Top

Acta Neuropathologica Communications

Published in:

Open Access 01-12-2015 | Research

Decreased mTOR signaling pathway in human idiopathic autism and in rats exposed to valproic acid

Authors: Chiara Nicolini, Younghee Ahn, Bernadeta Michalski, Jong M Rho, Margaret Fahnestock

Published in: Acta Neuropathologica Communications | Issue 1/2015

Abstract

Background

The molecular mechanisms underlying autistic behaviors remain to be elucidated. Mutations in genes linked to autism adversely affect molecules regulating dendritic spine formation, function and plasticity, and some increase the mammalian target of rapamycin, mTOR, a regulator of protein synthesis at spines. Here, we investigated whether the Akt/mTOR pathway is disrupted in idiopathic autism and in rats exposed to valproic acid, an animal model exhibiting autistic-like behavior.

Methods

Components of the mTOR pathway were assayed by Western blotting in postmortem fusiform gyrus samples from 11 subjects with idiopathic autism and 13 controls and in valproic acid versus saline-exposed rat neocortex. Additionally, protein levels of brain-derived neurotrophic factor receptor (TrkB) isoforms and the postsynaptic organizing molecule PSD-95 were measured in autistic versus control subjects.

Results

Full-length TrkB, PI3K, Akt, phosphorylated and total mTOR, p70S6 kinase, eIF4B and PSD-95 were reduced in autistic versus control fusiform gyrus. Similarly, phosphorylated and total Akt, mTOR and 4E-BP1 and phosphorylated S6 protein were decreased in valproic acid- versus saline-exposed rats. However, no changes in 4E-BP1 or eIF4E were found in autistic brains.

Conclusions

In contrast to some monogenic disorders with high rates of autism, our data demonstrate down-regulation of the Akt/mTOR pathway, specifically via p70S6K/eIF4B, in idiopathic autism. These findings suggest that disruption of this pathway in either direction is widespread in autism and can have adverse consequences for synaptic function. The use of valproic acid, a histone deacetylase inhibitor, in rats successfully modeled these changes, implicating an epigenetic mechanism in these pathway disruptions.

American Psychiatric Association (1994) Diagnostic and Statistical Manual of Mental Disorders, 5th edn. American Psychiatric Press, Washington, DC

Kelleher RJ 3rd, Bear MF (2008) The autistic neuron: troubled translation? Cell 135:401–406PubMedCrossRef

Troca-Marin JA, Alves-Sampaio A, Montesinos ML (2012) Deregulated mTOR-mediated translation in intellectual disability. Prog Neurobiol 96:268–282PubMedCrossRef

Levitt P, Campbell DB (2009) The genetic and neurobiologic compass points toward common signaling dysfunctions in autism spectrum disorders. J Clin Invest 119:747–754PubMedCentralPubMedCrossRef

Ehninger D, Silva AJ (2011) Rapamycin for treating Tuberous sclerosis and Autism spectrum disorders. Trends Mol Med 17:78–87PubMedCentralPubMedCrossRef

Gkogkas CG, Khoutorsky A, Ran I, Rampakakis E, Nevarko T, Weatherill DB et al (2013) Autism-related deficits via dysregulated eIF4E-dependent translational control. Nature 493:371–377PubMedCentralPubMedCrossRef

Hutsler JJ, Zhang H (2010) Increased dendritic spine densities on cortical projection neurons in autism spectrum disorders. Brain Res 1309:83–94PubMedCrossRef

Löscher V (2002) Basic pharmacology of valproate. A review after 35 years of clinical use for the treatment of epilepsy. CNS Drugs 16:669–694PubMedCrossRef

Lambert PA, Carraz G, Borselli S, Bouchardy M (1975) Dipropylacetamide in the treatment of manic-depressive psychosis. Encéphale 1:25–31PubMed

10.

Emrich HM, von Zerssen D, Kissling W, Möller HG, Windorfer A (1980) Effect of sodium valproate on mania. The GABA-hypothesis of affective disorders. Acta Psychiatr Nervenkr 229:1–16CrossRef

11.

Christianson AL, Chesler N, Kromberg JG (1994) Fetal valproate syndrome: clinical and neuro-developmental features in two sibling pairs. Dev Med Child Neurol 36:361–369PubMedCrossRef

12.

Moore SJ, Turnpenny P, Quinn A, Glover S, Lloyd DJ, Montgomery T et al (2000) A clinical study of 57 children with fetal anticonvulsant syndromes. J Med Genet 37:489–497PubMedCentralPubMedCrossRef

13.

