NETO1 Guides Development of Glutamatergic Connectivity in the Hippocampus by Regulating Axonal Kainate Receptors

Subcellular localization of recombinant NETO proteins in hippocampal neurons. A, Example images of hippocampal neurons expressing recombinant NETO1-HA and NETO2-HA (blue). MAP2 (purple) negative axons are marked with arrowheads. Cell morphology is visualized with GFP (green) expression. Scale bar, 10 µm. B, Quantified data demonstrating delivery of lentivirally expressed NETO1-HA and NETO2-HA (blue) to MAP2-positive (purple) dendritic (NETO1-HA n = 31, NETO2-HA n = 39) and MAP2-negative axonal (NETO1-HA n = 27, NETO2-HA n = 26) processes in cultured hippocampal neurons. For quantification, the signal intensity in the neurites is normalized to the soma intensity. Scale bar, 10 µm. C, Example images and quantified data demonstrating colocalization of lentivirally expressed NETO1-HA (n = 27) and NETO2-HA (n = 26; blue) with presynaptic marker synaptophysin (Syn) (red). Scale bar, 10 µm.

Loss of NETO1 leads to impaired GluK1c delivery to distal axons. A, RT-PCR data depicting Neto1, Neto2, and housekeeping gene Gapdh expression in WT dispersed hippocampal neuron culture throughout the culture period (DIV4, DIV6, DIV11, and DIV14). B, Quantified data on the delivery of recombinant KAR subunits to distal axons in WT hippocampal neurons. K1b: flag-GluK1b (n = 45), K1c: flag-GluK1c (n = 24), K2: myc-GluK2 (n = 39), K4: myc-GluK4 (n = 30), and K5: myc-GluK5 (n = 41). Signal intensity in distal axons is normalized to intensity in cell soma. C, Example images of WT neurons expressing recombinant flag-GluK1b, flag-GluK1c, myc-GluK2, myc-GluK4, or myc-GluK5 (blue). MAP2 (purple) negative axons are marked with arrowheads. Cell morphology is visualized with GFP (green) expression. Scale bar, 10 µm. D, Example images illustrating delivery of various recombinant KAR subunits (blue) to distal (>150 µm from soma) MAP2 negative axons in WT, Neto1 ^−/−, and Neto2 ^−/− neurons. Scale bar, 10 µm. E, Averaged data comparing KAR subunit delivery to WT versus Neto1 ^−/− or Neto2 ^−/− axons. K1b n = 47 and n = 24, K1c n = 13 and n = 29, K2 n = 41 and n = 34, K4 n = 18 and n = 22, K5 n = 34 and n = 48 for Neto1 ^−/− and Neto2 ^−/−, respectively. Data are presented as % of corresponding values in the WT axons.

NETO1 is required for tonic activity of KARs at CA3-CA1 synapse in the neonatal hippocampus. A, Example traces illustrating recording of mEPSCs from CA1 pyramidal neurons in WT, Neto1 ^−/−, and Neto2 ^−/− slices (P5), under control conditions and in the presence of ACET (200 nM). B, time-course plots and averaged data demonstrating the effect of ACET (200 nM) on mEPSC frequency in WT (n = 7) and Neto2 ^−/− (n = 5), and Neto1 ^−/− (n = 7) slices (P4-P6). C, Example traces and pooled data demonstrating short-term facilitation of EPSCs in response to five-pulse 50-Hz stimulation in WT (n = 7) and Neto2 ^−/− (n = 8), but not in Neto1 ^−/− (n = 14) slices (P4-P6).

NETO1 deficiency leads to loss of functional presynaptic KARs at immature CA3-CA1 synapses that is rescued with GluK1c overexpression in the area CA3. A, Example traces and pooled data showing that ATPA (1 µM) decreases synaptic transmission at CA3-CA1 synapse in WT (n = 6) and Neto2 ^−/− (n = 7), but not in Neto1 ^−/− (n = 9) acute slices (P4-P6). B, Example traces and pooled data showing the effect of ATPA (1 µM) on EPSCs in two week old (P14-P16) WT (n = 7) and Neto1 ^−/− (n = 8) acute slices. C, Example traces of mEPSCs recorded from CA1 pyramidal neurons in WT and Neto1 ^−/− organotypic cultures expressing GFP or GluK1c in CA3 pyramidal layer, under control conditions (trace 1), in the presence of ACET (200 nM; trace 2), and during washout (trace 3). Images show the GFP or GluK1c/GFP expression in the CA3 pyramidal layer in the corresponding cultures (scale bar, 20 µm). D, Time-course plot demonstrating the effect of ACET (200 nM) on mEPSC frequency in WT organotypic cultures expressing GFP (WT n = 7) in area CA3. E, Time-course plot demonstrating the effect of ACET (200 nM) on mEPSC frequency in Neto1 ^−/− organotypic cultures expressing GFP (n = 5) or GluK1c (n = 4) in area CA3. F, Pooled data for the experiments depicted in D, E.

Loss of axonal GluK1c in Neto1 ^−/− neurons results in reduced density of synaptophysin immunopositive (Syn) puncta. A, Example images of Syn puncta (red) in MAP2 negative WT, Neto1 ^−/−, and Neto2 ^−/− axons with lentiviral expression of GFP, GFP + flag-GluK1b, GFP + flag-GluK1c, or GFP + myc-GluK2. For clarity, the blue channel with flag/myc staining is not shown. Scale bar, 10 µm. B, Quantification of the Syn puncta (red) density in the three genotypes with lentiviral expression of GFP (WT n = 31; Neto1 ^−/− n = 36; Neto2 ^−/− n = 28), GFP + flag-GluK1b (WT n = 28; Neto1 ^−/− n = 29; Neto2 ^−/− n = 24), GFP + flag-GluK1c (WT n = 28; Neto1 ^−/− n = 19; Neto2 ^−/− n = 31), or GFP + myc-GluK2 (WT n = 40; Neto1 ^−/− n = 30; Neto2 ^−/− n = 27).