Barrett, Alec, McWhirter, Rebecca, Vidal, Berta, Tavazoie, Saeed, Hobert, Oliver, Weinreb, Alexis, Miller, David, Xu, Chuan, Taylor, Seth, Paninski, Liam, Yemini, Eviatar, Sestan, Nenad, Basavaraju, Manasa, Litwin-Kumar, Ashok, Cros, Cyril, Reilly, Molly, Santpere, Gabriel, Poff, Abigail, Glenwinkel, Lori, Abrams, Alexander, Hammarlund, Marc, Rafi, Ibnul, Varol, Erdem, Oikonomou, Panos, Cook, Steven
[
International Worm Meeting,
2021]
There is strong prior evidence for genetic encoding of synaptogenesis, axon guidance, and synaptic pruning in neural circuits. Despite these foundational observations, the transcriptional codes that drive neural connectivity have not been elucidated. The C. elegans nervous system is a particularly useful model for studying the interplay between genetics and connectivity since its wiring diagram is highly stereotyped and uniquely well-defined by electron microscopy. Furthermore, recent evidence in C. elegans has suggested that a unique combination of transcription factors specifies each of the 118 neuron classes[1]. Motivated by evidence for the stereotypy of neural circuits and for the genetic encoding of neural identity, we introduce a novel statistical technique, termed Network Differential Gene expression analysis (nDGE), to test the hypotheses that neuron-specific gene expression dictates connectivity. Specifically, we test the hypothesis that pre-synaptic neural identity is defined by a "key" gene combination whose post-synaptic targets are determined by a "lock" gene combination. For our approach, we utilize neuron-specific gene expression profiles from the CeNGEN project[2] to investigate transcriptional codes for connectivity in the nerve ring[3]. We hypothesize that the expression of specific cell adhesion molecules (CAM) among synaptically-connected neurons drives synaptic maintenance in the mature nervous system. We posit that CAMs mediating synaptic stability would be more highly expressed in synaptically-connected neurons than in adjacent neurons with membrane contacts but no synapses. Thus, for each neuron, we compare the expression of all possible combinations of pairs of CAMs in the neuron and its synaptic partners relative to the neuron and its non-synaptic adjacent neurons. Two independent comparisons are generated, one for presynaptic neurons and a second result for postsynaptic neurons. Our nDGE analysis reveals that specific combinations of CAMs are correlated with connectivity in different subsets of neurons and thus provides a uniquely comprehensive road map for investigating the genetic blueprint for the nerve ring wiring diagram. Open source software of Network Differential Gene Expression (nDGE) is publicly available at https://github.com/cengenproject/connectivity_analysis along with a vignette showcasing the CAM results. 1. Reilly, M. B., Cros, C., Varol, E., Yemini, E., & Hobert, O. (2020). Unique homeobox codes delineate all the neuron classes of C. elegans. Nature, 584(7822), 595-601. 2. Taylor, S. R., Santpere, G., Weinreb, A., Barrett, A., Reilly, M. B., Xu, C. Varol, E., ... & Miller, D. M. (2020). Molecular topography of an entire nervous system. bioRxiv. 3. Cook, S. J.,... & Emmons, S. W. (2019). Whole-animal connectomes of both Caenorhabditis elegans sexes. Nature, 571(7763), 63-71.