Genetic and Clinical Investigation of Noonan Spectrum Disorders

Ekvall, Sara

January 2012

Noonan spectrum disorders belong to the RASopathies, a group of clinically related developmental disorders caused by dysregulation of the RAS-MAPK pathway. This thesis describes genetic and clinical investigations of six families with Noonan spectrum disorders. In the first family, the index patient presented with severe Noonan syndrome (NS) and multiple café-au-lait (CAL) spots, while four additional family members displayed multiple CAL spots only. Genetic analysis of four RAS-MAPK genes revealed a de novo PTPN11 mutation and a paternally inherited NF1 mutation, which could explain the atypically severe NS, but not the CAL spots trait in the family. The co-occurrence of two mutations was also present in another patient with a severe/complex NS-like phenotype. Genetic analysis of nine RASopathy-associated genes identified a de novo SHOC2 mutation and a maternally inherited PTPN11 mutation. The latter was also identified in her brother. Both the mother and the brother displayed mild phenotypes of NS. The results from these studies suggest that an additive effect of co-occurring mutations contributes to severe/complex NS phenotypes. The inherent difficulty in diagnosing Noonan spectrum disorders is evident in families with neurofibromatosis-Noonan syndrome (NFNS). An analysis of nine RASopathy-associated genes in a five-generation family with NFNS revealed a novel NF1 mutation in all affected family members. Notably, this family was initially diagnosed with NS and CAL spots. The clinical overlap between NS and NFNS was further demonstrated in three additional NFNS families. An analysis of twelve RASopathy-associated genes revealed three different NF1 mutations, all segregating with the disorder in each family. These mutations have been reported in patients with NF1, but have, to our knowledge, not been associated with NFNS previously. Together, these findings support the notion that NFNS is a variant of NF1. Due to the clinical overlap between NS and NFNS, we propose screening for NF1 mutations in NS patients negative for mutations in NS-associated genes, preferentially when CAL spots are present. In conclusion, this thesis suggests that co-occurrence of mutations or modifying loci in the RAS-MAPK pathway contributes to the clinical variability observed within Noonan spectrum disorders and further demonstrates the importance of accurate genetic diagnosis.

RASopathies

Noonan syndrome

neurofibromatosis type 1

neurofibromatosis-Noonan syndrome

RAS-MAPK pathway

mutation

De novo germline disorders of the Ras-MAPK pathway : clinical delineation, molecular diagnosis and pathogenesis

Burkitt Wright, Emma Mary Milborough

January 2014

This work sought to investigate the clinical phenotypes and molecular basis of cardio-facio-cutaneous syndrome (CFC), a germline disorder of the Ras-MAPK pathway, like Noonan syndrome (NS) and neurofibromatosis type I, caused by mutations in genes encoding proteins that act within this signal transduction pathway. CFC is most commonly due to mutation in BRAF, and less commonly MAP2K1, MAP2K2 or KRAS. A proportion of patients currently have no mutation identified. Mutations and clinical features of patients with a molecular diagnosis of CFC were investigated, which demonstrated a wide range of causative mutations, and some unclassified variants. Both known and novel clinical features of CFC were identified. A strong association between severe contractures and the p.(Tyr130Cys) mutation in MAP2K1 was found, which has not previously been reported. In contrast to the large number of patients with a confirmed molecular diagnosis, several with a highly suggestive clinical phenotype have been found to have no mutationin any of the known CFC genes. The molecular basis of these presentations was investigated by conventional Sanger sequencing of candidate genes. Fourteen patients with the p.(Ser2Gly) mutation in SHOC2 were identified, with clinical presentations consistent with CFC, NS or CS. Target enrichment and massively parallel sequencing of selected genes was undertaken in ten patients. Mutations in known genes were identified in four patients (including the positive control). Candidate causative variants in novel genes were suggested in two further patients, one of which was confirmed on Sanger sequencing. Whole exome sequencing of patient-parent trios was also undertaken to identify de novo variants. Three trios were analysed, and in one patient with a clinical diagnosis of CFC, a frameshift mutation in NF1 was identified, which was confirmed by Sanger sequencing to be present and de novo. The molecular effects of CFC-associated mutations in BRAF on Ras-MAPK pathway signalling were studied in cell culture systems, using Western blotting for ERK1/2 phosphorylation, in vitro kinase assays and luciferase assays, to assess activity of downstream targets of the Ras-MAPK pathway. Altered pathway activity was demonstrated for novel variants that had not previously been characterised at the molecular level, which was in keeping with the findings of the effects of previously studied mutations. The cardiac phenotype in animal models of CFC, CS and NS/CFC was explored using expression microarrays to identify potentially important genes and pathways in the pathogenesis of hypertrophic cardiomyopathy (a progressive but potentially treatable disease feature) in these conditions. A signature of increased expression of Myh7, the embryonic form of myosin, was identified in the heart of the mouse model of CFC due to a B-Raf mutation at four weeks postnatal age, but comparative analysis suggested significant differences in either the mechanisms causing cardiac phenotypes, or the timescales over which these may exert their effects, in the three models. In summary, the most significant findings of this work were that SHOC2 mutation is a frequent cause of a severe NCFC presentation, and massively parallel sequencing can be an effective means of molecular investigation of this group of disorders. Novel features of CFC syndrome that were identified include severe contractures in association with p.(Tyr130Cys) mutations in MAP2K1. The analysis of mouse models of the NCFCs was hampered by heterogeneity within the expression microarray results, and low levels of expression of the H-Ras mutant allele in the mouse model of Costellosyndrome.

