Abstract
The elucidation of the molecular mechanisms of long-term synaptic plasticity has been hindered by both the compensation that can occur after chronic loss of the core plasticity molecules and by ex vivo conditions that may not reproduce in vivo plasticity. Here we describe a novel method to rapidly suppress gene expression by antisense oligodeoxynucleotides (ODNs) applied to rodent brain slices in an "Oslo-type" interface chamber. The method has three advantageous features: 1) rapid blockade of new synthesis of the targeted proteins that avoids genetic compensation, 2) efficient oxygenation of the brain slice, which is critical for reproducing in vivo conditions of long-term synaptic plasticity, and 3) a recirculation system that uses only small volumes of bath solution (< 5 ml), reducing the amount of reagents required for long-term experiments lasting many hours. The method employs a custom-made recirculation system involving piezoelectric micropumps and was first used for the acute translational blockade of protein kinase Mζ (PKMζ) synthesis during long-term potentiation (LTP) by Tsokas et al., 2016. In that study, applying antisense-ODN rapidly prevents the synthesis of PKMζ and blocks late-LTP without inducing the compensation by other protein kinase C (PKC) isoforms that occurs in PKCζ/PKMζ knockout mice. In addition, we show that in a low-oxygenation submersion-type chamber, applications of the atypical PKC inhibitor, zeta inhibitory peptide (ZIP), can result in unstable baseline synaptic transmission, but in the high-oxygenation, "Oslo-type" interface electrophysiology chamber, the drug reverses late-LTP without affecting baseline synaptic transmission. This comparison reveals that the interface chamber, but not the submersion chamber, reproduces the effects of ZIP in vivo. Therefore, the protocol combines the ability to acutely block new synthesis of specific proteins for the study of long-term synaptic plasticity, while maintaining properties of synaptic transmission that reproduce in vivo conditions relevant for long-term memory.
Highlights
Part I: artificial cerebrospinal fluid (ACSF) Recirculation System AssemblyNote: The bottom two mp6-OEM controllers will supply the inflow lines (perfusing the top and bottom sides of the mesh) of the bath of the interface chamber, and their flow rate is adjustable by the bottom Arduino Uno, which is connected to Pin 2 (Cyan, added in Step 22) (Figure 2, and Figures 15A and 15B)
[Background] Ex vivo acute brain slices have been a useful experimental model for studies of neural
ODNs can bind to complementary regions of a specific mRNA, usually located near the translation start site (AUG, in Figure 1A, top), and physically block the ability of ribosomes to move along the mRNA, preventing synthesis of the protein
Summary
Note: The bottom two mp6-OEM controllers will supply the inflow lines (perfusing the top and bottom sides of the mesh) of the bath of the interface chamber, and their flow rate is adjustable by the bottom Arduino Uno, which is connected to Pin 2 (Cyan, added in Step 22) (Figure 2, and Figures 15A and 15B). Connect Inputs B1, B2, B3, B4, B5, B6 of the top logic level converter to Digital Pins 2, 3, 4, 5, 6, 7, respectively, of the top Arduino Uno, as shown in Figure 12 (White cables). 1. Assemble the six cables connecting the six Molex connectors (one per mp[6] micropump) to the Breakout Board 26-pin ribbon cable, as shown in Figures 2B and 15E.
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