UBE3A expression during early postnatal brain development is required for proper dorsomedial striatal maturation
Diana C. Rotaru, Ilse Wallaard, Maud de Vries, Julia van der Bie, Ype Elgersma
Diana C. Rotaru, Ilse Wallaard, Maud de Vries, Julia van der Bie, Ype Elgersma
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Research Article Cell biology

UBE3A expression during early postnatal brain development is required for proper dorsomedial striatal maturation

Abstract

Angelman syndrome (AS) is a severe neurodevelopmental disorder (NDD) caused by loss of functional ubiquitin protein ligase E3A (UBE3A). Previous studies showed that UBE3A plays an important role in the first postnatal weeks of mouse brain development, but its precise role is unknown. Since impaired striatal maturation has been implicated in several mouse models for NDDs, we studied the importance of UBE3A in striatal maturation. We used inducible Ube3a mouse models to investigate the maturation of medium spiny neurons (MSNs) from dorsomedial striatum. MSNs of mutant mice matured properly till postnatal day 15 (P15) but remained hyperexcitable with fewer excitatory synaptic events at later ages, indicative of stalled striatal maturation in Ube3a mice. Reinstatement of UBE3A expression at P21 fully restored MSN excitability but only partially restored synaptic transmission and the operant conditioning behavioral phenotype. Gene reinstatement at P70 failed to rescue both electrophysiological and behavioral phenotypes. In contrast, deletion of Ube3a after normal brain development did not result in these electrophysiological and behavioral phenotypes. This study emphasizes the role of UBE3A in striatal maturation and the importance of early postnatal reinstatement of UBE3A expression to obtain a full rescue of behavioral phenotypes associated with striatal function in AS.

Authors

Diana C. Rotaru, Ilse Wallaard, Maud de Vries, Julia van der Bie, Ype Elgersma

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Figure 1

Absence of UBE3A generates increased firing rates and decreased excitatory transmission in MSNs from mature DMS.

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Absence of UBE3A generates increased firing rates and decreased excitato...
(A) Representative firing pattern of MSNs (top) obtained with current injection (bottom); thick traces represent the response to rheobase current. (B) F-I curves, 1-way repeated measures (RM) ANOVA (F1,49 = 7.90, P = 0.0005). (C) Rheobase, 2-tailed unpaired t test (t = 5.17 df = 47, P = 0.0001). (D) Maximum firing rate, 2-tailed unpaired t test (t = 0.66 df = 47, P = 0.52). (E) F-I slope, 2-tailed unpaired t test (t = 0.33 df = 47, P = 0.75). (F) Representative voltage responses of MSNs (top), obtained by 30 pA current increments between –100 pA and +140 pA (bottom). (G) Input resistance at hyperpolarized domain, 2-tailed unpaired t test (t = 3.16 df = 47, P = 0.0028). (H) Input resistance at depolarized domain, 2-tailed unpaired t test (t = 3.03 df = 47 P = 0.0041). (I) Examples of single AP. (J) AP threshold, 2-tailed unpaired t test (t = 1.12 df = 47, P = 0.26). (K) Representative recordings of sEPSCs from MSNs. (L) Representative average sEPSCs. (M) sEPSC frequency, 2-tailed unpaired t test (t = 3.63 df = 39, P = 0.0008). (N) sEPSC amplitude, 2-tailed unpaired t test (t = 0.17 df = 39, P = 0.87). Sample size (N = neurons/mice) for BE and GJ: WT: N = 27/7; LSL: N = 21/5 and for M and N: WT: N = 20/7; LSL: N = 21/5. Data represented as dot plots (1 neuron) with mean ± SEM. **P ≤ 0.01, ***P ≤ 0.001. See also Supplemental Table 1.