The CB 1 cannabinoid receptor, the main target of Δ 9 -tetrahydrocannabinol (THC), the most prominent psychoactive compound of marijuana, plays a crucial regulatory role in brain development as evidenced by the neurodevelopmental consequences of its manipulation in animal models. Likewise, recreational cannabis use during pregnancy affects brain structure and function of the progeny. However, the precise neurobiological substrates underlying the consequences of prenatal THC exposure remain unknown. As CB 1 signaling is known to modulate long-range corticofugal connectivity, we analyzed the impact of THC exposure on cortical projection neuron development. THC administration to pregnant mice in a restricted time window interfered with subcerebral projection neuron generation, thereby altering corticospinal connectivity, and produced long-lasting alterations in the fine motor performance of the adult offspring. Consequences of THC exposure were reminiscent of those elicited by CB 1 receptor genetic ablation, and CB 1 -null mice were resistant to THC-induced alterations. The identity of embryonic THC neuronal targets was determined by a Cre-mediated, lineage-specific, CB 1 expression-rescue strategy in a CB 1 -null background. Early and selective CB 1 reexpression in dorsal telencephalic glutamatergic neurons but not forebrain GABAergic neurons rescued the deficits in corticospinal motor neuron development of CB 1 -null mice and restored susceptibility to THC-induced motor alterations. In addition, THC administration induced an increase in seizure susceptibility that was mediated by its interference with CB 1 -dependent regulation of both glutamatergic and GABAergic neuron development. These findings demonstrate that prenatal exposure to THC has long-lasting deleterious consequences in the adult offspring solely mediated by its ability to disrupt the neurodevelopmental role of CB 1 signaling.R ecreational cannabis consumption during pregnancy can exert deleterious consequences in the progeny, including anxiety, depression, psychosis risk, and cognitive and social impairments (1, 2). In the last two decades, important advances in our understanding of the endocannabinoid system have paved the way to elucidate the particular neurobiological substrates responsible for some cannabinoid-induced neurological alterations in adult animals and humans (3). The currently accepted scenario is that the CB 1 cannabinoid receptor (CB 1 R), the main target of marijuana-derived cannabinoids, is located presynaptically and, upon engagement by endocannabinoids [2-arachidonoylglycerol (2-AG) and anandamide], can act as a key neuromodulatory and plasticity-tuning signaling platform at many different mature synapses (4). In fact, CB 1 R constitutes one of the most abundant and functionally relevant G proteincoupled receptors in several regions of the adult mammalian brain (3, 4).Manipulation of CB 1 R function in animal models, either directly or indirectly, by modulating 2-AG or anandamide levels through the main endocannabinoid-synthesi...
