ABSTRACT Rhythmic spontaneous activity episodes, known as spontaneous network activity (SNA), occur throughout the central nervous system (CNS) at the time in which the first synaptic connections are established. During this time an early connectome is form and it is through later maturation and refinement of these early connections that adult synaptic circuitries with mature functionalities emerge. Therefore, the early development of this first connectivity is critical for later adult functional networks and when genetic or environmental factors disrupt SNA the resulting adult circuits are malformed and dysfunctional. For example, SNA mechanisms are disturbed in fetal alcohol spectrum disorders resulting in anomalous circuit development in the hippocampus. Similarly, many neurodevelopmental disorders like those in the autism spectrum display associated motor deficits in the newborn. SNA has been intensely studied in some CNS regions (retina, visual pathways, hippocampus) and the exact cellular interactions involved, the assembly and disassembly of the SNA network and its significance for maturation of correctly connected adult circuits are well known. Surprisingly, less is known about SNA in spinal cord motor circuits, despite this being an early model for the study of SNA mechanisms. Currently, the literature offers contradictory conclusions on the exact types of neurons involved in the SNA spinal network and the significance of SNA for spinal circuit development remains unexplored. These are critical gaps in our knowledge given the large number of motor syndromes in newborns with unknown etiology. This exploratory proposal stems from the serendipitous finding of profound ataxia and limb discoordination in mouse pups in which spinal inhibitory interneurons expressing the transcription factors engrailed 1 (En1) and forkhead box P2 (Foxp2) were chronically silenced throughout embryonic development. This suggests major dysfunction in adult spinal motor circuits controlling limbs and preliminary results suggest disruption of early SNA in the embryo. This genetic model could therefore offer a new entry point to interrogate cellular mechanisms in the network driving SNA in the spinal cord (Aim 1) and the consequences of SNA dysfunction for the later organization of key spinal motor circuits (Aim 2). For the second aim we will use as model the most basic of motor circuits composed by extensor and flexor motoneurons, Ia reciprocal inhibitory interneurons (many of which are En1-Foxp2) and Renshaw cells. This circuit displays a well-defined organization of specific connections that has been extensively studied for many years and therefore offers an unambiguous model to test the role of SNA in establishing specific connectivity. We hypothesize that its basic organization will be disrupted by anomalous early SNA given that the principal interneurons involved in the SNA network (Renshaw cells and Ia inhibitory interneurons) are also participants in this adu...