RATIONALE: The genetic heterogeneity of autism spectrum disorders (ASDs) is enormous, and the neurobiology of proteins encoded by genes associated with ASD is very diverse. Revealing the mechanisms on which different neurobiological pathways in ASD pathogenesis converge may lead to the identification of drug targets. OBJECTIVE: The main objective is firstly to outline the main molecular networks and neuronal mechanisms in which ASD gene products participate and secondly to answer the question how these converge. Finally, we aim to pinpoint drug targets within these mechanisms. METHOD: Literature review of the neurobiological properties of ASD gene products with a special focus on the developmental consequences of genetic defects and the possibility to reverse these by genetic or pharmacological interventions. RESULTS: The regulation of activity-dependent protein synthesis appears central in the pathogenesis of ASD. Through sequential consequences for axodendritic function, neuronal disabilities arise expressed as behavioral abnormalities and autistic symptoms in ASD patients. Several known ASD gene products have their effect on this central process by affecting protein synthesis intrinsically, e.g., through enhancing the mammalian target of rapamycin (mTOR) signal transduction pathway or through impairing synaptic function in general. These are interrelated processes and can be targeted by compounds from various directions: inhibition of protein synthesis through Lovastatin, mTOR inhibition using rapamycin, or mGluR-related modulation of synaptic activity. CONCLUSIONS: ASD gene products may all feed into a central process of translational control that is important for adequate glutamatergic regulation of dendritic properties. This process can be modulated by available compounds but may also be targeted by yet unexplored routes.
RATIONALE: The genetic heterogeneity of autism spectrum disorders (ASDs) is enormous, and the neurobiology of proteins encoded by genes associated with ASD is very diverse. Revealing the mechanisms on which different neurobiological pathways in ASD pathogenesis converge may lead to the identification of drug targets. OBJECTIVE: The main objective is firstly to outline the main molecular networks and neuronal mechanisms in which ASD gene products participate and secondly to answer the question how these converge. Finally, we aim to pinpoint drug targets within these mechanisms. METHOD: Literature review of the neurobiological properties of ASD gene products with a special focus on the developmental consequences of genetic defects and the possibility to reverse these by genetic or pharmacological interventions. RESULTS: The regulation of activity-dependent protein synthesis appears central in the pathogenesis of ASD. Through sequential consequences for axodendritic function, neuronal disabilities arise expressed as behavioral abnormalities and autistic symptoms in ASDpatients. Several known ASD gene products have their effect on this central process by affecting protein synthesis intrinsically, e.g., through enhancing the mammalian target of rapamycin (mTOR) signal transduction pathway or through impairing synaptic function in general. These are interrelated processes and can be targeted by compounds from various directions: inhibition of protein synthesis through Lovastatin, mTOR inhibition using rapamycin, or mGluR-related modulation of synaptic activity. CONCLUSIONS:ASD gene products may all feed into a central process of translational control that is important for adequate glutamatergic regulation of dendritic properties. This process can be modulated by available compounds but may also be targeted by yet unexplored routes.
Authors: Georg Stoll; Olli P H Pietiläinen; Bastian Linder; Jaana Suvisaari; Cornelia Brosi; William Hennah; Virpi Leppä; Minna Torniainen; Samuli Ripatti; Sirpa Ala-Mello; Oliver Plöttner; Karola Rehnström; Annamari Tuulio-Henriksson; Teppo Varilo; Jonna Tallila; Kati Kristiansson; Matti Isohanni; Jaakko Kaprio; Johan G Eriksson; Olli T Raitakari; Terho Lehtimäki; Marjo-Riitta Jarvelin; Veikko Salomaa; Matthew Hurles; Hreinn Stefansson; Leena Peltonen; Patrick F Sullivan; Tiina Paunio; Jouko Lönnqvist; Mark J Daly; Utz Fischer; Nelson B Freimer; Aarno Palotie Journal: Nat Neurosci Date: 2013-08-04 Impact factor: 24.884
Authors: M Neves-Pereira; B Müller; D Massie; J H G Williams; P C M O'Brien; A Hughes; S-B Shen; David St Clair; Z Miedzybrodzka Journal: J Med Genet Date: 2009-06-25 Impact factor: 6.318
Authors: Michael Bucher; Stephan Niebling; Yuhao Han; Dmitry Molodenskiy; Fatemeh Hassani Nia; Hans-Jürgen Kreienkamp; Dmitri Svergun; Eunjoon Kim; Alla S Kostyukova; Michael R Kreutz; Marina Mikhaylova Journal: Elife Date: 2021-05-04 Impact factor: 8.140