scholarly journals Uncovering the genetic blueprint of the C. elegans nervous system

2020 ◽  
Vol 117 (52) ◽  
pp. 33570-33577
Author(s):  
István A. Kovács ◽  
Dániel L. Barabási ◽  
Albert-László Barabási
Keyword(s):  
Gene Expression ◽  
Expression Profiling ◽  
Expression Patterns ◽  
Computational Framework ◽  
Computational Tools ◽  
C Elegans ◽  
Junction Formation ◽  
Cell Gene Expression ◽  
Genetic Mechanisms ◽  
Cell Gene

Despite rapid advances in connectome mapping and neuronal genetics, we lack theoretical and computational tools to unveil, in an experimentally testable fashion, the genetic mechanisms that govern neuronal wiring. Here we introduce a computational framework to link the adjacency matrix of a connectome to the expression patterns of its neurons, helping us uncover a set of genetic rules that govern the interactions between neurons in contact. The method incorporates the biological realities of the system, accounting for noise from data collection limitations, as well as spatial restrictions. The resulting methodology allows us to infer a network of 19 innexin interactions that govern the formation of gap junctions in Caenorhabditis elegans, five of which are already supported by experimental data. As advances in single-cell gene expression profiling increase the accuracy and the coverage of the data, the developed framework will allow researchers to systematically infer experimentally testable connection rules, offering mechanistic predictions for synapse and gap junction formation.

scholarly journals Uncovering the genetic blueprint of the C. elegans nervous system

2020 ◽  
Author(s):  
István A. Kovács ◽  
Dániel L. Barabási ◽  
Albert-László Barabási
Keyword(s):  
Gene Expression ◽  
Expression Profiling ◽  
Expression Patterns ◽  
Computational Framework ◽  
Computational Tools ◽  
C Elegans ◽  
Junction Formation ◽  
Cell Gene Expression ◽  
Genetic Mechanisms ◽  
Cell Gene

Despite rapid advances in connectome mapping and neuronal genetics, we lack theoretical and computational tools to unveil, in an experimentally testable fashion, the genetic mechanisms that govern neuronal wiring. Here we introduce a computational framework to link the adjacency matrix of a connectome to the expression patterns of its neurons, helping us uncover a set of genetic rules that govern the interactions between adjacent neurons. The method incorporates the biological realities of the system, accounting for noise from data collection limitations, as well as spatial restrictions. The resulting methodology allows us to infer a network of 19 innexin interactions that govern the formation of gap junctions in C. elegans, five of which are already supported by experimental data. As advances in single-cell gene expression profiling increase the accuracy and the coverage of the data, the developed framework will allow researchers to systematically infer experimentally testable connection rules, offering mechanistic predictions for synapse and gap junction formation.

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