612.6

Ciblage de la voie PI3K/mTOR dans les léiomyosarcomes : sensibilité et mécanismes de résistance / Targeting PI3K/mTOR pathway in leiomyosarcomas : sensitivity and mechanisms of resistance

Fourneaux, Benjamin

17 November 2017

Les léiomyosarcomes (LMS) sont des tumeurs d’origine mésenchymateuse caractérisées par une différenciation musculaire lisse. La voie de signalisation PI3K/mTOR (qui contrôle la prolifération et la survie cellulaire) joue un rôle majeur dans le développement de ces tumeurs. De nos jours, cette voie est devenue une cible thérapeutique majeure en oncologie. Cette étude est la première qui évalue le bénéfice thérapeutique de l’inhibition de la voie PI3K/mTOR pour des patients atteint de LMS. Nous avons mis en évidence qu’une double inhibition de PI3K et mTOR est associée à une activité antitumorale supérieure à celle observée avec une inhibition de PI3K ou mTOR seule. Nous avons également montré que l’inhibition de la voie PI3K/mTOR est associée à une activation paradoxale de la voie MAPK et qu’un ciblage concomitant de cette voie est associé à une synergie antitumorale in vitro et in vivo. Afin de caractériser les mécanismes de résistance secondaire à l’inhibition de la voie PI3K/mTOR, nous avons développé in vitro et in vivo un modèle de résistance secondaire à l’inhibiteur double cible PI3K/mTOR. Nous avons notamment détecté une sous-population de cellules résistantes à l’inhibiteur et ayant des caractéristiques proches de celles des cellules souches. Nous avons mis en évidence que l’inhibition pharmacologique d’EZH2, une protéine cruciale du complexe Polycomb, permet de restaurer la sensibilité des modèles résistants. Ces résultats apportent de nouvelles perspectives thérapeutiques pour les patients atteints de LMS. / Leiomyosarcomas (LMS) are tumors of mesenchymal origin characterized by a smooth cell differentiation. The PI3K/mTOR pathway has been shown to play a crucial role in the tumorigenesis of LMS. Several agents targeting this pathway are under clinical development for the treatment of solid tumors and hematological malignancies. We report here the first study evaluating its potential therapeutic benefit for patients with LMS. We have demonstrated that dual inhibition of PI3K and mTOR is associated with more effective antitumor activity than agents targeting PI3K or mTOR only. We have also shown that PI3K and mTOR inhibition is associated with a paradoxal activation of the MAPK pathway and that combined treatment with MEK inhibitor resulted in synergistic antitumor activity in vitro and in vivo. Moreover, we developed in vitro and in vivo resistant model to dual PI3K/mTOR inhibitor. Interestingly, we have found that a cancer stem cell-like subpopulation may be involved in treatment resistance. We have shown that pharmacological inhibition of EZH2, a crucial protein of the Polycomb complex, is able to reverse dual PI3K/mTOR inhibitor resistance in vitro and in vivo. These results provide new therapeutic strategies for patients with LMS.

Léiomyosarcome

Voie PI3K/mTOR

BEZ235

Voie RAS/MAPK

Résistance secondaire

Leiomyosarcoma

PI3K/mTOR pathway

BEZ235

RAS/MAPK pathway

Secondary resistance