Seizure-induced LIN28A disrupts pattern separation via aberrant hippocampal neurogenesis
In-Young Choi, Jung-Ho Cha, Seong Yun Kim, Jenny Hsieh, Kyung-Ok Cho
In-Young Choi, Jung-Ho Cha, Seong Yun Kim, Jenny Hsieh, Kyung-Ok Cho
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Research Article Neuroscience Stem cells

Seizure-induced LIN28A disrupts pattern separation via aberrant hippocampal neurogenesis

Abstract

Prolonged seizures can disrupt stem cell behavior in the adult hippocampus, an important brain structure for spatial memory. Here, using a mouse model of pilocarpine-induced status epilepticus (SE), we characterized spatiotemporal expression of Lin28a mRNA and proteins after SE. Unlike Lin28a transcripts, induction of LIN28A protein after SE was detected mainly in the subgranular zone, where immunoreactivity was found in progenitors, neuroblasts, and immature and mature granule neurons. To investigate roles of LIN28A in epilepsy, we generated Nestin-Cre:Lin28aloxP/loxP (conditional KO [cKO]) and Nestin-Cre:Lin28a+/+ (WT) mice to block LIN28A upregulation in all neuronal lineages after acute seizure. Adult-generated neuron- and hippocampus-associated cognitive impairments were absent in epileptic LIN28A-cKO mice, as evaluated by pattern separation and contextual fear conditioning tests, respectively, while sham-manipulated WT and cKO animals showed comparable memory function. Moreover, numbers of hilar PROX1-expressing ectopic granule cells (EGCs), together with PROX1+/NEUN+ mature EGCs, were significantly reduced in epileptic cKO mice. Transcriptomics analysis and IHC validation at 3 days after pilocarpine administration provided potential LIN28A downstream targets such as serotonin receptor 4. Collectively, our findings indicate that LIN28A is a potentially novel target for regulation of newborn neuron-associated memory dysfunction in epilepsy by modulating seizure-induced aberrant neurogenesis.

Authors

In-Young Choi, Jung-Ho Cha, Seong Yun Kim, Jenny Hsieh, Kyung-Ok Cho

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Figure 1

Spatiotemporal expression and cellular phenotypes of Lin28a transcripts in the hippocampus after pilocarpine-induced status epilepticus (SE).

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Spatiotemporal expression and cellular phenotypes of Lin28a transcripts ...
(A) A graph showing hippocampal Lin28a mRNA expression after SE. Mann-Whitney U test compared the experimental and sham groups. Sham vs. SE 1 day (d): P = 0.345, U = 16.000; sham vs. SE 4 d: P = 0.015, U = 11.000; sham vs. SE 7 d: P = 0.045, U = 6.000; sham vs. SE 14 d: P = 0.019, U = 4.000; sham vs. SE 28 d: P = 0.005, U < 0.001. Sham (n = 8), SE 1 d (n = 6), SE 4 d (n = 9), SE 7 d (n = 5), SE 14 d (n = 5), SE 28 d (n = 5). (B) Triple labeling of Lin28a mRNA and GFAP and IBA1 proteins after pilocarpine-induced SE. In situ hybridization with Lin28a antisense probe showed increased Lin28a transcripts at 1 d after SE, which was maintained for 28 d. Small cells showing Lin28a mRNA signals (white) were colocalized with GFAP (red) and IBA1 (green) immunoreactivity, indicating a mixture of astrocytes (yellow arrows) and microglia (yellow arrowheads). Scale bar: 200 μm. (C) Graphs showing temporal Lin28a mRNA, Lin28a/GFAP, and Lin28a/IBA1 in DG. Top graph: Welch’s ANOVA, P = 0.001, W(5.000, 13.410) = 8.184. Middle graph: Kruskal-Wallis H test, P = 0.002, H = 18.630. Bottom graph: Kruskal-Wallis H test, P = 0.007, H = 15.710. All tests were followed by 2-stage linear step-up procedure of Benjamini, Krieger, and Yekutieli post hoc test. Sham (n = 5), SE 1 d (n = 6), SE 3 d (n = 6), SE 7 d (n = 6), SE 14 d (n = 6), SE 28 d (n = 6). Data are presented as mean ± SEM. *P < 0.05, **P < 0.01.