The Genetic Backdrop of Hypogonadotropic Hypogonadism

The pituitary is an organ of dual provenance: the anterior lobe is epithelial in origin, whereas the posterior lobe derives from the neural ectoderm. The pituitary gland is a pivotal element of the axis regulating reproductive function in mammals. It collects signals from the hypothalamus, and by secreting gonadotropins (FSH and LH) it stimulates the ovary into cyclic activity resulting in a menstrual cycle and in ovulation. Pituitary organogenesis is comprised of three main stages controlled by different signaling molecules: first, the initiation of pituitary organogenesis and subsequent formation of Rathke’s pouch; second, the migration of Rathke’s pouch cells and their proliferation; and third, lineage determination and cellular differentiation. Any disruption of this sequence, e.g., gene mutation, can lead to numerous developmental disorders. Gene mutations contributing to disordered pituitary development can themselves be classified: mutations affecting transcriptional determinants of pituitary development, mutations related to gonadotropin deficiency, mutations concerning the beta subunit of FSH and LH, and mutations in the DAX-1 gene as a cause of adrenal hypoplasia and disturbed responsiveness of the pituitary to GnRH. All these mutations lead to disruption in the hypothalamic–pituitary–ovarian axis and contribute to the development of primary amenorrhea.

SIX3 Variant Causes Pituitary Stalk Interruption Syndrome and Combined Pituitary Hormone Deficiency

The genetic basis for congenital hypopituitarism and related disorders is beginning to emerge, and over 30 causal genes have been identified. Mutations in some of these genes can also cause holoprosencephaly (HPE) or septo-optic dysplasia. SIX3 is a homeodomain protein expressed in the developing brain, pituitary gland, and eye. Heterozygous mutations in SIX3 cause variable HPE in humans and mice. We identified two children with neonatal GH and TSH deficiency and stalk interruption who were doubly heterozygous for rare, likely deleterious variants in SIX3 and POU1F1. Functional studies demonstrated that both variants are disruptive. We used Six3 and Pou1f1 loss of function mice to assess the genetic interaction between Six3 and Pou1f1. Six3 heterozygotes have variable pituitary gland dysmorphology, while Pou1f1 heterozygotes are normal. A significant portion of the Six3+/-; Pou1f1+/dw doubly heterozygous mice have a more pronounced pituitary phenotype than Six3+/-, supporting the possibility of digenic pituitary disease. To understand the role of SIX3 in pituitary and hypothalamic development, we used Prop1-cre and Nkx2.1-cre to delete Six3. Disruption of Six3 expression in Rathke’s pouch caused poor activation of Lhx3 expression and arrested anterior pituitary development. The Nkx2.1-cre, Six3flox/flox embryos had no evidence of infundibulum evagination and failed to induce FGF and BMP signaling, which normally drive expansion of Rathke’s pouch. By E11.5 cells in Rathke’s pouch underwent apoptosis. The Nkx2.1-cre, Six3flox/flox embryos failed to activate expression of Lhx2 and Tbx3 in the neural ectoderm. These embryos had elevated CCND1, MYCN, and Axin2 expression in the area of the presumptive infundibulum. This indicates that SIX3 is necessary to repress cell proliferation and Wnt/beta-catenin signals to promote formation of the pituitary stalk. Thus, Six3 has essential roles in both the neural and oral ectoderm for hypothalamic and pituitary development, respectively. Heterozygous loss of function variants in SIX3 could be a contributor to multiple pituitary hormone deficiencies in children, especially if there are associated craniofacial abnormalities or PSIS.

SAT-291 SIX3 Is Essential for Hypothalamic and Pituitary Development

The genetic basis for congenital hypopituitarism and related disorders is beginning to emerge, and over causal 30 genes have been identified, including six in the SHH signaling pathway. Mutations in some of these genes can also cause holoprosencephaly (HPE) or septo-optic dysplasia. SIX3 is a homeodomain protein expressed in the developing brain, pituitary gland, and eye. It activates SHH signaling and represses BMP signaling. Heterozygous mutations in SIX3 cause variable HPE in humans and mice. We identified a rare, heterozygous variant in SIX3 in two children with neonatal GH and TSH deficiency and stalk interruption, p.P74R. Using transient transfection in 3T3 cells, we demonstrated that the variant reduced the ability of SIX3 to transactivate the SHH enhancer and promoter of FOXG1, suggesting that the variant could be deleterious. To understand the role of SIX3 in hypothalamic and pituitary development we used Nkx2.1-cre and Prop1-cre to delete Six3 in mice. The Nkx2.1-cre, Six3flox/flox embryos had no evidence of infundibulum evagination or expression of Fgf10 or Tcf7l2 at e11.5. The oral ectoderm invaginated in mutants, but no definitive Rathke’s pouch formed. There was no evidence of Lhx3 expression and only trace amounts of Pitx1, indicating that pituitary induction failed due to the lack of Six3 in the developing hypothalamus. Similarly, disruption of Six3 expression in Rathke’s pouch using Prop1-cre ablated pituitary development. Together, these data reveal essential roles of Six3 in both the neural and oral ectoderm for hypothalamic and pituitary development, respectively. Heterozygous loss of function variants in SIX3 could be a contributor to multiple pituitary hormone deficiencies in children, especially if there are associated craniofacial abnormalities.

