Congenital pituitary hypoplasia model demonstrates hypothalamic OTX2 regulation of pituitary progenitor cells
Ryusaku Matsumoto, Hidetaka Suga, Takashi Aoi, Hironori Bando, Hidenori Fukuoka, Genzo Iguchi, Satoshi Narumi, Tomonobu Hasegawa, Keiko Muguruma, Wataru Ogawa, Yutaka Takahashi
Ryusaku Matsumoto, Hidetaka Suga, Takashi Aoi, Hironori Bando, Hidenori Fukuoka, Genzo Iguchi, Satoshi Narumi, Tomonobu Hasegawa, Keiko Muguruma, Wataru Ogawa, Yutaka Takahashi
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Research Article Development Endocrinology

Congenital pituitary hypoplasia model demonstrates hypothalamic OTX2 regulation of pituitary progenitor cells

Abstract

Pituitary develops from oral ectoderm in contact with adjacent ventral hypothalamus. Impairment in this process results in congenital pituitary hypoplasia (CPH); however, there have been no human disease models for CPH thus far, prohibiting the elucidation of the underlying mechanisms. In this study, we established a disease model of CPH using patient-derived induced pluripotent stem cells (iPSCs) and 3D organoid technique, in which oral ectoderm and hypothalamus develop simultaneously. Interestingly, patient iPSCs with a heterozygous mutation in the orthodenticle homeobox 2 (OTX2) gene showed increased apoptosis in the pituitary progenitor cells, and the differentiation into pituitary hormone–producing cells was severely impaired. As an underlying mechanism, OTX2 in hypothalamus, not in oral ectoderm, was essential for progenitor cell maintenance by regulating LHX3 expression in oral ectoderm via FGF10 expression in the hypothalamus. Convincingly, the phenotype was reversed by the correction of the mutation, and the haploinsufficiency of OTX2 in control iPSCs revealed a similar phenotype, demonstrating that this mutation was responsible. Thus, we established an iPSC-based congenital pituitary disease model, which recapitulated interaction between hypothalamus and oral ectoderm and demonstrated the essential role of hypothalamic OTX2.

Authors

Ryusaku Matsumoto, Hidetaka Suga, Takashi Aoi, Hironori Bando, Hidenori Fukuoka, Genzo Iguchi, Satoshi Narumi, Tomonobu Hasegawa, Keiko Muguruma, Wataru Ogawa, Yutaka Takahashi

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Figure 5

CRISPR/Cas9–based correction of the mutation in OTX2 restored the phenotype of OTX2mut-iPSCs.

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CRISPR/Cas9–based correction of the mutation in OTX2 restored the phenot...
(A) Quantitative RT-PCR for LHX3 mRNA expression in OTX2mut-iPSCs and OTX2mut-repaired-iPSCs at day 40. Representative data from 4 independent experiments are shown. The line within the box indicates the median, the edge of the box represents the first and third quartiles, and the whiskers are the range of data excluding outliers; n = 7 per group. **P < 0.01, Kruskal-Wallis test (χ2 = 16.8, df = 2, P < 0.001) followed by post hoc Steel’s test. Post hoc comparison with OTX2mut-iPSCs (far left) is presented. (B) Immunostaining of OTX2mut- and OTX2mut -repaired-iPSCs. OTX2mut-repaired-iPSCs restored LHX3 expression in oral ectoderm (indicated with dashed lines) (at day 40). (C) FGF10 expression in the hypothalamus was restored in OTX2mut-repaired-iPSCs (at day 40). (D) The induction of ACTH- and GH-producing cells was restored in OTX2mut-repaired-iPSCs (at day 100). (E and F) The ability to secrete hormones and the response to releasing hormones were restored in OTX2mut-repaired-iPSCs at day 100. Representative data from 4 independent experiments are shown. The line within the box indicates the median, the edge of the box represents the first and third quartiles, and the whiskers are the range of data excluding outliers; n = 7 per group for ACTH, n = 4 per group for GH;. *P < 0.05, **P < 0.01, Kruskal-Wallis test (ACTH without CRH, χ2 = 15.0, df = 2, P < 0.001; ACTH with CRH, χ2 = 14.0, df = 2, P < 0.001; GH without GHRH, χ2 = 8.34, df = 2, P = 0.015; GH with GHRH, χ2 = 7.54, df = 2, P = 0.023) followed by post hoc Steel’s test. Post hoc comparison with OTX2mut-iPSCs (far left) is presented. O, oral ectoderm; H, hypothalamus progenitor. Scale bars: 100 μm.