The Parvalbumin Hypothesis of Autism Spectrum Disorder
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Journal: 2021/January - Frontiers in Cellular Neuroscience
Abstract:
The prevalence of autism spectrum disorder (ASD)-a type of neurodevelopmental disorder-is increasing and is around 2% in North America, Asia, and Europe. Besides the known genetic link, environmental, epigenetic, and metabolic factors have been implicated in ASD etiology. Although highly heterogeneous at the behavioral level, ASD comprises a set of core symptoms including impaired communication and social interaction skills as well as stereotyped and repetitive behaviors. This has led to the suggestion that a large part of the ASD phenotype is caused by changes in a few and common set of signaling pathways, the identification of which is a fundamental aim of autism research. Using advanced bioinformatics tools and the abundantly available genetic data, it is possible to classify the large number of ASD-associated genes according to cellular function and pathways. Cellular processes known to be impaired in ASD include gene regulation, synaptic transmission affecting the excitation/inhibition balance, neuronal Ca2+ signaling, development of short-/long-range connectivity (circuits and networks), and mitochondrial function. Such alterations often occur during early postnatal neurodevelopment. Among the neurons most affected in ASD as well as in schizophrenia are those expressing the Ca2+-binding protein parvalbumin (PV). These mainly inhibitory interneurons present in many different brain regions in humans and rodents are characterized by rapid, non-adaptive firing and have a high energy requirement. PV expression is often reduced at both messenger RNA (mRNA) and protein levels in human ASD brain samples and mouse ASD (and schizophrenia) models. Although the human PVALB gene is not a high-ranking susceptibility/risk gene for either disorder and is currently only listed in the SFARI Gene Archive, we propose and present supporting evidence for the Parvalbumin Hypothesis, which posits that decreased PV level is causally related to the etiology of ASD (and possibly schizophrenia).
Keywords: E/I balance; GABAergic neurons; ROS; autism (ASD); calcium signal modulator; mitochondria; parvalbumin; schizophrenia.
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Front Cell Neurosci 14: 577525

The Parvalbumin Hypothesis of Autism Spectrum Disorder

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Section of Medicine, Anatomy, University of Fribourg, Fribourg, Switzerland
Edited by: Yu-Chih Lin, Hussman Institute for Autism, United States
Reviewed by: Nael Nadif Kasri, Radboud University Nijmegen, Netherlands; Christopher Pittenger, Yale University, United States; Rochelle Marie Hines, University of Nevada, Las Vegas, United States
*Correspondence: Beat Schwaller hc.rfinu@rellawhcs.taeb
This article was submitted to Cellular Neuropathology, a section of the journal Frontiers in Cellular Neuroscience
Section of Medicine, Anatomy, University of Fribourg, Fribourg, Switzerland
Edited by: Yu-Chih Lin, Hussman Institute for Autism, United States
Reviewed by: Nael Nadif Kasri, Radboud University Nijmegen, Netherlands; Christopher Pittenger, Yale University, United States; Rochelle Marie Hines, University of Nevada, Las Vegas, United States
Received 2020 Jun 29; Accepted 2020 Nov 10.
Copyright © 2020 Filice, Janickova, Henzi, Bilella and Schwaller.
This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

Abstract

The prevalence of autism spectrum disorder (ASD)—a type of neurodevelopmental disorder—is increasing and is around 2% in North America, Asia, and Europe. Besides the known genetic link, environmental, epigenetic, and metabolic factors have been implicated in ASD etiology. Although highly heterogeneous at the behavioral level, ASD comprises a set of core symptoms including impaired communication and social interaction skills as well as stereotyped and repetitive behaviors. This has led to the suggestion that a large part of the ASD phenotype is caused by changes in a few and common set of signaling pathways, the identification of which is a fundamental aim of autism research. Using advanced bioinformatics tools and the abundantly available genetic data, it is possible to classify the large number of ASD-associated genes according to cellular function and pathways. Cellular processes known to be impaired in ASD include gene regulation, synaptic transmission affecting the excitation/inhibition balance, neuronal Ca signaling, development of short-/long-range connectivity (circuits and networks), and mitochondrial function. Such alterations often occur during early postnatal neurodevelopment. Among the neurons most affected in ASD as well as in schizophrenia are those expressing the Ca-binding protein parvalbumin (PV). These mainly inhibitory interneurons present in many different brain regions in humans and rodents are characterized by rapid, non-adaptive firing and have a high energy requirement. PV expression is often reduced at both messenger RNA (mRNA) and protein levels in human ASD brain samples and mouse ASD (and schizophrenia) models. Although the human PVALB gene is not a high-ranking susceptibility/risk gene for either disorder and is currently only listed in the SFARI Gene Archive, we propose and present supporting evidence for the Parvalbumin Hypothesis, which posits that decreased PV level is causally related to the etiology of ASD (and possibly schizophrenia).

Keywords: parvalbumin, autism (ASD), calcium signal modulator, GABAergic neurons, E/I balance, schizophrenia, ROS, mitochondria
Abstract

Acknowledgments

We thank all investigators and collaborators in the many research labs (>35) worldwide (>10 countries) with whom we have had the privilege of collaborating and publishing many findings on the role of PV in the last two decades. The integration of results obtained in different transgenic mouse lines, various tissues and organs (brain, fast-twitch muscle, and kidney), and in cell-based systems allowed us to develop the Parvalbumin Hypothesis of ASD. Additionally, we thank Simone Eichenberger, Natascha Bersier, and Marie Bardet (University of Fribourg) for assistance in maintaining the mouse facility and Valerie Salicio, Marlene Sanchez, and Anne Oberson for technical assistance.

Acknowledgments

Footnotes

Funding. The experimental part of this study was supported by a Simons Foundation Autism Research Initiative (SFARI) Explorer award (# 603695) to BS and by the Swiss National Science Foundation SNF grants # 155952 and 184668 to BS.

Footnotes
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