Christensen J, Gronborg TK, Sorensen MJ, Schendel D, Parner ET, Pedersen LH et al (2013) Prenatal exposure and risk of autism spectrum disorders and childhood autism. JAMA 309:1696–1703PubMedCrossRef

14.

Markram H, Rinaldi T, Markram K (2007) The intense world syndrome- an alternative hypothesis for autism. Front Neurosci 1:77–96PubMedCentralPubMedCrossRef

15.

Stanton ME, Peloso E, Brown KL, Rodier P (2007) Discrimination learning and reversal of the conditioned eyeblink reflex in a rodent model of autism. Behav Brain Res 176:133–140PubMedCentralPubMedCrossRef

16.

Roulett FI, Wollaston L, Decatanzaro D, Foster JA (2010) Behavioural and molecular changes in the mouse in response to prenatal exposure to the anti-epileptic drug valproic acid. Neuroscience 170:514–522CrossRef

17.

Kataoka S, Takuma K, Hara Y, Maeda Y, Ago Y, Matsuda T (2013) Autism-like behaviours with transient histone hyperacetylation in mice treated prenatally with valproic acid. Int J Neuropsychopharmacol 16:91–103PubMedCrossRef

18.

Schneider T, Przewlocki R (2005) Behavioural alterations in rats prenatally exposed to valproic acid: animal model of autism. Neuropsychopharmacology 30:80–89PubMedCrossRef

19.

Markram K, Rinaldi T, La Mendola D, Sandi C, Markram H (2008) Abnormal fear conditioning and amygdala processing in an animal model of autism. Neuropsychopharmacology 33:901–912PubMedCrossRef

20.

Rodier PM, Ingram JL, Tisdale B, Croog VJ (1997) Linking etiologies in humans and animal models: studies of autism. Reprod Toxicol 11:417–422PubMedCrossRef

21.

Ingram JL, Peckham SM, Tisdale B, Rodier PM (2000) Prenatal exposure of rats to valproic acid reproduces the cerebellar anomalies associated with autism. Neurotoxicol Teratol 22:319–324PubMedCrossRef

22.

Narita N, Kato M, Tazoe M, Miyazaki K, Narita M, Okado N (2002) Increased monoamine concentration in the brain and blood of fetal thalidomide- and valproic acid-exposed rat: putative animal models for autism. Pediatr Res 52:576–579PubMed

23.

Kolozsi E, Mackenzie RN, Roulett FI, deCatanzaro D, Foster JA (2009) Prenatal exposure to valproic acid leads to reduced expression of synptic adhesion molecule neuroligin 3 in mice. Neuroscience 163:1201–1210PubMedCrossRef

24.

Rinaldi T, Silberberg G, Markram H (2008) Hyperconnectivity of local neocortical microcircuitry induced by prenatal exposure to valproic acid. Cereb Cortex 18:763–770PubMedCrossRef

25.

Rinaldi T, Perrodin C, Markram H (2008) Hyper-connectivity and hyper-plasticity in the medial prefrontal cortex in the valproic acid animal model of autism. Front Neural Circuits 2:4PubMedCentralPubMedCrossRef

26.

Schanen NC (2006) Epigenetics of autism spectrum disorders. Hum Mol Genet 2:138–150CrossRef

27.

Wong CC, Meaburn EL, Ronald A, Price TS, Jeffries AR, Schwalkwyk LC et al (2014) Methylomic analysis of monozygotic twins discordant for autism spectrum disorder and related behavioural traits. Mol Psychiatry 19:495–503PubMedCentralPubMedCrossRef

28.

Garcia KLP, Guanhua Y, Nicolini C, Michalski B, Garzon D, Chiu VS et al (2012) Altered balance of proteolytic forms of pro-brain-derived neurotrophic factor in autism. J Neuropathol Exp Neurol 71:289–297PubMedCentralPubMedCrossRef

29.

Boucher J, Lewis V (1992) Unfamiliar face recognition in relatively able autistic children. J Child Psychol Psychiatry 33:843–859PubMedCrossRef

30.

Allison T, Ginter H, McCarthy G, Nobre AC, Puce A, Luby M et al (1994) Face recognition in human extrastriate cortex. J Neurophysiol 71:821–825PubMed

31.

Gauthier I, Anderson AW, Tarr MJ, Skudlarski P, Gore JC (1997) Levels of categorization in visual recognition studied using functional magnetic resonance imaging. Curr Biol 7:645–651PubMedCrossRef

32.

Schultz RT, Gauthier I, Klin A, Fulbright RK, Anderson AW, Volkmar F et al (2000) Abnormal ventral temporal cortical activity during face discrimination among individuals with autism and Asperger syndrome. Arch Gen Psychiatry 57:331–340PubMedCrossRef

33.

