The role of DNA methylation in chondrogenesis of human iPSCs as a stable marker of cartilage quality.

IF 4.8 2区医学 Q1 GENETICS & HEREDITY

Clinical Epigenetics Pub Date : 2024-10-15 DOI:10.1186/s13148-024-01759-y

Ghazaleh Hajmousa, Rodrigo Coutinho de Almeida, Niek Bloks, Alejandro Rodríguez Ruiz, Marga Bouma, Roderick Slieker, Thomas B Kuipers, Rob G H H Nelissen, Keita Ito, Christian Freund, Yolande F M Ramos, Ingrid Meulenbelt

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引用次数: 0

Abstract

Background: Lack of insight into factors that determine purity and quality of human iPSC (hiPSC)-derived neo-cartilage precludes applications of this powerful technology toward regenerative solutions in the clinical setting. Here, we set out to generate methylome-wide landscapes of hiPSC-derived neo-cartilages from different tissues-of-origin and integrated transcriptome-wide data to identify dissimilarities in set points of methylation with associated transcription and the respective pathways in which these genes act.

Methods: We applied in vitro chondrogenesis using hiPSCs generated from two different tissue sources: skin fibroblasts and articular cartilage. Upon differentiation toward chondrocytes, these are referred to as hFiCs and hCiC, respectively. Genome-wide DNA methylation and RNA sequencing datasets were generated of the hiPSC-derived neo-cartilages, and the epigenetically regulated transcriptome was compared to that of neo-cartilage deposited by human primary articular cartilage (hPAC).

Results: Methylome-wide landscapes of neo-cartilages of hiPSCs reprogrammed from two different somatic tissues were 85% similar to that of hPACs. By integration of transcriptome-wide data, differences in transcriptionally active CpGs between hCiC relative to hPAC were prioritized. Among the CpG-gene pairs lower expressed in hCiCs relative to hPACs, we identified genes such as MGP, GDF5, and CHAD enriched in closely related pathways and involved in cartilage development that likely mark phenotypic differences in chondrocyte states. Vice versa, among the CpG-gene pairs higher expressed, we identified genes such as KIF1A or NKX2-2 enriched in neurogenic pathways and likely reflecting off target differentiation.

Conclusions: We did not find significant variation between the neo-cartilages derived from hiPSCs of different tissue sources, suggesting that application of a robust differentiation protocol such as we applied here is more important as compared to the epigenetic memory of the cells of origin. Results of our study could be further exploited to improve quality, purity, and maturity of hiPSC-derived neo-cartilage matrix, ultimately to realize introduction of sustainable, hiPSC-derived neo-cartilage implantation into clinical practice.

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DNA 甲基化作为软骨质量的稳定标记在人类 iPSCs 软骨成因中的作用。

背景：由于对决定人类 iPSC（hiPSC）衍生新软骨纯度和质量的因素缺乏深入了解，这一强大的技术无法应用于临床再生解决方案。在此，我们着手生成来自不同原生组织的 hiPSC 衍生新软骨的全甲基组图谱，并整合全转录组数据，以确定甲基化集点与相关转录的差异，以及这些基因发挥作用的各自途径：我们使用从皮肤成纤维细胞和关节软骨这两种不同组织来源生成的 hiPSCs 进行体外软骨生成。分化为软骨细胞后，分别称为 hFiCs 和 hCiCs。研究人员生成了源于hiPSC的新软骨的全基因组DNA甲基化和RNA测序数据集，并将表观遗传调控转录组与人类原生关节软骨（hPAC）沉积的新软骨进行了比较：结果：从两种不同的体细胞组织重编程的 hiPSCs 新软骨的全基因组图谱与 hPACs 新软骨的全基因组图谱有 85% 的相似性。通过整合全转录组数据，确定了 hCiC 与 hPAC 之间转录活跃 CpG 的差异。在hCiCs相对于hPACs表达较低的CpG基因对中，我们发现了MGP、GDF5和CHAD等富集在密切相关通路中并参与软骨发育的基因，这些基因可能标志着软骨细胞状态的表型差异。反之亦然，在表达较高的 CpG 基因对中，我们发现了 KIF1A 或 NKX2-2 等富含神经源通路的基因，这些基因可能反映了脱靶分化：我们没有发现不同组织来源的 hiPSCs 所衍生的新软骨之间存在明显差异，这表明与原代细胞的表观遗传记忆相比，我们所采用的稳健分化方案更为重要。我们的研究结果可进一步用于提高 hiPSC 衍生新软骨基质的质量、纯度和成熟度，最终实现将可持续的 hiPSC 衍生新软骨植入临床实践。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Clinical Epigenetics ONCOLOGY-

自引率

5.30%

发文量

150

期刊介绍： Clinical Epigenetics, the official journal of the Clinical Epigenetics Society, is an open access, peer-reviewed journal that encompasses all aspects of epigenetic principles and mechanisms in relation to human disease, diagnosis and therapy. Clinical trials and research in disease model organisms are particularly welcome.