TY - JOUR
T1 - Regulation of NGF Signaling by an Axonal Untranslated mRNA
AU - Crerar, Hamish
AU - Scott-Solomon, Emily
AU - Bodkin-Clarke, Chantal
AU - Andreassi, Catia
AU - Hazbon, Maria
AU - Logie, Emilie
AU - Cano-Jaimez, Marifé
AU - Gaspari, Marco
AU - Kuruvilla, Rejji
AU - Riccio, Antonella
N1 - Funding Information:
We thank C. Gerfen (NIH, USA) for the kind gift of the TH-Cre mice, R. Luisier (The Francis Crick Institute, London) for providing the 3′ RNA-seq track for Tp53inp2 in Figure S1B, and A. Zorzano (IRB, Barcelona) for the generous gift of the Tp53inp2 antibody. We thank Adolfo Saiardi, Alison Lloyd, Jernej Ule, Haiqing Zhao, and Samer Hattar for insightful suggestions regarding the manuscript and all members of the Riccio and Kuruvilla labs for helpful discussions. This work was supported by Wellcome Trust investigator award 103717/Z/14/Z (to A.R.), MRC senior non-clinical fellowship SNCF G0802010 (to A.R.), MRC LMCB core grant MC_U12266B, Wellcome Trust institutional strategic support fund 2014 (to C.A.), NIH R01 DK108267 and NS073751 (to R.K.), NIH training grant T32GM007231 (to C.B.-C. and E.S-S.), and MIUR, Programma Operativo Nazionale, iCARE Project grant ICARE PON03PE_0009_2 (to M.G.). H.C. E.S.-S. C.B.-C. A.R. and R.K. conceived the work. H.C. C.B.-C. E.S.-S. C.A. E.L. M.H. and M.C.-J. performed the experiments. M.G. performed the mass spectrometry analysis. A.R. and R.K. wrote the manuscript with input from all authors. The authors declare no competing interests.
Funding Information:
We thank C. Gerfen (NIH, USA) for the kind gift of the TH-Cre mice, R. Luisier (The Francis Crick Institute, London) for providing the 3′ RNA-seq track for Tp53inp2 in Figure S1 B, and A. Zorzano (IRB, Barcelona) for the generous gift of the Tp53inp2 antibody. We thank Adolfo Saiardi, Alison Lloyd, Jernej Ule, Haiqing Zhao, and Samer Hattar for insightful suggestions regarding the manuscript and all members of the Riccio and Kuruvilla labs for helpful discussions. This work was supported by Wellcome Trust investigator award 103717/Z/14/Z (to A.R.), MRC senior non-clinical fellowship SNCF G0802010 (to A.R.), MRC LMCB core grant MC_U12266B , Wellcome Trust institutional strategic support fund 2014 (to C.A.), NIH R01 DK108267 and NS073751 (to R.K.), NIH training grant T32GM007231 (to C.B.-C. and E.S-S.), and MIUR , Programma Operativo Nazionale , iCARE Project grant ICARE PON03PE_0009_2 (to M.G.).
Publisher Copyright:
© 2019 The Authors
PY - 2019/5/8
Y1 - 2019/5/8
N2 - Neurons are extraordinarily large and highly polarized cells that require rapid and efficient communication between cell bodies and axons over long distances. In peripheral neurons, transcripts are transported along axons to growth cones, where they are rapidly translated in response to extrinsic signals. While studying Tp53inp2, a transcript highly expressed and enriched in sympathetic neuron axons, we unexpectedly discovered that Tp53inp2 is not translated. Instead, the transcript supports axon growth in a coding-independent manner. Increasing evidence indicates that mRNAs may function independently of their coding capacity; for example, acting as a scaffold for functionally related proteins. The Tp53inp2 transcript interacts with the nerve growth factor (NGF) receptor TrkA, regulating TrkA endocytosis and signaling. Deletion of Tp53inp2 inhibits axon growth in vivo, and the defects are rescued by a non-translatable form of the transcript. Tp53inp2 is an atypical mRNA that regulates axon growth by enhancing NGF-TrkA signaling in a translation-independent manner. Crerar et al. report that Tp53inp2, an mRNA transcript abundantly localized in axons of sympathetic neurons, interacts with the NGF receptor TrkA. The Tp53inp2 transcript is not translated but acts in a coding-independent manner to regulate axon growth and neuronal survival in vivo.
AB - Neurons are extraordinarily large and highly polarized cells that require rapid and efficient communication between cell bodies and axons over long distances. In peripheral neurons, transcripts are transported along axons to growth cones, where they are rapidly translated in response to extrinsic signals. While studying Tp53inp2, a transcript highly expressed and enriched in sympathetic neuron axons, we unexpectedly discovered that Tp53inp2 is not translated. Instead, the transcript supports axon growth in a coding-independent manner. Increasing evidence indicates that mRNAs may function independently of their coding capacity; for example, acting as a scaffold for functionally related proteins. The Tp53inp2 transcript interacts with the nerve growth factor (NGF) receptor TrkA, regulating TrkA endocytosis and signaling. Deletion of Tp53inp2 inhibits axon growth in vivo, and the defects are rescued by a non-translatable form of the transcript. Tp53inp2 is an atypical mRNA that regulates axon growth by enhancing NGF-TrkA signaling in a translation-independent manner. Crerar et al. report that Tp53inp2, an mRNA transcript abundantly localized in axons of sympathetic neurons, interacts with the NGF receptor TrkA. The Tp53inp2 transcript is not translated but acts in a coding-independent manner to regulate axon growth and neuronal survival in vivo.
KW - 3′untranslated region
KW - axons
KW - neuronal development
KW - neurotrophin-signaling
KW - RNA localization
KW - sympathetic neurons
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U2 - 10.1016/j.neuron.2019.02.011
DO - 10.1016/j.neuron.2019.02.011
M3 - Article
C2 - 30853298
AN - SCOPUS:85065002941
SN - 0896-6273
VL - 102
SP - 553-563.e8
JO - Neuron
JF - Neuron
IS - 3
ER -