Lord C, Rutter M, Le Couteur A (1994) Autism diagnostic interview-revised. A revised version of a diagnostic interview for caregivers of individuals with possible pervasive developmental disorders. Autism Dev Dis 24:659–685CrossRef

34.

Chomiak T, Karnik V, Block E, Hu B (2010) Altering the trajectory of early postnatal cortical development can lead to structural and behavioural features of autism. BMC Neurosci 11:102PubMedCentralPubMedCrossRef

35.

Menna E, Zambetti S, Morini R, Donzelli A, Disanza A, Calvigioni D et al (2013) Eps8 controls dendritic spine density and synaptic plasticity through its actin-capping activity. EMBO J 32:1730–1744PubMedCentralPubMedCrossRef

36.

Ricciardi S, Boggio EM, Grosso S, Lonetti G, Forlani G, Stefanelli G et al (2011) Reduced AKT/mTOR signaling and protein synthesis dysregulation in a Rett syndrome animal model. Hum Mol Genet 20:1182–1196PubMedCrossRef

37.

Yoshii A, Constantine-Paton M (2010) Postsynaptic BDNF-TrkB signaling in synapse maturation, plasticity, and disease. Dev Neurobiol 70:304–322PubMedCentralPubMed

38.

Newcombe J, Woodroofe MN, Cuzner ML (1986) Distribution of glial fibrillary acidic protein in gliosed human white matter. J Neurochem 47:1713–1719PubMedCrossRef

39.

Fatemi SH, Folsom TD (2011) Dysregulation of fragile X mental retardation protein and metabotropic glutamate receptor 5 in superior frontal cortex of individuals with autism: a postmortem brain study. Mol Autism 2:6PubMedCentralPubMedCrossRef

40.

Bourgeron T (2009) A synaptic trek to autism. Curr Opin Neurobiol 19:231–234PubMedCrossRef

41.

Hoeffer CA, Klann E (2010) mTOR signaling: at the crossroads of plasticity, memory and disease. Trends Neurosci 33:67–75PubMedCentralPubMedCrossRef

42.

Sheikh AM, Malik M, Wen G, Chauhan A, Chauhan V, Gong CX et al (2010) BDNF-Akt-Bcl2 antiapoptotic signaling pathway is compromised in the brain of autistic subjects. J Neurosci Res 88:2641–2647PubMed

43.

Zoghbi HY, Bear MF (2012) Synaptic dysfunction in neurodevelopmental disorders associated with autism and intellectual disabilities. Cold Spring Harb Perspect Biol 4(3):a009886PubMedCentralPubMedCrossRef

44.

Hay N, Sonenberg N (2004) Upstream and downstream of mTOR. Genes Dev 18:1926–1945PubMedCrossRef

45.

Jaworski J, Spangler S, Seeburg DP, Hoogenraad CC, Sheng M (2005) Control of dendritic arborization by the phosphoinositide-3′-kinase–Akt–mammalian target of rapamycin pathway. J Neurosci 25:11300–11312PubMedCrossRef

46.

Santos AR, Comprido D, Duarte CB (2010) Regulation of local translation at the synapse by BDNF. Prog Neurobiol 92:505–516PubMedCrossRef

47.

Santini E, Klann E (2011) Dysregulated mTORC1-dependent translational control: From brain disorders to psychoactive drugs. Front Behav Neurosci 5:76PubMedCentralPubMedCrossRef

48.

Neves-Pereira M, Müller B, Massie D, Williams JH, O’Brien PC, Hughes A et al (2009) Deregulation of EIF4E: A novel mechanism for autism. J Med Genet 46:759–765PubMedCrossRef

49.

Ahn Y, Narous M, Tobias R, Hu B, Rho JM (2012) Alterations in social behavior and mTOR signaling in the valproic acid-induced model of autism spectrum disorder, Program No. 861.21. 2012 Neuroscience Meeting Planner. Society for Neuroscience, New Orleans, LA, Online

50.

Williams RS, Hauser SL, Purpura DP, DeLong GR, Swisher CN (1980) Autism and mental retardation: neuropathologic studies performed in four retarded persons with autistic behavior. Arch Neurol 37:749–753PubMedCrossRef

51.

Correia CT, Coutinho AM, Sequeira AF, Sousa IG, Lourenço Venda L, Almeida JP et al (2010) Increased BDNF levels and NTRK2 gene association suggest a disruption of BDNF/TrkB signaling in autism. Genes Brain Behav 9:841–848PubMedCrossRef

52.

