Neuronal P2X2 receptors are mobile ATP sensors that explore the plasma membrane when activated.

ATP-gated ionotropic P2X2 receptors are widely expressed in neurons. Although the electrophysiological properties of P2X2 receptors have been extensively studied, little is known about the plasma membrane lateral mobility of P2X2 receptors or whether receptor mobility is regulated by ATP. Here we used single-molecule imaging with simultaneous whole-cell voltage-clamp recordings to track quantum dot-labeled P2X2 receptors in the dendrites of rat hippocampal neurons to explore P2X2 receptor mobility and its regulation. We find that plasma membrane P2X2 receptor lateral mobility in dendrites is heterogeneous but mostly Brownian in nature, consisting of mobile and slowly mobile receptor pools. Moreover, lateral mobility is P2X2 subunit and cell specific, is increased in an activation-dependent manner, and is regulated by cytosolic VILIP1, a calcium binding protein. Our data provide the first direct measures of P2X receptor mobility and show that P2X2 receptors are mobile ATP sensors, sampling more of the dendritic plasma membrane in response to ATP.

Tracking transmitter-gated P2X cation channel activation in vitro and in vivo.

We present a noninvasive approach to track activation of ATP-gated P2X receptors and potentially other transmitter-gated cation channels that show calcium fluxes. We genetically engineered rat P2X receptors to carry calcium sensors near the channel pore and tested this as a reporter for P2X(2) receptor opening. The method has several advantages over previous attempts to image P2X channel activation by fluorescence resonance energy transfer (FRET): notably, it reports channel opening rather than a conformation change in the receptor protein. Our FRET-based imaging approach can be used as a general method to track, in real time, the location, regional expression variation, mobility and activation of transmitter-gated P2X channels in living neurons in vitro and in vivo. This approach should help to determine when, where and how different receptors are activated during physiological processes.

A quantitative regional expression profile of EAAT2 known and novel splice variants reopens the question of aberrant EAAT2 splicing in disease.

The glutamate transporter 1 (GLT1) in rodents, or EAAT2 in humans, is alternatively spliced in a complex manner including the use of multiple 5' and 3' untranslated regions and several coding variants. We used quantitative RT-PCR to profile these splice variants in human and rat brain. We also used RT-PCR and Northern blotting to demonstrate that a novel isoform of GLT1b has an approximately 11kb 3' UTR extending through intron 9, exon 10 and approximately 5kb into the 3' untranslated region of GLT1. However, our most important finding concerns an aberrant transcript lacking exon 9, which contains a motif permitting translocation from the endoplasmic reticulum. This variant had previously been associated with amyotrophic lateral sclerosis until several groups reported high levels in normal brain tissue. In contrast, our data shows that this aberrant transcript is present at 0.1-0.2% of the major EAAT2 isoforms.

Autism and ultraconserved non-coding sequence on chromosome 7q.

OBJECTIVE: Autism has been linked to a broad region on chromosome 7q that contains a large number of genes involved in transcription and development. This region is also enriched for ultraconserved non-coding elements, defined as human-rodent sequences that are 100% aligned over > or =200 base pairs, which have a high likelihood of being functional. Therefore, as only a few rare coding variants have been detected in the autism candidate genes on 7q examined to date, we decided to screen these ultraconserved elements for possible autism susceptibility alleles. METHODS: We used denaturing high-performance liquid chromatography, and DNA sequencing, to perform variant detection in a total of 146 cases with autism, 96 from the Autism Genetic Resource Exchange and 50 from the Central Valley of Costa Rica, as well as 124 controls from the Polymorphism Discovery Resource Panel. We screened 10 consecutive ultraconserved elements in, or flanking, the genes DLX5/6, AUTS2 and FOXP2 on chromosome 7q. RESULTS: Although we did find several rare variants in autism cases that were not present in controls, we also observed rare variants present in controls and not cases. The most common variant occurred in controls at a frequency of 3.3%. Interestingly, two ultraconserved elements each harbored three independent variants and one ultraconserved element harbored two independent variants, suggesting that ultraconservation is maintained chiefly by a decreased tendency toward fixation, rather than a significantly lower mutation rate. CONCLUSIONS: Our results show that these sequences are unlikely to harbor major autism susceptibility alleles.

Regulation of P2X2 receptors by the neuronal calcium sensor VILIP1.

Extracellular adenosine triphosphate (ATP) activates P2X receptors, which are involved in diverse physiological functions. Using a proteomic approach, we identified the neuronal calcium sensor VILIP1 as interacting with P2X2 receptors. We found that VILIP1 forms a signaling complex in vitro and in vivo with P2X2 receptors and regulates P2X2 receptor sensitivity to ATP, peak response, surface expression, and diffusion. VILIP1 constitutively binds to P2X2 receptors and displays enhanced interactions in an activation- and calcium-dependent manner owing to exposure of its binding segment in P2X2 receptors. VILIP1-P2X2 interactions are also enhanced in hippocampal neurons during conditions of action potential firing known to trigger P2X2 receptor activation. Our data thus reveal a previously unrecognized function for the neuronal calcium sensor protein VILIP1 and a mechanism for regulation of ATP-dependent P2X receptor signaling by neuronal calcium sensors.