FRI670 Osteoblast Rna Sequencing In T1d Mice Reveals Genetic Signature Of Maladaptation To Hypoxia And Compromised Collagen Synthesis

Disclosure: S. Kim: None. J. Hong: None. F. Sultana: None. E. Shelly: None. F. Korkmaz: None. J. Gimenez: None. T. Yuen: None. I. Daehn: None. J. Choi: None. M. Zaidi: None. The main feature of skeletal abnormality in type 1 diabetes (T1D) is low bone turnover with decreased osteoblastic bone format...

Descripción completa

Detalles Bibliográficos
Autores principales: Kim, Se Min, Hong, Juhyeon, Sultana, Farhath, Shelly, Eleanor, Korkmaz, Funda, Gimenez, Judit, Yuen, Tony, Daehn, Ilse, Choi, Jungmin, Zaidi, Mone
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Oxford University Press 2023
Materias:
Bone And Mineral Metabolism
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10554623/
http://dx.doi.org/10.1210/jendso/bvad114.438
_version_ 1785116456428503040
author Kim, Se Min
Hong, Juhyeon
Sultana, Farhath
Shelly, Eleanor
Korkmaz, Funda
Gimenez, Judit
Yuen, Tony
Daehn, Ilse
Choi, Jungmin
Zaidi, Mone
author_facet Kim, Se Min
Hong, Juhyeon
Sultana, Farhath
Shelly, Eleanor
Korkmaz, Funda
Gimenez, Judit
Yuen, Tony
Daehn, Ilse
Choi, Jungmin
Zaidi, Mone
author_sort Kim, Se Min
collection PubMed
description Disclosure: S. Kim: None. J. Hong: None. F. Sultana: None. E. Shelly: None. F. Korkmaz: None. J. Gimenez: None. T. Yuen: None. I. Daehn: None. J. Choi: None. M. Zaidi: None. The main feature of skeletal abnormality in type 1 diabetes (T1D) is low bone turnover with decreased osteoblastic bone formation [1, 2]. However, the mechanism of osteoblast dysfunction remains unclear. We generated T1D mice using low dose streptozotocin (STZ). T1D mice showed lower bone mass (g/cm(2)) at the femur (0.07 vs. 0.09*) and trends at lumbar spine (0.05 vs. 0.06, p=0.08) compared with control group at 8 weeks after inducing T1D. Osteoblasts were differentiated using bone marrow mesenchymal stem cells, and RNAseq was performed to analyze the transcriptome of osteoblasts. In gene set enrichment analysis, several pathways including immune, hypoxia, and glycolytic pathway were enriched. The osteogenic genes panel showed decreased Bglap and Col1a1 expression, together with lower expression of Bmp2 and Wnt5a, suggesting decreased bone formation might be related to the suppression of BMP and WNT signaling. Particularly, P4ha2, encoding prolyl 4-hydroxylase subunit alpha–2, which are responsible for posttranslational modification of collagen were downregulated in T1D osteoblasts (log(2)FC = – 1.7**). Among genes in hypoxia pathway, Egln3 encoding prolyl hydroxylase domain-containing protein 2 and Vhl encoding von Hippel-Lindau tumor suppressor, both of which stabilize HIF–α were downregulated (log(2)FC = – 2.8** and – 0.31*, respectively) likely for promoting HIF–α dependent gene expression in hypoxia. However, genes of the growth signaling pathway namely Pgf, Vegfa, and Igf1r were downregulated (log(2)FC = – 3.1**, – 0.4* and – 0.5**, respectively). Altogether, our findings suggest that maladaptation to hypoxic condition in T1D with compromised growth signaling pathway and impaired collagen synthesis might be related to osteoblasts dysfunction in T1D bone. (* p < 0.05 and ** p < 0.001) [1] Shanbhogue VV et al, JBMR. 2015[2] Rubin MR et al, JCEM. 2022 Presentation: Friday, June 16, 2023
format Online
Article
Text
id pubmed-10554623
institution National Center for Biotechnology Information
language English
publishDate 2023
publisher Oxford University Press
record_format MEDLINE/PubMed
spelling pubmed-105546232023-10-06 FRI670 Osteoblast Rna Sequencing In T1d Mice Reveals Genetic Signature Of Maladaptation To Hypoxia And Compromised Collagen Synthesis Kim, Se Min Hong, Juhyeon Sultana, Farhath Shelly, Eleanor Korkmaz, Funda Gimenez, Judit Yuen, Tony Daehn, Ilse Choi, Jungmin Zaidi, Mone J Endocr Soc Bone And Mineral Metabolism Disclosure: S. Kim: None. J. Hong: None. F. Sultana: None. E. Shelly: None. F. Korkmaz: None. J. Gimenez: None. T. Yuen: None. I. Daehn: None. J. Choi: None. M. Zaidi: None. The main feature of skeletal abnormality in type 1 diabetes (T1D) is low bone turnover with decreased osteoblastic bone formation [1, 2]. However, the mechanism of osteoblast dysfunction remains unclear. We generated T1D mice using low dose streptozotocin (STZ). T1D mice showed lower bone mass (g/cm(2)) at the femur (0.07 vs. 0.09*) and trends at lumbar spine (0.05 vs. 0.06, p=0.08) compared with control group at 8 weeks after inducing T1D. Osteoblasts were differentiated using bone marrow mesenchymal stem cells, and RNAseq was performed to analyze the transcriptome of osteoblasts. In