Brain-wide genetic mapping identifies the indusium griseum as a prenatal and shared target of pharmacologically-unrelated psychostimulants

Psychostimulant use is an ever-increasing socioeconomic burden, including a dramatic rise during pregnancy. Nevertheless, brain-wide effects of psychostimulant exposure are incompletely understood. Here, we performed Fos-CreER-based activity mapping, correlated for pregnant mouse dams and their fetuses with amphetamine, nicotine and caffeine applied acutely during mid-gestation. While light-sheet microscopy-assisted intact tissue imaging revealed drug- and age-specific neuronal activation, the indusium griseum (IG) appeared indiscriminately affected. By using GAD67 mice we subdivided the IG into a dorsolateral domain populated by GABA interneurons and a ventromedial segment containing glutamatergic neurons, many showing drug-induced activation and sequentially expressing and secretagogin (Scgn) during differentiation. We then combined Patch-seq and circuit mapping to show that the ventromedial IG is a quasi-continuum of glutamatergic neurons (IG-Vglut1) reminiscent to dentate granule cells in both rodents and humans, whose dendrites emanate perpendicularly towards, while their axons course parallel with the superior longitudinal fissure. IG-Vglut1 neurons receive Vglut1 and Vglut2 excitatory afferents that topologically segregate along their somatodendritic axis. In turn, their efferents terminate in the olfactory bulb, thus being integral to a multi-synaptic circuit that could feed information antiparallel to the olfactory-cortical pathway. In IG-Vglut1 neurons, prenatal psychostimulant exposure delayed the onset of Scgn expression. Genetic ablation of Scgn was then found to sensitize adult mice towards methamphetamine-induced epilepsy, suggesting a role for this Ca-binding protein in scaling IG-Vglut1 neuronal excitability. Overall, our study identifies brain-wide targets of the most common psychostimulants, among which Scgn/Vglut1 neurons of the IG link limbic and olfactory circuits.