Shank2 Identifies a Subset of Glycinergic Neurons Involved in Altered Nociception in an Autism Model

Overview

Journal Mol Autism

Publisher Biomed Central

Date 2023 Jun 14

PMID 37316943

Authors

Florian Olde Heuvel

Najwa Ouali Alami

Oumayma Aousji

Esther Pogatzki-Zahn

Peter K Zahn

Hanna Wilhelm

Dhruva Deshpande

Elmira Khatamsaz

Alberto Catanese

Sarah Woelfle

Michael Schon

Sanjay Jain

Stefanie Grabrucker

Albert C Ludolph

Chiara Verpelli

Jens Michaelis

Tobias M Boeckers

Francesco Roselli

Affiliations

Soon will be listed here.

Abstract

Background: Autism Spectrum Disorders (ASD) patients experience disturbed nociception in the form of either hyposensitivity to pain or allodynia. A substantial amount of processing of somatosensory and nociceptive stimulus takes place in the dorsal spinal cord. However, many of these circuits are not very well understood in the context of nociceptive processing in ASD.

Methods: We have used a Shank2 mouse model, which displays a set of phenotypes reminiscent of ASD, and performed behavioural and microscopic analysis to investigate the role of dorsal horn circuitry in nociceptive processing of ASD.

Results: We determined that Shank2 mice display increased sensitivity to formalin pain and thermal preference, but a sensory specific mechanical allodynia. We demonstrate that high levels of Shank2 expression identifies a subpopulation of neurons in murine and human dorsal spinal cord, composed mainly by glycinergic interneurons and that loss of Shank2 causes the decrease in NMDAR in excitatory synapses on these inhibitory interneurons. In fact, in the subacute phase of the formalin test, glycinergic interneurons are strongly activated in wild type (WT) mice but not in Shank2 mice. Consequently, nociception projection neurons in laminae I are activated in larger numbers in Shank2 mice.

Limitations: Our investigation is limited to male mice, in agreement with the higher representation of ASD in males; therefore, caution should be applied to extrapolate the findings to females. Furthermore, ASD is characterized by extensive genetic diversity and therefore the findings related to Shank2 mutant mice may not necessarily apply to patients with different gene mutations. Since nociceptive phenotypes in ASD range between hyper- and hypo-sensitivity, diverse mutations may affect the circuit in opposite ways.

Conclusion: Our findings prove that Shank2 expression identifies a new subset of inhibitory interneurons involved in reducing the transmission of nociceptive stimuli and whose unchecked activation is associated with pain hypersensitivity. We provide evidence that dysfunction in spinal cord pain processing may contribute to the nociceptive phenotypes in ASD.

Citing Articles

Expression profiles of the autism-related SHANK proteins in the human brain.

Woelfle S, Pedro M, Wagner J, Schon M, Boeckers T BMC Biol. 2023; 21(1):254.

PMID: 37953224 PMC: 10641957. DOI: 10.1186/s12915-023-01712-0.

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