Cargando…

Identification of the minimum region of flatfish myostatin propeptide (Pep45-65) for myostatin inhibition and its potential to enhance muscle growth and performance in animals

Myostatin (MSTN) negatively regulates skeletal muscle growth, and its activity is inhibited by the binding of MSTN propeptide (MSTNpro), the N-terminal domain of proMSTN that is proteolytically cleaved from the proMSTN. Partial sequences from the N-terminal side of MSTNpro have shown to be sufficien...

Descripción completa

Detalles Bibliográficos
Autores principales: Kim, Jeong Hwan, Kim, Jeong Han, Sutikno, Lisa Andriani, Lee, Sang Beum, Jin, Deuk-Hee, Hong, Yong-Ki, Kim, Yong Soo, Jin, Hyung-Joo
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2019
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6472743/
https://www.ncbi.nlm.nih.gov/pubmed/30998775
http://dx.doi.org/10.1371/journal.pone.0215298
_version_ 1783412300856688640
author Kim, Jeong Hwan
Kim, Jeong Han
Sutikno, Lisa Andriani
Lee, Sang Beum
Jin, Deuk-Hee
Hong, Yong-Ki
Kim, Yong Soo
Jin, Hyung-Joo
author_facet Kim, Jeong Hwan
Kim, Jeong Han
Sutikno, Lisa Andriani
Lee, Sang Beum
Jin, Deuk-Hee
Hong, Yong-Ki
Kim, Yong Soo
Jin, Hyung-Joo
author_sort Kim, Jeong Hwan
collection PubMed
description Myostatin (MSTN) negatively regulates skeletal muscle growth, and its activity is inhibited by the binding of MSTN propeptide (MSTNpro), the N-terminal domain of proMSTN that is proteolytically cleaved from the proMSTN. Partial sequences from the N-terminal side of MSTNpro have shown to be sufficient to inhibit MSTN activity. In this study, to determine the minimum size of flatfish MSTNpro for MSTN inhibition, various truncated forms of flatfish MSTNpro with N-terminal maltose binding protein (MBP) fusion were expressed in E. coli and purified. MSTNpro regions consisting of residues 45–68, -69, and -70 with MBP fusion suppressed MSTN activity with a potency comparable to that of full-sequence flatfish MSTNpro in a pGL3-(CAGA)(12)-luciferase reporter assay. Even though the MSTN-inhibitory potency was about 1,000-fold lower, the flatfish MSTNpro region containing residues 45–65 (MBP-Pro45-65) showed MSTN-inhibitory capacity but not the MBP-Pro45-64, indicating that the region 45–65 is the minimum domain required for MSTN binding and suppression of its activity. To examine the in vivo effect of MBP-fused, truncated flatfish MSTNpro, MBP-Pro45-70-His6 (20 mg/kg body wt) was subcutaneously injected 5 times for 14 days in mice. Body wt gain and bone mass were not affected by the administration. Grip strength and swimming time were significantly enhanced at 7 d after the administration. At 14 d, the effect on grip strength disappeared, and the extent of the effect on swimming time significantly diminished. The presence of antibody against MBP-Pro45-70-His6 was observed at both 7 and 14 d after the administration with the titer value at 14 d being much greater than that at 7 d, suggesting that antibodies against MBP-Pro45-70-His6 neutralized the MSTN-inhibitory effect of MBP-Pro45-70-His6. We, thus, examined the MSTN-inhibitory capacity and in vivo effect of flatfish MSTNpro region 45–65 peptide (Pep45-65-NH2), which was predicted to have no immunogenicity in silico analysis. Pep45-65-NH2 suppressed MSTN activity with a potency similar to that of MBP-Pro45-65 but did not suppress GDF11, or activin A. Pep45-65-NH2 blocked MSTN-induced Smad2 phosphorylation in HepG2 cells. The administration of Pep45-65 (20 mg/kg body wt, 5 times for 2 weeks) increased the body wt gain with a greater gain at 14 d than at 7 d and muscle wt. Grip strength and swimming time were also significantly enhanced by the administration. Antibody titer against Pep45-65 was not detected. In conclusion, current results indicate that MSTN-inhibitory proteins with heterologous fusion partner may not be effective in suppressing MSTN activity in vivo due to an immune response against the proteins. Current results also show that the region of flatfish MSTNpro consisting of 45–65 (Pep45-65) can suppress mouse MSTN activity and increase muscle mass and function without invoking an immune response, implying that Pep45-65 would be a potential agent to enhance skeletal muscle growth and function in animals or to treat muscle atrophy caused by various clinical conditions.
format Online
Article
Text
id pubmed-6472743
institution National Center for Biotechnology Information
language English
publishDate 2019
publisher Public Library of Science
record_format MEDLINE/PubMed
spelling pubmed-64727432019-05-03 Identification of the minimum region of flatfish myostatin propeptide (Pep45-65) for myostatin inhibition and its potential to enhance muscle growth and performance in animals Kim, Jeong Hwan Kim, Jeong Han Sutikno, Lisa Andriani Lee, Sang Beum Jin, Deuk-Hee Hong, Yong-Ki Kim, Yong Soo Jin, Hyung-Joo PLoS One Research Article Myostatin (MSTN) negatively regulates skeletal muscle growth, and its activity is inhibited by the binding of MSTN propeptide (MSTNpro), the N-terminal domain of proMSTN that is proteolytically cleaved from the proMSTN. Partial sequences from the N-terminal side of MSTNpro have shown to be sufficient to inhibit MSTN activity. In this study, to determine the minimum size of flatfish MSTNpro for MSTN inhibition, various truncated forms of flatfish MSTNpro with N-terminal maltose binding protein (MBP) fusion were expressed in E. coli and purified. MSTNpro regions consisting of residues 45–68, -69, and -70 with MBP fusion suppressed MSTN activity with a potency comparable to that of full-sequence flatfish MSTNpro in a