Noonan Syndrome (NS, OMIM 163950) is a condition characterized by typical craniofacial abnormalities, congenital cardiac defects, pulmonic stenosis, a wide spectrum of cognitive disorders causing a wide spectrum of mild/moderate mental retardation and learning disabilities (ranging from attention deficits to language impairments), multiple skeletal defects, cryptorchidism, short stature.
More than 50% of the NS cases are caused by mutations in the PTPN11 gene, and 10-20% of the cases by mutations on SOS1 gene, encoding for two proteins, SHP2 and SOS1 respectively, that possess critical roles in the activation and regulation of the RAS/MAPK pathway.
In both cases, mutations result in an abnormal gain-of-function, with mutations insisting on residues maintaining the proteins in an auto-inhibited state for SHP2 and mutations strengthening the interaction with Grb2 in the case of SOS1.
The projects is based on the hypothesis that an effective therapeutic strategy for NS would be based on the recovery of the SHP2 and SOS1 normal functions. This aim will be achieved by studying the mechanisms
of activation of SHP2 and SOS1 and designing small molecules to hijack the functions of these two proteins in the naturally occurring NS mutants.
The experimental plan is, therefore, based on the synergy between experimental and computational techniques focussed on the understanding of the molecular details of the gain-of-function of SHP2 and SOS1 in NS. In parallel, small molecules stabilizing the autho-inhibitied state of the two proteins will be selected via virtual screening and, subsequently, studied in vitro.
We expect to provide a mechanistic characterization of the most prominent mutations associated with NS and to identify one or more lead compound aimed at reducing the gain-of-function observed in the pathological conditions.
There is no single treatment for Noonan syndrome and, therefore, this severe genetic disease is currently treated by addressing individually the different associated problems and symptoms.
By understanding the mechanistic details underlying the molecular bases of NS and, consequently, by being able to design specific drugs to restore the wild-type condition in naturally occurring mutants (with specific emphasis on PTPN11 and SOS1), the proposed project has the potential to pave the way to the discovery of an effective strategy to treat NS.
The project will tackle for the first time the mechanistic details of the gain-of-function of SHP2 and Sos1 for Noonan Syndrome mutants. These aims will represent a relevant step forward in the understanding of Noonan Syndrome.
No biophysical data is available to date on the molecular basis of this disease.
Furthermore, the computational selection and in vitro testing of possible drugs to modulate the gain-of-function of SHP2 and Sos1 for Noonan Syndrome mutants represents a tantalizing possibility to relieve this disease. Whilst such a goal is relatively ambitious, appears rather feasible as the experimantal approach described in the Project has been previously successful on similar small domain protein systems.