Evolution of neurohormone function revealed by actions of kisspeptin-type peptides in an echinoderm
Evolution of neurohormone function revealed by actions of kisspeptin-type peptides in an echinoderm
Background: The neurohormone kisspeptin regulates reproductive maturation and function in mammals by stimulating hypothalamic production and release of gonadotropin-releasing hormone. However, little is known about kisspeptin-type neuropeptide function in invertebrates and the evolution of kisspeptin signalling as a regulator of physiological processes. Here, we address these issues in a deuterostome invertebrate — the starfish Asterias rubens (phylum Echinodermata). Results: Unlike mammals that have one kisspeptin precursor protein, in A. rubens, two precursor proteins (ArKPP1, ArKPP2) give rise to four kisspeptin-type neuropeptides (ArKP1.1, ArKP1.2, ArKP2.1, ArKP2.2). Use of mRNA in situ hybridisation and immunohistochemistry revealed widespread but different patterns of expression of KP1-type and KP2-type neuropeptides in the central nervous system, locomotory organs, sensory organs, reproductive system, and digestive system of A. rubens. In vitro experiments revealed that KP1-type and KP2-type neuropeptides have opposing myoinhibitory and myoexcitatory effects, respectively, on starfish gonad and stomach preparations. When injected in vivo, both KP1-type and KP2-type neuropeptides trigger stomach eversion and ArKP1.2 affects righting behaviour. Conclusions: This study has revealed that kisspeptin-type neuropeptides are evolutionarily ancient and pleiotropic regulators of processes that extend beyond reproductive physiology. Furthermore, the excitatory actions of ArKP2.2 in A. rubens are consistent with stimulatory effects of kisspeptins in vertebrates; accordingly, ArKP2.2 acts as a ligand for a receptor (ArKPR3) that is closely related to vertebrate kisspeptin receptors. On the other hand, phylogenetic analysis of receptors for ArKP1.1 and ArKP1.2 indicates that inhibitory kisspeptin signalling either evolved uniquely in Ambulacraria (echinoderms, hemichordates) or originated in Urbilateria but was lost in chordates.
Asterias rubens, Echinodermata, Evolution, Kisspeptin, Neurohormone, Neuropeptide, Receptor, Reproduction
Islam, Tabinda
3fdf14c3-a951-4e8e-93ec-cea5852293a1
Yañez-Guerra, Luis A.
cbca947b-bbf0-4b91-96b0-4a126e3b94b6
Semmens, Dean C.
51d84b62-2928-425a-878e-2841268e43e2
Beskeen, Riley T.
8e7f08b2-8ef0-4840-ae2b-684eb198791e
Egertová, Michaela
9a68b847-d995-40b0-8d94-3918037aed83
Elphick, Maurice R.
b4c8b4f9-bb5c-4a0a-bc9d-e941857d4800
18 February 2026
Islam, Tabinda
3fdf14c3-a951-4e8e-93ec-cea5852293a1
Yañez-Guerra, Luis A.
cbca947b-bbf0-4b91-96b0-4a126e3b94b6
Semmens, Dean C.
51d84b62-2928-425a-878e-2841268e43e2
Beskeen, Riley T.
8e7f08b2-8ef0-4840-ae2b-684eb198791e
Egertová, Michaela
9a68b847-d995-40b0-8d94-3918037aed83
Elphick, Maurice R.
b4c8b4f9-bb5c-4a0a-bc9d-e941857d4800
Islam, Tabinda, Yañez-Guerra, Luis A., Semmens, Dean C., Beskeen, Riley T., Egertová, Michaela and Elphick, Maurice R.
(2026)
Evolution of neurohormone function revealed by actions of kisspeptin-type peptides in an echinoderm.
BMC Biology, 24 (1), [74].
(doi:10.1186/s12915-026-02555-1).
Abstract
Background: The neurohormone kisspeptin regulates reproductive maturation and function in mammals by stimulating hypothalamic production and release of gonadotropin-releasing hormone. However, little is known about kisspeptin-type neuropeptide function in invertebrates and the evolution of kisspeptin signalling as a regulator of physiological processes. Here, we address these issues in a deuterostome invertebrate — the starfish Asterias rubens (phylum Echinodermata). Results: Unlike mammals that have one kisspeptin precursor protein, in A. rubens, two precursor proteins (ArKPP1, ArKPP2) give rise to four kisspeptin-type neuropeptides (ArKP1.1, ArKP1.2, ArKP2.1, ArKP2.2). Use of mRNA in situ hybridisation and immunohistochemistry revealed widespread but different patterns of expression of KP1-type and KP2-type neuropeptides in the central nervous system, locomotory organs, sensory organs, reproductive system, and digestive system of A. rubens. In vitro experiments revealed that KP1-type and KP2-type neuropeptides have opposing myoinhibitory and myoexcitatory effects, respectively, on starfish gonad and stomach preparations. When injected in vivo, both KP1-type and KP2-type neuropeptides trigger stomach eversion and ArKP1.2 affects righting behaviour. Conclusions: This study has revealed that kisspeptin-type neuropeptides are evolutionarily ancient and pleiotropic regulators of processes that extend beyond reproductive physiology. Furthermore, the excitatory actions of ArKP2.2 in A. rubens are consistent with stimulatory effects of kisspeptins in vertebrates; accordingly, ArKP2.2 acts as a ligand for a receptor (ArKPR3) that is closely related to vertebrate kisspeptin receptors. On the other hand, phylogenetic analysis of receptors for ArKP1.1 and ArKP1.2 indicates that inhibitory kisspeptin signalling either evolved uniquely in Ambulacraria (echinoderms, hemichordates) or originated in Urbilateria but was lost in chordates.
This record has no associated files available for download.
More information
Accepted/In Press date: 11 February 2026
Published date: 18 February 2026
Additional Information:
© 2026. The Author(s).
Keywords:
Asterias rubens, Echinodermata, Evolution, Kisspeptin, Neurohormone, Neuropeptide, Receptor, Reproduction
Identifiers
Local EPrints ID: 510784
URI: http://eprints.soton.ac.uk/id/eprint/510784
ISSN: 1741-7007
PURE UUID: 8898570b-7bf9-45fa-83e8-0257852f72f3
Catalogue record
Date deposited: 21 Apr 2026 17:00
Last modified: 22 Apr 2026 02:10
Export record
Altmetrics
Contributors
Author:
Tabinda Islam
Author:
Luis A. Yañez-Guerra
Author:
Dean C. Semmens
Author:
Riley T. Beskeen
Author:
Michaela Egertová
Author:
Maurice R. Elphick
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