生物工程化人源化胰岛素分泌新器官中胰腺转录因子的分子动力学

Molecular dynamics of pancreatic transcription factors in bioengineered humanized insulin producing neoorgan.

机构信息

Central Laboratory for Stem Cell Research & Translational Medicine, Centre for Liver Research and Diagnostics, Deccan College of Medical Sciences, Kanchanbagh, Hyderabad 500058, Telangana, India; Dr. Habeebullah Life Sciences, Attapur, Hyderabad 500030, Telangana, India.

出版信息

Gene. 2018 Oct 30;675:165-175. doi: 10.1016/j.gene.2018.07.006. Epub 2018 Jul 3.

DOI:10.1016/j.gene.2018.07.006

PMID:30180963

Abstract

BACKGROUND

The present study has been aimed to identify molecular dynamics of pancreatic transcription factors (pTFs) during events of directed trans-differentiation of human hepatic progenitor cells (hHPCs) into insulin producing cells (InPCs) within bioengineered humanized neoorgan. The study demonstrates applicability of acellularized whole splenic scaffold (ASOS) to generate insulin producing humanized transplantable neoorgan through activation of pancreatic transcription factors.

METHODS

An efficient acellularization process was developed for xenogeneic rat spleen using change in different gradients of reagents perfusion through splenic artery for varying time points. The acellularized xenogeneic spleen scaffold was characterized thoroughly for preservation of extra-cellular matrix and retention of organ specific vasculature and mechanical properties. Further scaffolds were sterilized and repopulated with hHPCs which were triggered using a stage wise induction with growth factors and hyperglycemic challenge for trans-differentiation into InPCs. Dynamics of pTFs alone or simultaneously during induction process was identified using gene expression analysis and immunological staining.

RESULTS

The cells within the engineered neoorgan respond to growth factors and extrinsic hyperglycemic challenge and generate large number of InPCs under controlled dynamic regulation of pTFs. Highly controlled regulation of pTFs generates higher percentage of Nkx-6.1+/C-peptide+ cells within the engineered splenic scaffolds. Generation of high percentage of insulin and C-peptide positive cells in three-dimensional organ architecture responded better to hyperglycemic stimuli and produced higher quantity of insulin than 2D-culture system.

CONCLUSION

The present study provides a novel platform for designing effective regenerative strategies using whole organ scaffolds to control hyperglycemia under tight regulation of pTFs using humanized neoorgan system.

摘要

背景

本研究旨在鉴定人肝祖细胞（hHPC）在生物工程化的人源化新器官内定向转分化为胰岛素产生细胞（InPC）过程中胰腺转录因子（pTFs）的分子动力学。该研究证明了使用去细胞化的整个脾支架（ASOS）通过激活胰腺转录因子产生胰岛素产生的人源化可移植新器官的适用性。

方法

使用不同浓度的试剂通过脾动脉以不同的时间梯度进行灌注，开发了一种有效的异种大鼠脾去细胞化方法。对去细胞化的异种脾支架进行了彻底的特征描述，以保留细胞外基质并保留器官特异性脉管系统和机械性能。进一步对支架进行了消毒，并重新填充 hHPC，并用生长因子进行分阶段诱导，并进行高血糖挑战，以将其转分化为 InPC。使用基因表达分析和免疫染色鉴定 pTFs 在诱导过程中单独或同时的动力学。

结果

工程化新器官内的细胞对生长因子和外源性高血糖挑战作出反应，并在 pTFs 的严格动态调节下产生大量 InPC。pTFs 的高度受控调节可在工程化的脾支架内产生更高比例的 Nkx-6.1+/C-肽+细胞。在三维器官结构中产生高比例的胰岛素和 C-肽阳性细胞对高血糖刺激的反应更好，产生的胰岛素量高于 2D 培养系统。