gene set enrichment analysis, several pathways including immune, hypoxia, and glycolytic pathway were enriched. The osteogenic genes panel showed decreased Bglap and Col1a1 expression, together with lower expression of Bmp2 and Wnt5a, suggesting decreased bone formation might be related to the suppression of BMP and WNT signaling. Particularly, P4ha2, encoding prolyl 4-hydroxylase subunit alpha–2, which are responsible for posttranslational modification of collagen were downregulated in T1D osteoblasts (log(2)FC = – 1.7**). Among genes in hypoxia pathway, Egln3 encoding prolyl hydroxylase domain-containing protein 2 and Vhl encoding von Hippel-Lindau tumor suppressor, both of which stabilize HIF–α were downregulated (log(2)FC = – 2.8** and – 0.31*, respectively) likely for promoting HIF–α dependent gene expression in hypoxia. However, genes of the growth signaling pathway namely Pgf, Vegfa, and Igf1r were downregulated (log(2)FC = – 3.1**, – 0.4* and – 0.5**, respectively). Altogether, our findings suggest that maladaptation to hypoxic condition in T1D with compromised growth signaling pathway and impaired collagen synthesis might be related to osteoblasts dysfunction in T1D bone. (* p < 0.05 and ** p < 0.001) [1] Shanbhogue VV et al, JBMR. 2015[2] Rubin MR et al, JCEM. 2022 Presentation: Friday, June 16, 2023 Oxford University Press 2023-10-05 /pmc/articles/PMC10554623/ http://dx.doi.org/10.1210/jendso/bvad114.438 Text en © The Author(s) 2023. Published by Oxford University Press on behalf of the Endocrine Society. https://creativecommons.org/licenses/by-nc-nd/4.0/This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivs licence (https://creativecommons.org/licenses/by-nc-nd/4.0/), which permits non-commercial reproduction and distribution of the work, in any medium, provided the original work is not altered or transformed in any way, and that the work is properly cited. For commercial re-use, please contact journals.permissions@oup.com
spellingShingle Bone And Mineral Metabolism
Kim, Se Min
Hong, Juhyeon
Sultana, Farhath
Shelly, Eleanor
Korkmaz, Funda
Gimenez, Judit
Yuen, Tony
Daehn, Ilse
Choi, Jungmin
Zaidi, Mone
FRI670 Osteoblast Rna Sequencing In T1d Mice Reveals Genetic Signature Of Maladaptation To Hypoxia And Compromised Collagen Synthesis
title FRI670 Osteoblast Rna Sequencing In T1d Mice Reveals Genetic Signature Of Maladaptation To Hypoxia And Compromised Collagen Synthesis
title_full FRI670 Osteoblast Rna Sequencing In T1d Mice Reveals Genetic Signature Of Maladaptation To Hypoxia And Compromised Collagen Synthesis
title_fullStr FRI670 Osteoblast Rna Sequencing In T1d Mice Reveals Genetic Signature Of Maladaptation To Hypoxia And Compromised Collagen Synthesis
title_full_unstemmed FRI670 Osteoblast Rna Sequencing In T1d Mice Reveals Genetic Signature Of Maladaptation To Hypoxia And Compromised Collagen Synthesis
title_short FRI670 Osteoblast Rna Sequencing In T1d Mice Reveals Genetic Signature Of Maladaptation To Hypoxia And Compromised Collagen Synthesis
title_sort fri670 osteoblast rna sequencing in t1d mice reveals genetic signature of maladaptation to hypoxia and compromised collagen synthesis
topic Bone And Mineral Metabolism
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10554623/
http://dx.doi.org/10.1210/jendso/bvad114.438
work_keys_str_mv AT kimsemin fri670osteoblastrnasequencingint1dmicerevealsgeneticsignatureofmaladaptationtohypoxiaandcompromisedcollagensynthesis
AT hongjuhyeon fri670osteoblastrnasequencingint1dmicerevealsgeneticsignatureofmaladaptationtohypoxiaandcompromisedcollagensynthesis
AT sultanafarhath fri670osteoblastrnasequencingint1dmicerevealsgeneticsignatureofmaladaptationtohypoxiaandcompromisedcollagensynthesis
AT shellyeleanor fri670osteoblastrnasequencingint1dmicerevealsgeneticsignatureofmaladaptationtohypoxiaandcompromisedcollagensynthesis
AT korkmazfunda fri670osteoblastrnasequencingint1dmicerevealsgeneticsignatureofmaladaptationtohypoxiaandcompromisedcollagensynthesis
AT gimenezjudit fri670osteoblastrnasequencingint1dmicerevealsgeneticsignatureofmaladaptationtohypoxiaandcompromisedcollagensynthesis
AT yuentony fri670osteoblastrnasequencingint1dmicerevealsgeneticsignatureofmaladaptationtohypoxiaandcompromisedcollagensynthesis
AT daehnilse fri670osteoblastrnasequencingint1dmicerevealsgeneticsignatureofmaladaptationtohypoxiaandcompromisedcollagensynthesis
AT choijungmin fri670osteoblastrnasequencingint1dmicerevealsgeneticsignatureofmaladaptationtohypoxiaandcompromisedcollagensynthesis
AT zaidimone fri670osteoblastrnasequencingint1dmicerevealsgeneticsignatureofmaladaptationtohypoxiaandcompromisedcollagensynthesis

Ejemplares similares