SAT-288 Pituitary Developmental Defects Caused by Haploinsufficiency for the Transcription Factor SIX3 Are Worsened by POU1F1 Deficiency

Advances in genomic technologies are revolutionizing the practice of medicine by delivering molecular diagnoses that can be informative for prognosis and treatment of genetic disorders. Most of the known genetic causes of multiple pituitary hormone deficiency have been investigated as monogenic disorders. It can be challenging to predict clinical features from genetic data, as loss of function mutations in some genes can present with a spectrum of phenotypes ranging from craniofacial abnormalities, intellectual disability, and neurosensory and neuroendocrine defects to pituitary hormone deficiency with no other abnormalities. Although maternal exposures could be contributing factors, the contribution of rare, deleterious variation in other genes is a likely contributor. In humans, loss of function mutations in the transcription factor SIX3 cause variable, autosomal dominant holoprosencephaly with incomplete penetrance, and mouse models recapitulate some of the clinical features. Because Six3 and Pou1f1 gene expression patterns overlap in pituitary development, we hypothesized that doubly heterozygous mice (Six3+/-; Pou1f1+/dw) might have pituitary anomalies not present in singly heterozygous mice. We intercrossed Six3+/- and Pou1f1+/dw mice to produce doubly heterozygous animals. At e11.5, both Six3+/- and Six3+/-; Pou1f1+/dw exhibited abnormal morphology of the developing infundibulum and Rathke’s pouch, although ventral diencephalon expression of Tle4, Fgf10, and Nkx2.1 appeared normal. Both newborn Six3+/- and Six3+/-; Pou1f1+/dw littermates had abnormal pituitary gland morphology that resembled that of Aes-/-. AES is a co-repressor that interacts with SIX3. Specification of vasopressin neurons and anterior lobe hormone cell types appeared normal. Mice of all genotypes were born in expected Mendelian ratios (N=144, p=0.49), and there were no significant differences in body weight at 3 wks. A portion of the Six3+/- and doubly heterozygous mice developed hydrocephalus, exhibited failure to thrive, and died (6-9% of N=82, 85, respectively). At 6 wks, 25% (N=61) of the Six3+/-; Pou1f1+/dw animals exhibited striking pituitary dysmorphology in which the rostral aspect of the pituitary penetrated the palate. This was not observed in single heterozygotes. These results reveal that haploinsufficiency for Six3 affects Rathke’s pouch formation, resulting in pituitary gland dysmorphology in and around the stem cell niche. A significant portion of the Six3+/-; Pou1f1+/dw doubly heterozygous mice have a more pronounced pituitary phenotype than Six3+/-, supporting the possibility of digenic pituitary disease and highlighting phenotypic variability. Genetically engineered mice provide an excellent tool for assessing the possibility of gene-gene interactions that could enhance the severity of hypopituitarism and associated craniofacial development.

Hydrocephalus and hypothalamic involvement in pediatric patients with craniopharyngioma or cysts of Rathke's pouch: impact on long-term prognosis

ObjectivePediatric patients with sellar masses such as craniopharyngioma (CP) or cyst of Rathke's pouch (CRP) frequently suffer disease- and treatment-related sequelae. We analyzed the impact and prognostic relevance of initial hydrocephalus (HY) and hypothalamic involvement (HI) on long-term survival and functional capacity (FC) in children with CP or CRP.Subjects and methodsUsing retrospective analysis of patient records, presence of initial HY or HI was assessed in 177 pediatric patients (163 CP and 14 CRP). Twenty-year overall survival (OS) and progression-free survival (PFS), FC, and BMI were analyzed with regard to initial HY, degree of resection, or HI.ResultsOf the 177 patients, 105 patients (103/163 CP and 2/14 CRP) presented with initial HY and 96 presented with HI. HY at diagnosis was associated (P=0.000) with papilledema, neurological deficits, and higher BMI at diagnosis and during follow-up. OS, PFS, and FC were not affected by HY at initial diagnosis. HI at diagnosis (96/177) had major negative impact on long-term prognosis. Sellar masses with HI were associated with lower OS (0.84±0.04; P=0.021), lower FC (P=0.003), and higher BMI at diagnosis and last follow-up (P=0.000) when compared with sellar masses without HI (OS: 0.94±0.05). PFS was not affected by HI or degree of resection.ConclusionsInitial HY has no impact on outcome in patients with sellar masses. OS and FC are impaired in survivors presenting with initial HI. PFS is not affected by HY, HI, or degree of resection. Accordingly, gross-total resection is not recommended in sellar masses with initial HI to prevent further hypothalamic damage.