Parenchymal and Stromal Tissue Regeneration of Tooth Organ by Pivotal Signals Reinstated in Decellularized Matrix

Overview

Journal Nat Mater

Date 2019 May 23

PMID 31114073

Citations 29

Authors

Ling He

Jian Zhou

Mo Chen

Chyuan-Sheng Lin

Sahng G Kim

Yue Zhou

Lusai Xiang

Ming Xie

Hanying Bai

Hai Yao

Changcheng Shi

Paulo G Coelho

Timothy G Bromage

Bin Hu

Nick Tovar

Lukasz Witek

Jiaqian Wu

Kenian Chen

Wei Gu

Jinxuan Zheng

Tzong-Jen Sheu

Juan Zhong

Jin Wen

Yuting Niu

Bin Cheng

Qimei Gong

David M Owens

Milda Stanislauskas

Jasmine Pei

Gregory Chotkowski

Sainan Wang

Guodong Yang

David J Zegarelli

Xin Shi

Myron Finkel

Wen Zhang

Junyuan Li

Jiayi Cheng

Dennis P Tarnow

Xuedong Zhou

Zuolin Wang

Xinquan Jiang

Alexander Romanov

David W Rowe

Songlin Wang

Ling Ye

Junqi Ling

Jeremy Mao

Affiliations

Soon will be listed here.

Abstract

Cells are transplanted to regenerate an organs' parenchyma, but how transplanted parenchymal cells induce stromal regeneration is elusive. Despite the common use of a decellularized matrix, little is known as to the pivotal signals that must be restored for tissue or organ regeneration. We report that Alx3, a developmentally important gene, orchestrated adult parenchymal and stromal regeneration by directly transactivating Wnt3a and vascular endothelial growth factor. In contrast to the modest parenchyma formed by native adult progenitors, Alx3-restored cells in decellularized scaffolds not only produced vascularized stroma that involved vascular endothelial growth factor signalling, but also parenchymal dentin via the Wnt/β-catenin pathway. In an orthotopic large-animal model following parenchyma and stroma ablation, Wnt3a-recruited endogenous cells regenerated neurovascular stroma and differentiated into parenchymal odontoblast-like cells that extended the processes into newly formed dentin with a structure-mechanical equivalency to native dentin. Thus, the Alx3-Wnt3a axis enables postnatal progenitors with a modest innate regenerative capacity to regenerate adult tissues. Depleted signals in the decellularized matrix may be reinstated by a developmentally pivotal gene or corresponding protein.

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