalamus, colliculi, brainstem, and spinal cord, and forms complexes with the inhibitory postsynapse proteins gephyrin and collybistin in vivo, indicating that NL4 is an important component of glycinergic postsynapses.synaptogenesis | inhibitory transmission | visual processing I n rodents, postsynaptic adhesion proteins of the neuroligin family (NL1-NL4) are expressed throughout the central nervous system (CNS) (1-3) and essential for synapse organization and function (2-5). In vivo, each NL isoform localizes to specific synapse subpopulations, with NL1, NL2, and NL3 predominantly associating with glutamatergic, GABAergic, or both types of postsynapses, respectively (1, 6-9).Thus far, the distribution and function of the fourth NL isoform has remained unclear, despite the wide interest triggered by the causal link of specific loss-of-function mutations in NL4 to cases of autism, which led to the notion that aberrant synaptic transmission may cause autism spectrum disorders (ASDs) (10).We examined the distribution of NL4 in the mouse retina, a well-characterized region of the CNS with distinct, topographically organized glutamatergic, GABAergic, and glycinergic synapses, which has recently allowed us to characterize crucial aspects of NL2 distribution and function (8). Additionally, we assessed NL4 function by studying synaptic activity and visual processing in the NL4-deficient (NL4-KO; ref.3) mouse retina. Finally, we studied NL4 localization in the rest of the CNS and identified some of its key binding partners at the synapse. Results NL4 Is Localized to Glycinergic Postsynapses in the Retina.We characterized the distribution of NL4 by immunohistochemistry by using an isoform-specific antibody (3) (Fig. 1). A punctate labeling was detected in the inner plexiform layer (IPL) of wildtype (WT) but not NL4-KO retinae (Fig. 1A). NL4-positive puncta were abundant in the outer IPL but sparse in the rest of the IPL (Fig. 1A), which is reminiscent of glycine receptor (GlyR) distribution in the retina (11,12). Indeed, upon co...
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