pGL3-(CAGA)(12)-luciferase reporter assay. Even though the MSTN-inhibitory potency was about 1,000-fold lower, the flatfish MSTNpro region containing residues 45–65 (MBP-Pro45-65) showed MSTN-inhibitory capacity but not the MBP-Pro45-64, indicating that the region 45–65 is the minimum domain required for MSTN binding and suppression of its activity. To examine the in vivo effect of MBP-fused, truncated flatfish MSTNpro, MBP-Pro45-70-His6 (20 mg/kg body wt) was subcutaneously injected 5 times for 14 days in mice. Body wt gain and bone mass were not affected by the administration. Grip strength and swimming time were significantly enhanced at 7 d after the administration. At 14 d, the effect on grip strength disappeared, and the extent of the effect on swimming time significantly diminished. The presence of antibody against MBP-Pro45-70-His6 was observed at both 7 and 14 d after the administration with the titer value at 14 d being much greater than that at 7 d, suggesting that antibodies against MBP-Pro45-70-His6 neutralized the MSTN-inhibitory effect of MBP-Pro45-70-His6. We, thus, examined the MSTN-inhibitory capacity and in vivo effect of flatfish MSTNpro region 45–65 peptide (Pep45-65-NH2), which was predicted to have no immunogenicity in silico analysis. Pep45-65-NH2 suppressed MSTN activity with a potency similar to that of MBP-Pro45-65 but did not suppress GDF11, or activin A. Pep45-65-NH2 blocked MSTN-induced Smad2 phosphorylation in HepG2 cells. The administration of Pep45-65 (20 mg/kg body wt, 5 times for 2 weeks) increased the body wt gain with a greater gain at 14 d than at 7 d and muscle wt. Grip strength and swimming time were also significantly enhanced by the administration. Antibody titer against Pep45-65 was not detected. In conclusion, current results indicate that MSTN-inhibitory proteins with heterologous fusion partner may not be effective in suppressing MSTN activity in vivo due to an immune response against the proteins. Current results also show that the region of flatfish MSTNpro consisting of 45–65 (Pep45-65) can suppress mouse MSTN activity and increase muscle mass and function without invoking an immune response, implying that Pep45-65 would be a potential agent to enhance skeletal muscle growth and function in animals or to treat muscle atrophy caused by various clinical conditions. Public Library of Science 2019-04-18 /pmc/articles/PMC6472743/ /pubmed/30998775 http://dx.doi.org/10.1371/journal.pone.0215298 Text en © 2019 Kim et al http://creativecommons.org/licenses/by/4.0/ This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/) , which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
spellingShingle Research Article
Kim, Jeong Hwan
Kim, Jeong Han
Sutikno, Lisa Andriani
Lee, Sang Beum
Jin, Deuk-Hee
Hong, Yong-Ki
Kim, Yong Soo
Jin, Hyung-Joo
Identification of the minimum region of flatfish myostatin propeptide (Pep45-65) for myostatin inhibition and its potential to enhance muscle growth and performance in animals
title Identification of the minimum region of flatfish myostatin propeptide (Pep45-65) for myostatin inhibition and its potential to enhance muscle growth and performance in animals
title_full Identification of the minimum region of flatfish myostatin propeptide (Pep45-65) for myostatin inhibition and its potential to enhance muscle growth and performance in animals
title_fullStr Identification of the minimum region of flatfish myostatin propeptide (Pep45-65) for myostatin inhibition and its potential to enhance muscle growth and performance in animals
title_full_unstemmed Identification of the minimum region of flatfish myostatin propeptide (Pep45-65) for myostatin inhibition and its potential to enhance muscle growth and performance in animals
title_short Identification of the minimum region of flatfish myostatin propeptide (Pep45-65) for myostatin inhibition and its potential to enhance muscle growth and performance in animals
title_sort identification of the minimum region of flatfish myostatin propeptide (pep45-65) for myostatin inhibition and its potential to enhance muscle growth and performance in animals
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6472743/
https://www.ncbi.nlm.nih.gov/pubmed/30998775
http://dx.doi.org/10.1371/journal.pone.0215298
work_keys_str_mv AT kimjeonghwan identificationoftheminimumregionofflatfishmyostatinpropeptidepep4565formyostatininhibitionanditspotentialtoenhancemusclegrowthandperformanceinanimals
AT kimjeonghan identificationoftheminimumregionofflatfishmyostatinpropeptidepep4565formyostatininhibitionanditspotentialtoenhancemusclegrowthandperformanceinanimals
AT sutiknolisaandriani identificationoftheminimumregionofflatfishmyostatinpropeptidepep4565formyostatininhibitionanditspotentialtoenhancemusclegrowthandperformanceinanimals
AT leesangbeum identificationoftheminimumregionofflatfishmyostatinpropeptidepep4565formyostatininhibitionanditspotentialtoenhancemusclegrowthandperformanceinanimals
AT jindeukhee identificationoftheminimumregionofflatfishmyostatinpropeptidepep4565formyostatininhibitionanditspotentialtoenhancemusclegrowthandperformanceinanimals
AT hongyongki identificationoftheminimumregionofflatfishmyostatinpropeptidepep4565formyostatininhibitionanditspotentialtoenhancemusclegrowthandperformanceinanimals
AT kimyongsoo identificationoftheminimumregionofflatfishmyostatinpropeptidepep4565formyostatininhibitionanditspotentialtoenhancemusclegrowthandperformanceinanimals
AT jinhyungjoo identificationoftheminimumregionofflatfishmyostatinpropeptidepep4565formyostatininhibitionanditspotentialtoenhancemusclegrowthandperformanceinanimals