Laser-scanning astrocyte mapping reveals increased glutamate-responsive domain size and disrupted maturation of glutamate uptake following neonatal cortical freeze-lesion.

David Hampton,Chris G. Dulla,Moritz Armbruster,Yongjie Yang

doi:10.3389/fncel.2014.00277

David Hampton, Chris G. Dulla + Show 2 more

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https://doi.org/10.3389/fncel.2014.00277

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Journal: Frontiers in cellular neuroscience	Publication Date: Sep 9, 2014
Citations: 12	License type: cc-by

Affiliation: Tufts University

Abstract

Astrocytic uptake of glutamate shapes extracellular neurotransmitter dynamics, receptor activation, and synaptogenesis. During development, glutamate transport becomes more robust. How neonatal brain insult affects the functional maturation of glutamate transport remains unanswered. Neonatal brain insult can lead to developmental delays, cognitive losses, and epilepsy; the disruption of glutamate transport is known to cause changes in synaptogenesis, receptor activation, and seizure. Using the neonatal freeze-lesion (FL) model, we have investigated how insult affects the maturation of astrocytic glutamate transport. As lesioning occurs on the day of birth, a time when astrocytes are still functionally immature, this model is ideal for identifying changes in astrocyte maturation following insult. Reactive astrocytosis, astrocyte proliferation, and in vitro hyperexcitability are known to occur in this model. To probe astrocyte glutamate transport with better spatial precision we have developed a novel technique, Laser Scanning Astrocyte Mapping (LSAM), which combines glutamate transport current (TC) recording from astrocytes with laser scanning glutamate photolysis. LSAM allows us to identify the area from which a single astrocyte can transport glutamate and to quantify spatial heterogeneity in the rate of glutamate clearance kinetics within that domain. Using LSAM, we report that cortical astrocytes have an increased glutamate-responsive area following FL and that TCs have faster decay times in distal, as compared to proximal processes. Furthermore, the developmental shift from GLAST- to GLT-1-dominated clearance is disrupted following FL. These findings introduce a novel method to probe astrocyte glutamate uptake and show that neonatal cortical FL disrupts the functional maturation of cortical astrocytes.

Highlights

Developmental cortical malformations are a cause of focal cortical epilepsy and are often refractory to treatment (Schwartzkroin and Walsh, 2000; Crino, 2005)
We report that neonatal freeze lesion (FL) increases the glutamate-responsive domain of astrocytes following FL, induces heterogeneity in intra-astrocyte transport current (TC) kinetics, and alters excitatory amino acid transporters (EAATs) sub-type specific pharmacological sensitivity of TCs
Using Laser Scanning Astrocyte Mapping (LSAM), we set out to determine the territory from which individual astrocytes remove glutamate from the extracellular space and the heterogeneity of TC decay kinetics within that area (Figure 1A)

Summary

Introduction

Developmental cortical malformations are a cause of focal cortical epilepsy and are often refractory to treatment (Schwartzkroin and Walsh, 2000; Crino, 2005). The freeze lesion (FL) model of cortical malformation is used to model these conditions and closely approximates human polymicrogyria (Dvorak et al, 1978; Jacobs et al, 1996, 1999). In addition to changes in neuronal systems, astroglial cells are altered in the FL model (Bordey and Sontheimer, 1998) and previous studies show that alterations in glutamate uptake occur (Campbell and Hablitz, 2008; Dulla et al, 2012). No studies have investigated glutamate uptake on a single cell basis in the FL model. Developmental processes and lesion-induced changes become intermingled. How neonatal insult affects developing astrocytic glutamate uptake, both acutely after lesion and more long term, is not well understood

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