A transcriptional signature of hub connectivity in the mouse connectome
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Edited by Danielle S. Bassett, University of Pennsylvania, Philadelphia, PA, and accepted by the Editorial Board December 11, 2015 (received for review July 11, 2015)
Significance
Some brain regions are highly connected with other areas, designating them as network hubs. These hubs are also heavily interconnected with each other, forming a dense core that integrates information across different neural systems. Here, we show that the functionally important projections linking hub areas of the mouse brain have a distinct genetic signature that is characterized by the tightly coupled expression of genes regulating the synthesis and metabolism of ATP, the primary energy source for neural activity. Our findings establish a direct link between molecular function and the large-scale organization of neuronal connectivity and suggest that coordinated gene expression between hub areas is closely related to the metabolic demands of these highly active and functionally important regions.
Abstract
Connectivity is not distributed evenly throughout the brain. Instead, it is concentrated on a small number of highly connected neural elements that act as network hubs. Across different species and measurement scales, these hubs show dense interconnectivity, forming a core or “rich club” that integrates information across anatomically distributed neural systems. Here, we show that projections between connectivity hubs of the mouse brain are both central (i.e., they play an important role in neural communication) and costly (i.e., they extend over long anatomical distances) aspects of network organization that carry a distinctive genetic signature. Analyzing the neuronal connectivity of 213 brain regions and the transcriptional coupling, across 17,642 genes, between each pair of regions, we find that coupling is highest for pairs of connected hubs, intermediate for links between hubs and nonhubs, and lowest for connected pairs of nonhubs. The high transcriptional coupling associated with hub connectivity is driven by genes regulating the oxidative synthesis and metabolism of ATP—the primary energetic currency of neuronal communication. This genetic signature contrasts that identified for neuronal connectivity in general, which is driven by genes regulating neuronal, synaptic, and axonal structure and function. Our findings establish a direct link between molecular function and the large-scale topology of neuronal connectivity, showing that brain hubs display a tight coordination of gene expression, often over long anatomical distances, that is intimately related to the metabolic requirements of these highly active network elements.
Footnotes
- ↵1To whom correspondence should be addressed. Email: ben.fulcher@monash.edu.
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Author contributions: B.D.F. and A.F. designed research; B.D.F. performed research; B.D.F. analyzed data; and B.D.F. and A.F. wrote the paper.
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The authors declare no conflict of interest.
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This article is a PNAS Direct Submission. D.S.B. is a guest editor invited by the Editorial Board.
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This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.1073/pnas.1513302113/-/DCSupplemental.
Freely available online through the PNAS open access option.
