Abstract
The mechanisms specifying neuronal diversity are well characterized, yet it remains unclear how or if these mechanisms regulate neural circuit assembly. To address this, we mapped the developmental origin of 160 interneurons from seven bilateral neural progenitors (neuroblasts) and identify them in a synapse-scale TEM reconstruction of the Drosophila larval central nervous system. We find that lineages concurrently build the sensory and motor neuropils by generating sensory and motor hemilineages in a Notch-dependent manner. Neurons in a hemilineage share common synaptic targeting within the neuropil, which is further refined based on neuronal temporal identity. Connectome analysis shows that hemilineage-temporal cohorts share common connectivity. Finally, we show that proximity alone cannot explain the observed connectivity structure, suggesting hemilineage/temporal identity confers an added layer of specificity. Thus, we demonstrate that the mechanisms specifying neuronal diversity also govern circuit formation and function, and that these principles are broadly applicable throughout the nervous system.
Highlights
Tremendous progress has been made in understanding the molecular mechanisms generating neuronal diversity in both vertebrate and invertebrate model systems
To relate developmental mechanisms to circuit establishment mechanisms, we first needed to identify the developmental origin of neurons within a TEM reconstruction of the larval central nervous system (CNS) (Ohyama et al, 2015), allowing us to quantify neuronal projections, synapse localization, and connectivity
We determine the relationship between developmental mechanisms and circuit assembly mechanisms
Summary
Tremendous progress has been made in understanding the molecular mechanisms generating neuronal diversity in both vertebrate and invertebrate model systems. The first step occurs when spatial patterning genes act combinatorially to establish single, unique progenitor (neuroblast) identities (Skeath and Thor, 2003). These patterning genes endow each neuroblast with a unique spatial identity (Figure 1A, left). The second step is temporal patterning – the specification of neuronal identity based on birth-order – an evolutionarily-conserved mechanism for generating neuronal diversity (Kohwi and Doe, 2013; Rossi et al., 2017). The combination of spatial and temporal factors endows each GMC with a unique identity
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