Hamartoma-like lesions in the mouse retina: an animal model of Pten hamartoma tumour syndrome.

Nobuhiko Tachibana,Yacine Touahri,Carol Schuurmans,Robert Cantrup,Tooka Aavani,Kyle C Kurek,Cairine Logan,Rajiv Dixit,Rachel O Wong,Luke Ajay David,Lata Adnani

doi:10.1242/dmm.031005

Abstract

ABSTRACTPTEN hamartoma tumour syndrome (PHTS) is a heterogeneous group of rare, autosomal dominant disorders associated with PTEN germline mutations. PHTS patients routinely develop hamartomas, which are benign tissue overgrowths comprised of disorganized ‘normal’ cells. Efforts to generate PHTS animal models have been largely unsuccessful due to the early lethality of homozygous germline mutations in Pten, together with the lack of hamartoma formation in most conditional mutants generated to date. We report herein a novel PHTS mouse model that reproducibly forms hamartoma-like lesions in the central retina by postnatal day 21. Specifically, we generated a Pten conditional knockout (cKO) using a retinal-specific Pax6::Cre driver that leads to a nearly complete deletion of Pten in the peripheral retina but produces a mosaic of ‘wild-type’ and Pten cKO cells centrally. Structural defects were only observed in the mosaic central retina, including in Müller glia and in the outer and inner limiting membranes, suggesting that defective mechanical integrity partly underlies the hamartoma-like pathology. Finally, we used this newly developed model to test whether rapamycin, an mTOR inhibitor that is currently the only PHTS therapy, can block hamartoma growth. When administered in the early postnatal period, prior to hamartoma formation, rapamycin reduces hamartoma size, but also induces new morphological abnormalities in the Pten cKO retinal periphery. In contrast, administration of rapamycin after hamartoma initiation fails to reduce lesion size. We have thus generated and used an animal model of retinal PHTS to show that, although current therapies can reduce hamartoma formation, they might also induce new retinal dysmorphologies.This article has an associated First Person interview with the first author of the paper.

Highlights

The basic body plan is established during development, dictating the size and positioning of each cell type for optimal tissue functioning
We questioned whether the Pten conditional knock-out (cKO) central lesions were developmental defects, or whether they arose post-cellular differentiation, which is complete by P7 in the central retina and P12 in the peripheral retina (Young, 1985)
By examining retinas between P7, the earliest time point we detected the hamartoma-like lesions, and P21, we revealed that central morphological defects developed progressively over time, with 37.5% (n=18/48), 68.42% (n=13/19) and 100% (n=49/49) of Pten cKO retinas displaying central dysmorphologies that were not detectable in wild-type retinas at P7 (Fig. 1C,D), P14 (Fig. 1E,F) and P21 (Fig. 1G,H), respectively (Fig. 1I)

Summary

Introduction

The basic body plan is established during development, dictating the size and positioning of each cell type for optimal tissue functioning. PTEN (phosphatase and tensin homolog) is a wellknown negative regulator of cell growth and an essential determinant of tissue patterning (Cantrup et al, 2012; Yamada and Araki, 2001). It encodes a lipid and protein phosphatase that controls the phosphorylation status of membrane phospholipids by removing a 3'-phosphate from PIP3 (phosphatidyl-inositol-3,4,5-triphosphate) to convert it to PIP2 (phosphatidylinositol-4,5bisphosphate), counteracting the activity of phosphoinositide-3-kinase (PI3K), which phosphorylates PIP2 to generate PIP3. Formation of CNS hamartomas can have devastating consequences, resulting in neurological dysfunction such as epilepsy, ASD, and vision loss (Echevarria et al, 2014; Mansoor and Steel, 2012; Pilarski et al, 2013)

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