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相关概念视频

EPS and iPS Cells in Disease Research01:21

EPS and iPS Cells in Disease Research

2.8K
Embryonic and induced pluripotent stem cells are excellent models for disease research because of their ability to self-renew and differentiate into most cell types. Somatic cells from a patient are isolated and reprogrammed into induced pluripotent stem cells or iPSCs. These iPSCs are later differentiated into the desired cell type, which mirrors the diseased cell of the patient. In this way, disease models have been created for investigating diseases such as Down syndrome, type I diabetes,...
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Induced Pluripotent Stem Cells01:13

Induced Pluripotent Stem Cells

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Stem cells are undifferentiated cells that divide and produce different types of cells. Ordinarily, cells that have differentiated into a specific cell type are post-mitotic—that is, they no longer divide. However, scientists have found a way to reprogram these mature cells so that they “de-differentiate” and return to an unspecialized, proliferative state. These cells are also pluripotent like embryonic stem cells—able to produce all cell types—and are therefore...
24.2K
Chromatin Modification in iPS Cells01:32

Chromatin Modification in iPS Cells

1.7K
Chromatin modification alters gene expression; therefore, scientists can add histone-modifying enzymes, histone variants, and chromatin remodeling complexes to somatic cells to aid reprogramming into pluripotent stem (iPS) cells.
Compact chromatin makes reprogramming difficult. Enzymes, such as histone demethylases and acetyltransferases, are often added during reprogramming to loosen the chromatin, making the DNA more accessible to transcription factors. Molecules that inhibit histone...
1.7K
Somatic to iPS Cell Reprogramming01:29

Somatic to iPS Cell Reprogramming

2.2K
Reprogramming alters the gene expression in somatic cells, transforming them into induced pluripotent stem (iPS) cells over several generations. Scientists can reprogram cells by introducing genes for four transcription factors—Oct4, Sox2, Klf4, and c-Myc (OSKM) by viral or non-viral methods. These factors are also known as Yamanaka factors after Shinya Yamanaka, who first generated iPS cells using mouse skin cells. Yamanaka was awarded the Nobel Prize in Physiology or Medicine in 2012...
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Selecting and Isolating Colonies of Human Induced Pluripotent Stem Cells Reprogrammed from Adult Fibroblasts
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在人类多能干细胞模型中操纵和研究基因功能.

Elisa Balmas1, Federica Sozza1, Sveva Bottini1

  • 1Department of Molecular Biotechnology and Health Sciences, Molecular Biotechnology Center "Guido Tarone", University of Turin, Torino, Italy.

FEBS letters
|July 31, 2023
PubMed
概括
此摘要是机器生成的。

本综述详细介绍了操纵人类多能干细胞 (hPSC) 基因功能的方法. 它涵盖了基因编辑工具,如CRISPR/Cas9及其在研究再生医学的发育和疾病中的应用.

关键词:
干扰和激活CRISPR的干扰和激活这就是CRISPR/Cas9的作用.这是一种RNA干扰.排列和聚合的屏幕.基础和主要编辑.基因组安全港是基因组安全港.同类的重组组合.人类多能干细胞干细胞一个单细胞的屏幕.转基因的转基因发生.

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科学领域:

  • 干细胞生物学 干细胞生物学
  • 遗传学 遗传学 是一个
  • 分子生物学分子生物学

背景情况:

  • 人类多能干细胞 (hPSCs) 对于研究人类发育和疾病至关重要.
  • 在再生医学中的应用取决于hPSCs有效的基因功能操纵.

研究的目的:

  • 在hPSCs中提供基因操纵技术的全面审查.
  • 引导新进入该领域的研究人员,并更新经验丰富的干细胞生物学家.

主要方法:

  • 讨论基因表达操纵 (传染,转导,转位,安全港编辑) 的挑战和解决方案.
  • 概述了历史 (RNAi,转基因,同源重组) 和现代 (CRISPR/Cas9,基编辑,原始编辑) 损失,增益和功能变化研究的方法.
  • 涵盖了数组/聚合功能研究,单细胞基因组学和生物信息学工具.

主要成果:

  • 突出了在hPSC中精确基因编辑的既定和新兴技术.
  • 详细介绍构成性或诱导性基因调制的策略.
  • 解释了这些方法用于功能基因组研究的整合.

结论:

  • 掌握这些基因操纵技术将推动人类生物学和医学的重大进步.
  • 该审查使研究人员能够利用先进的技术进行基于hPSC的研究.