Weickert CS, Ligons DL, Romanczyk T, Ungaro G, Hyde TM, Herman MM et al (2005) Reductions in neurotrophin receptor mRNAs in the prefrontal cortex of patients with schizophrenia. Mol Psychiatry 10:637–650PubMedCrossRef

53.

Pillai A, Mahadik SP (2008) Increased truncated TrkB receptor expression and decreased BDNF/TrkB signaling in the frontal cortex of reeler mouse model of schizophrenia. Schizophr Res 100:325–333PubMedCrossRef

54.

Waterhouse EG, Xu B (2009) New insights into the role of brain-derived neurotrophic factor in synaptic plasticity. Mol Cell Neurosci 42:81–89PubMedCentralPubMedCrossRef

55.

Klein R, Conway D, Parada LF, Barbacid M (1990) The trkB tyrosine protein kinase gene codes for a second neurogenic receptor that lacks the catalytic kinase domain. Cell 61:647–656PubMedCrossRef

56.

Wong J, Rothmond DA, Webster MJ, Weickert C (2013) Increases in two truncated TrkB isoforms in the prefrontal cortex of people with schizophrenia. Schizophr Bull 39:130–140PubMedCentralPubMedCrossRef

57.

Eide FF, Vining ER, Eide BL, Zang K, Wang XY, Reichardt LF (1996) Naturally occurring truncated trkB receptors have dominant inhibitory effects on brain-derived neurotrophic factor signaling. J Neurosci 16:3123–3129PubMedCentralPubMed

58.

Haapasalo A, Koponen E, Hoppe E, Wong G, Castrén E (2001) Truncated trkB.T1 is dominant negative inhibitor of trkB.TK + −mediated cell survival. Biochem Biophys Res Commun 280:1352–1358PubMedCrossRef

59.

Stoilov P, Castren E, Stamm S (2002) Analysis of the human TrkB gene genomic organization reveals novel TrkB isoforms, unusual gene length, and splicing mechanism. Biochem Biophys Res Commun 290:1054–1065PubMedCrossRef

60.

Klein R, Parada LF, Coulier F, Barbacid M (1989) TrkB, a novel tyrosine protein kinase receptor expressed during mouse neural development. EMBO J 8:3701–3709PubMedCentralPubMed

61.

Klein R, Nanduri V, Jing SA, Lamballe F, Tapley P, Bryant S et al (1991) The trkB tyrosine protein kinase is a receptor for brain-derived neurotrophic factor and neurotrophin-3. Cell 66:395–403PubMedCentralPubMedCrossRef

62.

Rose CR, Blum R, Pichler B, Lepier A, Kafitz KW, Konnerth A (2003) Truncated TrkB-T1 mediates neurotrophin-evoked calcium signaling in glia cells. Nature 426:74–78PubMedCrossRef

63.

Romanczyk TB, Weickert CS, Webster MJ, Herman MM, Akil M, Kleinman JE (2002) Alterations in trkB mRNA in the human prefrontal cortex throughout the lifespan. Eur J Neurosci 15:269–280PubMedCrossRef

64.

Ohira K, Hayashi M (2003) Expression of TrkB subtypes in the adult monkey cerebellar cortex. J Chem Neuroanat 25:175–183PubMedCrossRef

Title: Decreased mTOR signaling pathway in human idiopathic autism and in rats exposed to valproic acid
Authors: Chiara Nicolini
Younghee Ahn
Bernadeta Michalski
Jong M Rho
Margaret Fahnestock
Publication date: 01-12-2015
Publisher: BioMed Central
Published in: Acta Neuropathologica Communications / Issue 1/2015
Electronic ISSN: 2051-5960
DOI: https://doi.org/10.1186/s40478-015-0184-4

2024 ASCO Annual Meeting

Springer Medicine

Decreased mTOR signaling pathway in human idiopathic autism and in rats exposed to valproic acid

Abstract

Background

Methods

Results

Conclusions

2024 ASCO Annual Meeting

Springer Medicine

Abstract

Background

Methods

Results

Conclusions

Please log in to get access to this content

Other articles of this Issue 1/2015

The defining pathology of the new clinical and histopathologic entity ACTA2-related cerebrovascular disease

Intracellular amyloid β oligomers impair organelle transport and induce dendritic spine loss in primary neurons

IL-6 and Akt are involved in muscular pathogenesis in myasthenia gravis

Neuropathologic analysis of Tyr69His TTR variant meningovascular amyloidosis with dementia

The A673T mutation in the amyloid precursor protein reduces the production of β-amyloid protein from its β-carboxyl terminal fragment in cells

Early neurone loss in Alzheimer’s disease: cortical or subcortical?