Researchers find association of autism spectrum disorder, disrupted developmental dopamine

Pennsylvania [US], May 16 : According to recent research, dopamine is essential for the growth of neurons. Researchers have shown that autism spectrum disorder (ASD) and disrupted impaired developmental dopamine signalling are related.

Their findings open the door for future targeted therapies by highlighting the significance of researching developmental signalling pathways to comprehend the aetiology of ASD. Their research is published by Elsevier in The American Journal of Pathology.

Lead investigators Lingyan Xing, PhD, and Gang Chen, PhD, Key Laboratory of Neuroregeneration of Jiangsu and the Ministry of Education, Co-innovation Center of Neuroregeneration, NMPA Key Laboratory for Research and Evaluation of Tissue Engineering Technology Products, Nantong University, explained, "While dopamine is commonly recognized as a neurotransmitter, its significance in the developmental aspects of autism is largely unexplored. Recent studies have highlighted the crucial roles of dopamine and serotonin in development and their importance in the construction of neural circuits."

"In addition, studies have indicated that the use of dopamine-related drugs during pregnancy is associated with an increased risk of autism in children. Armed with these tantalizing clues, we embarked on a mission to bridge the gap between dopamine's known functions and its potential impact on neurodevelopmental disorders, particularly autism. Our quest was to uncover a novel therapeutic target that could revolutionize the way we approach autism treatment."

Investigators studied the role of disrupted dopaminergic signaling in the etiology of ASD by integrating human brain RNA sequencing transcriptome analysis and a zebrafish model, recognized for its high degree of conservation with humans.

To analyze the developmental deficits in ASD systematically, two large publicly available data sets were retrieved from the National Center for Biotechnology Information (NCBI) Gene Expression Omnibus database and RNA sequencing data from Arkinglab. Transcriptome analysis of human brains revealed significant correlations between changes in dopaminergic signaling pathways and neural developmental signaling in patients with autism. This suggests a potential link between disrupted developmental dopamine signaling and autism pathology.

To explore this link further researchers used the zebrafish model to study the effects of disrupted dopaminergic signaling on neural circuit development. They found that perturbations in developmental dopaminergic signaling led to neural circuit abnormalities and behavioral phenotypes reminiscent of autism in zebrafish larvae. The study also uncovered a potential mechanism by which dopamine impacts neuronal specification through the modulation of integrins.

Dr. Chen commented, "We were surprised by the extent of the impact that dopaminergic signaling has on neuronal specification in zebrafish, potentially laying the groundwork for circuit disruption in autism-related phenotype. Furthermore, the unexpected involvement of integrins as downstream targets of dopaminergic signaling provides new insights into the mechanisms underlying neurodevelopmental disorders."

Dr. Xing concluded, "This research sheds light on the role of dopamine in neural circuit formation during early development, specifically in the context of autism. Understanding these mechanisms could lead to novel therapeutic interventions targeting dopaminergic signaling pathways to improve outcomes in individuals with autism and other neurodevelopmental disorders."

ASD is a developmental disorder that usually manifests itself in early childhood. Although clinical outcomes vary greatly from case to case, autism is characterized by both a restricted interest in social interaction and repetitive behavior. This coincides with disruptions in brain connectivity shown by diffusion tension imaging. Studies have shown that several neurodevelopmental processes may be affected in ASD, including neurogenesis, neural migration, axon pathfinding, and synaptic formation, all of which can lead to neural circuit disruption.

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