Oxytocin/Osteocalcin/IL-6 and NGF/BDNF mRNA Levels in Response to Cold Stress Challenge in Mice: Possible Oxytonic Brain-Bone-Muscle-Interaction.

Claudia Camerino,Marcello Diego Lograno,Maria Rosaria Carratù,Adriano Fonzino,Elena Conte,Domenico Tricarico

doi:10.3389/fphys.2019.01437

Claudia Camerino, Marcello Diego Lograno + Show 4 more

Open Access

https://doi.org/10.3389/fphys.2019.01437

Copy DOI

Abstract

Oxytocin (Oxt), osteocalcin (Ost), and NGF/BDNF have a role in bone homeostasis, reproduction, and cognition. Oxt/Ost is required for muscle repair. We investigated gene response of muscle and the inter-organ communication following cold stress (CS). The mRNA quantity of Ngf, Ost, Oxt, Bdnf, p75ntr, Ntrk1, Gprc6a, Oxtr, Ntrk2, UCP1, and Il-6 genes in bone, brain, soleus (SOL), and tibialis anterior (TA) muscles from adult mice following CS were investigated. The myosin heavy-chain Mhc2b, Mhc1, Mhc2x, and Mhc2a gene expression were investigated. Mice were maintained at T = 23°C or 4°C for 6 h and 5-days (5d). CS mice did not show signs of muscle degeneration. An upregulation of Ucp1 and Ngf genes by 2 and 1.5 folds, respectively, in TA after 6 h CS and Ntrk1 by 4 and 22 folds in SOL muscle after 6 h and 5d CS, respectively, was observed; while after 6 h CS p75Ntr was downregulated in either muscle. Bdnf was unaffected, while after 5d CS Ntrk2 was upregulated in TA. Ost was downregulated in SOL by 0.9-folds at 5d. Following 5d CS, Oxtr and Il-6 genes were upregulated, respectively, by 1 and 1.5 folds in SOL. A downregulation of Mhc2b, respectively, by 0.96 and 0.88-folds after 6 h and 5d CS in SOL and Mhc2a was also downregulated by 0.88-fold after 5d CS in TA. Mhc1 and Mhc2x were not affected. Changes in the expression levels of genes in TA and SOL muscles, bone, and brain following CS were regulated by IL6 and Oxt. CS potentiates the slow-twitch phenotype of SOL which is in line with the metabolic need of this muscle, and the potentiation of the slow-twitch phenotype in TA. Oxt and IL6 coordinate a phenotype-dependent tonic effect of slow-twitch muscle and Oxt regulates the inter-organ interaction between brain and SOL muscle. Muscle tropism is maintained by NGF signaling following CS.

Highlights

Reviewed by: Hongshuai Li, University of Pittsburgh, United States Weiping Qin, Icahn School of Medicine at Mount Sinai, United States
We show that skeletal muscle properties are influenced by genes that are not classically associated with it and that skeletal muscle cross-talk with bone and brain allows adaptation of these tissues during thermogenic challenge (Monod and Jacob, 1961; Abboud, 2010)
In slow-twitching muscle, the marked up-regulation of the neurothrophin receptor gene Ntrk1 may lead to a sustained NGF signaling in response to circulating NGF released from bone and fast-twitching muscle during cold stress (CS) challenges; thereby skeletal muscle may be considered as a recipient of hormonal inputs released from bone under CS (Camerino, 2009a)

Summary

Introduction

Reviewed by: Hongshuai Li, University of Pittsburgh, United States Weiping Qin, Icahn School of Medicine at Mount Sinai, United States. We investigated gene response of muscle and the inter-organ communication following cold stress (CS). The mRNA quantity of Ngf, Ost, Oxt, Bdnf, p75ntr, Ntrk, Gprc6a, Oxtr, Ntrk, UCP1, and Il-6 genes in bone, brain, soleus (SOL), and tibialis anterior (TA) muscles from adult mice following CS were investigated. The neurotrophines NGF/BDNF and osteocalcin (Ost) are implied in regulating the physiological adaptation of the organism to challenging stimuli (Karsenty, 2012a; Hristova, 2013; Elabd et al, 2014; Mera et al, 2016a; Camerino et al, 2018). The expression levels of osteocalcin, NGF/BDNF, and their relative receptors Gprc6a, NGFR, Cold Stress Challenge and Skeletal Muscle. Osteocalcin is shown to be necessary for hippocampal memory and to prevent anxiety

Methods

Results

Conclusion