The epigenetic reader PHF21B modulates murine social memory and synaptic plasticity–related genes
Eunice W.M. Chin, … , Julio Licinio, Ma-Li Wong
Eunice W.M. Chin, … , Julio Licinio, Ma-Li Wong
Published July 22, 2022
Citation Information: JCI Insight. 2022;7(14):e158081. https://doi.org/10.1172/jci.insight.158081.
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Research Article Neuroscience

The epigenetic reader PHF21B modulates murine social memory and synaptic plasticity–related genes

Abstract

Synaptic dysfunction is a manifestation of several neurobehavioral and neurological disorders. A major therapeutic challenge lies in uncovering the upstream regulatory factors controlling synaptic processes. Plant homeodomain (PHD) finger proteins are epigenetic readers whose dysfunctions are implicated in neurological disorders. However, the molecular mechanisms linking PHD protein deficits to disease remain unclear. Here, we generated a PHD finger protein 21B–depleted (Phf21b-depleted) mutant CRISPR mouse model (hereafter called Phf21bΔ4/Δ4) to examine Phf21b’s roles in the brain. Phf21bΔ4/Δ4 animals exhibited impaired social memory. In addition, reduced expression of synaptic proteins and impaired long-term potentiation were observed in the Phf21bΔ4/Δ4 hippocampi. Transcriptome profiling revealed differential expression of genes involved in synaptic plasticity processes. Furthermore, we characterized a potentially novel interaction of PHF21B with histone H3 trimethylated lysine 36 (H3K36me3), a histone modification associated with transcriptional activation, and the transcriptional factor CREB. These results establish PHF21B as an important upstream regulator of synaptic plasticity–related genes and a candidate therapeutic target for neurobehavioral dysfunction in mice, with potential applications in human neurological and psychiatric disorders.

Authors

Eunice W.M. Chin, Qi Ma, Hongyu Ruan, Camille Chin, Aditya Somasundaram, Chunling Zhang, Chunyu Liu, Martin D. Lewis, Melissa White, Tracey L. Smith, Malcolm Battersby, Wei-Dong Yao, Xin-Yun Lu, Wadih Arap, Julio Licinio, Ma-Li Wong

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Figure 1

Generation and verification of Phf21bΔ4/Δ4 animals.

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Generation and verification of Phf21bΔ4/Δ4 animals. (A) Alignment of PHF...
(A) Alignment of PHF21B cDNA sequences in Phf21b+/+ (+/+) and Phf21bΔ4/Δ4 (Δ4/Δ4) mice. Pink regions depict the sequences that were deleted in the Δ4/Δ4 mouse model. (B) Quantification of Phf21b mRNA transcript expression in +/+ and Δ4/Δ4 hippocampal tissues by using 2 different targeting primer pairs; n = 4–5/group. (C) Representative images of (top panels) hippocampal Western blots (each lane is an individual animal) and (bottom panels) immunostained nuclei of CA1 neurons of PHF21B expression levels in +/+ and Δ4/Δ4 animals; scale bar: 20 μm. (D) Quantification of PHF21B immunoblot (left, n = 6/group) and signal intensity in immunostained (right, n = 5/group) +/+ and Δ4/Δ4 hippocampal sections. (E) mRNA transcript expression of (from left to right) Shank3, Phf21a, Kdm1a, and Scn1a in +/+ and Δ4/Δ4 animals, evaluated once; n = 10/group. Values are presented as mean ± SEM (B, D left graph, and E) or minimum to maximum and line at the median (D right graph); Student’s t test/Mann-Whitney test; * P < 0.05; ** P < 0.01; *** P < 0.001; **** P < 0.0001.