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Defective jagged-1 signaling affects GnRH development and contributes to congenital hypogonadotropic hypogonadism
Ludovica Cotellessa, Federica Marelli, Paolo Duminuco, Michela Adamo, Georgios E. Papadakis, Lucia Bartoloni, Naoko Sato, Mariarosaria Lang-Muritano, Amineh Troendle, Waljit S. Dhillo, Annamaria Morelli, Giulia Guarnieri, Nelly Pitteloud, Luca Persani, Marco Bonomi, Paolo Giacobini, Valeria Vezzoli
Ludovica Cotellessa, Federica Marelli, Paolo Duminuco, Michela Adamo, Georgios E. Papadakis, Lucia Bartoloni, Naoko Sato, Mariarosaria Lang-Muritano, Amineh Troendle, Waljit S. Dhillo, Annamaria Morelli, Giulia Guarnieri, Nelly Pitteloud, Luca Persani, Marco Bonomi, Paolo Giacobini, Valeria Vezzoli
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Research Article Development Genetics

Defective jagged-1 signaling affects GnRH development and contributes to congenital hypogonadotropic hypogonadism

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Abstract

In vertebrate species, fertility is controlled by gonadotropin-releasing hormone (GnRH) neurons. GnRH cells arise outside the central nervous system, in the developing olfactory pit, and migrate along olfactory/vomeronasal/terminal nerve axons into the forebrain during embryonic development. Congenital hypogonadotropic hypogonadism (CHH) and Kallmann syndrome are rare genetic disorders characterized by infertility, and they are associated with defects in GnRH neuron migration and/or altered GnRH secretion and signaling. Here, we documented the expression of the jagged-1/Notch signaling pathway in GnRH neurons and along the GnRH neuron migratory route both in zebrafish embryos and in human fetuses. Genetic knockdown of the zebrafish ortholog of JAG1 (jag1b) resulted in altered GnRH migration and olfactory axonal projections to the olfactory bulbs. Next-generation sequencing was performed in 467 CHH unrelated probands, leading to the identification of heterozygous rare variants in JAG1. Functional in vitro validation of JAG1 mutants revealed that 7 out of the 9 studied variants exhibited reduced protein levels and altered subcellular localization. Together our data provide compelling evidence that Jag1/Notch signaling plays a prominent role in the development of GnRH neurons, and we propose that JAG1 insufficiency may contribute to the pathogenesis of CHH in humans.

Authors

Ludovica Cotellessa, Federica Marelli, Paolo Duminuco, Michela Adamo, Georgios E. Papadakis, Lucia Bartoloni, Naoko Sato, Mariarosaria Lang-Muritano, Amineh Troendle, Waljit S. Dhillo, Annamaria Morelli, Giulia Guarnieri, Nelly Pitteloud, Luca Persani, Marco Bonomi, Paolo Giacobini, Valeria Vezzoli

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Figure 5

jag1b, but not jag1a, affects the distribution of GnRH3 neurons and their axonal projections.

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jag1b, but not jag1a, affects the distribution of GnRH3 neurons and the...
(A) Schematic representations of 48 hpf zebrafish embryos and representing the distribution of GnRH3 cell bodies (red dots) and of GnRH3 neurites (green lines) under the indicated experimental conditions. (B) Confocal analysis of tg(GnRH3:EGFP) control embryos and jag1a + jag1b double morphants at 48 hpf and 72 hpf, respectively. The experiments were performed 5 times with n = 15 EGFP-positive embryos/condition. (C) Confocal analysis of tg(GnRH3:EGFP) control embryos and jag1a and jag1b morphants at 48 hpf. Arrows indicate GnRH3-positive cells in the OP; arrowheads indicate GnRH3 fibers in the AC and innervating hypothalamus. HYP, hypothalamus. Red arrows indicate the somata of GnRH3+ cells. Red arrowheads highlight the GnRH3+ fiber in the AC or innervating hypothalamus at 72 hpf. (D) Percentage of embryos showing a scattered GnRH3+ cell phenotype between controls and jag1b morphants at 48 hpf. (E) Percentage of embryos showing a defasciculation of the AC between controls and jag1b morphants at 48 hpf. Mann-Whitney U test followed by a Fisher’s exact test. (F and G) Representative confocal images of tg(omp2k:gap-CFP rw034) control (F) and jag1b MO embryos (G). The experiments were performed 4 times with n = 15 tg(omp2k:gap-CFP rw034) embryos/condition. Scale bars: 100 μm, B and C; 50 μm, F and G.

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