Dopamine receptor autoantibody signaling in infectious sequelae differentiates movement versus neuropsychiatric disorders
Chandra M. Menendez, Jonathan Zuccolo, Susan E. Swedo, Sean Reim, Brian Richmand, Hilla Ben-Pazi, Abraham Kovoor, Madeleine W. Cunningham
Chandra M. Menendez, Jonathan Zuccolo, Susan E. Swedo, Sean Reim, Brian Richmand, Hilla Ben-Pazi, Abraham Kovoor, Madeleine W. Cunningham
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Research Article Immunology

Dopamine receptor autoantibody signaling in infectious sequelae differentiates movement versus neuropsychiatric disorders

Abstract

Despite growing recognition, neuropsychiatric diseases associated with infections are a major unsolved problem worldwide. Group A streptococcal (GAS) infections can cause autoimmune sequelae characterized by movement disorders, such as Sydenham chorea, and neuropsychiatric disorders. The molecular mechanisms underlying these diseases are not fully understood. Our previous work demonstrates that autoantibodies (AAbs) can target dopaminergic neurons and increase dopamine D2 receptor (D2R) signaling. However, AAb influence on dopamine D1 receptor (D1R) activity is underexplored. We found evidence that suggests GAS-induced cross-reactive AAbs promote autoimmune encephalitis of the basal ganglia, a region of high dopamine receptor density. Here, we report a mechanism whereby neuropsychiatric syndromes are distinguished from movement disorders by differences in D1R and D2R AAb titers, signaling, receiver operating characteristic curves, and immunoreactivity with D1R and D2R autoreactive epitopes. D1R AAb signaling was observed through patient serum AAbs and novel patient-derived monoclonal antibodies (mAbs), which induced both D1R G protein– and β-arrestin–transduced signals. Furthermore, patient AAbs and mAbs enhanced D1R signaling mechanisms mediated by the neurotransmitter dopamine. Our findings suggest that AAb-mediated D1R signaling may contribute to the pathogenesis of neuropsychiatric sequelae and inform new options for diagnosis and treatment of GAS sequelae and related disorders.

Authors

Chandra M. Menendez, Jonathan Zuccolo, Susan E. Swedo, Sean Reim, Brian Richmand, Hilla Ben-Pazi, Abraham Kovoor, Madeleine W. Cunningham

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Figure 7

PANDAS-derived human mAbs target D1R, induce agonistic responses, and enhance receptor signaling by dopamine.

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PANDAS-derived human mAbs target D1R, induce agonistic responses, and en...
(A) Human mAb 42.4.1 and mAb 3C3.1 reactivity with the human D1R by ELISA. (B) Human mAb 42.4.1 and mAb 3C3.1 stimulated cAMP induction in Tango D1-bla U2OS cells; dopamine was used at (0.001 M) as reference. Nonspecific mAb and mAb media controls were not quantifiable (NQ), as the ELISA values were below the standard curve. (C) Human mAbs 42.4.1 (red, **P = 0.0067) and 3C3.1 (blue, ****P < 0.0001) induced dose-dependent D1R agonistic signaling in Tango D1-bla U2OS cells versus media control (nonlinear regression, F test). (D) Human mAb 3C3.1 treatment with dopamine enhanced Tango D1-bla U2OS cells’ dopamine dose-response curve significantly, compared with dopamine alone, as per nonlinear regression, F test. (E) PANDAS sera–mediated (n = 5) D1R signaling of NS (nonsilencing control siRNA) or D1R siRNA–transfected D1R-bla U2OS. (F) PANDAS mAb–mediated signaling following D1R or NS siRNA transfection. In E and F, data represent the average of 3 technical replicates. *P < 0.05, **P < 0.01 by Mann-Whitney U test.