Relaxin Family Peptides and Receptors in Mammalian Brain

As a foundation for regulatory and functional studies of central relaxin family peptide receptor systems, we are mapping the distribution of the different receptors in the brain of rat, mouse, and nonhuman primates, attempting to identify the nature of the receptor‐positive neurons in key circuits a...

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Bibliographic Details
Published in:Annals of the New York Academy of Sciences 2009-04, Vol.1160 (1), p.226-235
Main Authors: Gundlach, Andrew L., Ma, Sherie, Sang, Qian, Shen, Pei-Juan, Piccenna, Loretta, Sedaghat, Katayoun, Smith, Craig M., Bathgate, Ross A. D., Lawrence, Andrew J., Tregear, Geoffrey W., Wade, John D., Finkelstein, David I., Bonaventure, Pascal, Liu, Changlu, Lovenberg, Timothy W., Sutton, Steve W.
Format: Article
Language:English
Subjects:
and neuroendocrine systems
Animals
Brain - metabolism
Cerebral Cortex - metabolism
cognition
GPCR135/142
Humans
immunohistochemistry
in situ hybridization
insulin-like peptide-3
LGR7/8
limbic
Primates
radioligand binding sites
rat mouse and primate
Receptors, Peptide - genetics
Receptors, Peptide - metabolism
Receptors, Peptide - physiology
Relaxin - genetics
Relaxin - metabolism
Relaxin - physiology
relaxin and relaxin-3
RXFP1/2/3
somatosensory
somatosensory, limbic, and neuroendocrine systems
stress
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Summary:As a foundation for regulatory and functional studies of central relaxin family peptide receptor systems, we are mapping the distribution of the different receptors in the brain of rat, mouse, and nonhuman primates, attempting to identify the nature of the receptor‐positive neurons in key circuits and establish the complementary distribution of the respective ligands in these species. Here we review progress in mapping RXFP1, RXFP2, and RXFP3 (mRNAs and proteins) and their respective ligands and discuss some of the putative functions for these peptides and receptors that are being explored using receptor‐selective agonist and antagonist peptides and receptor and peptide gene deletion mouse strains. Comparative studies reveal an association of RXFP1 and RXFP2 with excitatory neurons but a differential regional or cellular distribution, in contrast to the association of RXFP3 with inhibitory neurons. These studies also reveal differences in the distribution of RXFP1 and RXFP2 in rat and mouse brain, whereas the distribution of RXFP3 is more conserved across these species. Enrichment of RXFP1/2/3 in olfactory, cortical, thalamic, limbic, hypothalamic, midbrain, and pontine circuits suggests a diverse range of modulatory actions for these receptors. For example, experimental evidence in the rat reveals that RXFP1 activation in the amygdala inhibits memory consolidation, RXFP2 activation in striatum produces sniffing behavior, and RXFP3 modulation has effects on feeding and metabolism, the activity of the septohippocampal pathway, and spatial memory. Further studies are now required to reveal additional details of these and other functions linked to relaxin family peptide receptor signaling in mammalian brain and the precise mechanisms involved.
ISSN:0077-8923
1749-6632
1930-6547
DOI:10.1111/j.1749-6632.2009.03956.x