Dense and distributed neuropeptide network in the nerve net of Hydra vulgaris
Dense and distributed neuropeptide network in the nerve net of Hydra vulgaris
Neuroscience has long emphasized synaptic transmission and physical wiring as the substrate of brain function and behavior. However, an additional layer of connectivity - a "chemical connectome" formed by neuropeptide-GPCR signaling - has been increasingly recognized in animals such as C. elegans, Drosophila, and the cnidarian Nematostella vectensis. To further explore neuropeptide networks in basal metazoans, we analyzed the genome and transcriptome of the freshwater cnidarian Hydra vulgaris. Hydra offers unique experimental advantages: a simple nerve net, robust regenerative capacity, a well described behavioral repertoire, and tractable whole-body calcium imaging that allows mapping of neural and muscle activity, and cell type identity, in an integrated manner. This makes Hydra a powerful system to investigate how neuropeptidergic signaling shapes neuronal ensembles and behavior. Here, we identify 61 putative unique neuropeptides and 65 neuropeptide-specific G protein-coupled receptors (GPCRs). We show that different neuronal cell types display specific neuropeptide and receptor expression profiles, suggestive of defined communication pathways within Hydra´s decentralized nervous system. Network topology analysis of the neuropeptide network reveals a dense and distributed signaling architecture, with ectodermal neurons acting as centralized hubs for organism-wide coordination. Computational simulations using a simplified model of the nerve net demonstrate that this architecture can implement stable dynamical states. Our study reveals a comprehensive neuropeptidergic network in a non-bilaterian species, highlighting the evolutionary continuity and functional relevance of wireless chemical networks for complex behavior. Moreover, the distributed and recurrent connectivity we uncover suggests the existence in nervous systems of attractor neural networks implemented with chemical signaling, as opposed to synaptic wiring.
e1014037
De La Cruz Rothenfusser, Johanna
54375ec5-097c-46be-8ccf-1bb058ba4192
Yáñez-Guerra, Luis Alfonso
cbca947b-bbf0-4b91-96b0-4a126e3b94b6
Teufel, Felix
a8c654f1-17d9-4e49-a809-5a1f2dff19a5
Yuste, Rafael
9d1dabe2-deec-4634-89d3-2682bbd19dd2
20 March 2026
De La Cruz Rothenfusser, Johanna
54375ec5-097c-46be-8ccf-1bb058ba4192
Yáñez-Guerra, Luis Alfonso
cbca947b-bbf0-4b91-96b0-4a126e3b94b6
Teufel, Felix
a8c654f1-17d9-4e49-a809-5a1f2dff19a5
Yuste, Rafael
9d1dabe2-deec-4634-89d3-2682bbd19dd2
De La Cruz Rothenfusser, Johanna, Yáñez-Guerra, Luis Alfonso, Teufel, Felix and Yuste, Rafael
(2026)
Dense and distributed neuropeptide network in the nerve net of Hydra vulgaris.
PLoS Computational Biology, 22 (3), .
(doi:10.1371/journal.pcbi.1014037).
Abstract
Neuroscience has long emphasized synaptic transmission and physical wiring as the substrate of brain function and behavior. However, an additional layer of connectivity - a "chemical connectome" formed by neuropeptide-GPCR signaling - has been increasingly recognized in animals such as C. elegans, Drosophila, and the cnidarian Nematostella vectensis. To further explore neuropeptide networks in basal metazoans, we analyzed the genome and transcriptome of the freshwater cnidarian Hydra vulgaris. Hydra offers unique experimental advantages: a simple nerve net, robust regenerative capacity, a well described behavioral repertoire, and tractable whole-body calcium imaging that allows mapping of neural and muscle activity, and cell type identity, in an integrated manner. This makes Hydra a powerful system to investigate how neuropeptidergic signaling shapes neuronal ensembles and behavior. Here, we identify 61 putative unique neuropeptides and 65 neuropeptide-specific G protein-coupled receptors (GPCRs). We show that different neuronal cell types display specific neuropeptide and receptor expression profiles, suggestive of defined communication pathways within Hydra´s decentralized nervous system. Network topology analysis of the neuropeptide network reveals a dense and distributed signaling architecture, with ectodermal neurons acting as centralized hubs for organism-wide coordination. Computational simulations using a simplified model of the nerve net demonstrate that this architecture can implement stable dynamical states. Our study reveals a comprehensive neuropeptidergic network in a non-bilaterian species, highlighting the evolutionary continuity and functional relevance of wireless chemical networks for complex behavior. Moreover, the distributed and recurrent connectivity we uncover suggests the existence in nervous systems of attractor neural networks implemented with chemical signaling, as opposed to synaptic wiring.
Text
journal.pcbi.1014037
- Version of Record
More information
Accepted/In Press date: 17 February 2026
Published date: 20 March 2026
Additional Information:
Copyright: © 2026 De La Cruz Rothenfusser et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Identifiers
Local EPrints ID: 511633
URI: http://eprints.soton.ac.uk/id/eprint/511633
ISSN: 1553-734X
PURE UUID: 59e5f558-bcf0-4645-a4fa-85300d20dc37
Catalogue record
Date deposited: 26 May 2026 16:38
Last modified: 27 May 2026 02:08
Export record
Altmetrics
Contributors
Author:
Johanna De La Cruz Rothenfusser
Author:
Luis Alfonso Yáñez-Guerra
Author:
Felix Teufel
Author:
Rafael Yuste
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics