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All-Trans Retinoic Acid

Retinoid pathway activator; Activates retinoic acid receptor (RAR)

All-Trans Retinoic Acid

Retinoid pathway activator; Activates retinoic acid receptor (RAR)

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Retinoid pathway activator; Activates retinoic acid receptor (RAR)
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Overview

All-Trans Retinoic Acid is a derivative of Vitamin A that functions as a ligand for the retinoic acid receptor (RAR, ICâ‚…â‚€ = 14 nM). RARs heterodimerize with retinoid X receptors (RXRs) and bind to retinoic acid response elements (RAREs) in DNA and act as transcription factors, altering gene expression. (Apfel et al., Chambon)

DIFFERENTIATION
· Promotes differentiation of motor neurons from mouse and human pluripotent stem cells (Dimos et al., Wichterle et al.).
· Promotes differentiation of neurons from neural stem cells (Takahashi et al.).
· Promotes differentiation of pancreatic progenitors from human embryonic stem (ES) cells (D'Amour et al.).
· Promotes differentiation of adipocytes from mouse ES cells (Dani et al.).
· Promotes differentiation of ventricular cardiomyocytes from mouse ES cells (Wobus et al.).
· Promotes terminal differentiation of granulocytes (Collins).

CANCER RESEARCH
· Promotes maturation of blast cells in differentiation therapy of acute promyelocytic leukemia (Huang et al.).
Cell Type
Adipocytes, Cardiomyocytes, PSC-Derived, Endoderm, PSC-Derived, Granulocytes and Subsets, Leukemia/Lymphoma Cells, Mesoderm, PSC-Derived, Neural Cells, PSC-Derived, Neurons, Pancreatic Cells, Pluripotent Stem Cells
Species
Human, Mouse, Non-Human Primate, Other, Rat
Application
Differentiation
Area of Interest
Cancer, Neuroscience, Stem Cell Biology
CAS Number
302-79-4
Chemical Formula
°äâ‚‚â¸ö±á₂₈°¿â‚‚
Purity
≥ 98%
Pathway
Retinoid
Target
RAR

Protocols and Documentation

Find supporting information and directions for use in the Product Information Sheet or explore additional protocols below.

Document Type
Product Name
Catalog #
Lot #
Language
Document Type
Product Name
Catalog #
72264, 72262, 100-1045
Lot #
All
Language
English
Document Type
Product Name
Catalog #
72264, 72262
Lot #
All
Language
English
Document Type
Product Name
Catalog #
72264, 72262
Lot #
All
Language
English
Document Type
Product Name
Catalog #
100-1045
Lot #
All
Language
English

Resources and Publications

Publications (12)

Mechanosensitive Differentiation of Human iPS Cell-Derived Podocytes Bioengineering 2024 Oct

Abstract

Stem cell fate decisions, including proliferation, differentiation, morphological changes, and viability, are impacted by microenvironmental cues such as physical and biochemical signals. However, the specific impact of matrix elasticity on kidney cell development and function remains less understood due to the lack of models that can closely recapitulate human kidney biology. An established protocol to differentiate podocytes from human-induced pluripotent stem (iPS) cells provides a promising avenue to elucidate the role of matrix elasticity in kidney tissue development and lineage determination. In this study, we synthesized polyacrylamide hydrogels with different stiffnesses and investigated their ability to promote podocyte differentiation and biomolecular characteristics. We found that 3 kPa and 10 kPa hydrogels significantly support the adhesion, differentiation, and viability of podocytes. Differentiating podocytes on a more compliant (0.7 kPa) hydrogel resulted in significant cell loss and detachment. Further investigation of the mechanosensitive proteins yes-associated protein (YAP) and synaptopodin revealed nuanced molecular distinctions in cellular responses to matrix elasticity that may otherwise be overlooked if morphology and cell spreading alone were used as the primary metric for selecting matrices for podocyte differentiation. Specifically, hydrogels with kidney-like rigidities outperformed traditional tissue culture plates at modulating the molecular-level expression of active mechanosensitive proteins critical for podocyte health and function. These findings could guide the development of physiologically relevant platforms for kidney tissue engineering, disease modeling, and mechanistic studies of organ physiology and pathophysiology. Such advances are critical for realizing the full potential of in vitro platforms in accurately predicting human biological responses.
Aberrant evoked calcium signaling and nAChR cluster morphology in a Frontiers in Cell and Developmental Biology 2024 Jun

Abstract

Familial amyotrophic lateral sclerosis (ALS) is a progressive neuromuscular disorder that is due to mutations in one of several target genes, including SOD1. So far, clinical records, rodent studies, and in vitro models have yielded arguments for either a primary motor neuron disease, or a pleiotropic pathogenesis of ALS. While mouse models lack the human origin, in vitro models using human induced pluripotent stem cells (hiPSC) have been recently developed for addressing ALS pathogenesis. In spite of improvements regarding the generation of muscle cells from hiPSC, the degree of maturation of muscle cells resulting from these protocols has remained limited. To fill these shortcomings, we here present a new protocol for an enhanced myotube differentiation from hiPSC with the option of further maturation upon coculture with hiPSC-derived motor neurons. The described model is the first to yield a combination of key myogenic maturation features that are consistent sarcomeric organization in association with complex nAChR clusters in myotubes derived from control hiPSC. In this model, myotubes derived from hiPSC carrying the SOD1 D90A mutation had reduced expression of myogenic markers, lack of sarcomeres, morphologically different nAChR clusters, and an altered nAChR-dependent Ca2+ response compared to control myotubes. Notably, trophic support provided by control hiPSC-derived motor neurons reduced nAChR cluster differences between control and SOD1 D90A myotubes. In summary, a novel hiPSC-derived neuromuscular model yields evidence for both muscle-intrinsic and nerve-dependent aspects of neuromuscular dysfunction in SOD1-based ALS.
Induced pluripotent stem cells generated from patients with ALS can be differentiated into motor neurons. Dimos JT et al. Science (New York, N.Y.) 2008 AUG

Abstract

The generation of pluripotent stem cells from an individual patient would enable the large-scale production of the cell types affected by that patient's disease. These cells could in turn be used for disease modeling, drug discovery, and eventually autologous cell replacement therapies. Although recent studies have demonstrated the reprogramming of human fibroblasts to a pluripotent state, it remains unclear whether these induced pluripotent stem (iPS) cells can be produced directly from elderly patients with chronic disease. We have generated iPS cells from an 82-year-old woman diagnosed with a familial form of amyotrophic lateral sclerosis (ALS). These patient-specific iPS cells possess properties of embryonic stem cells and were successfully directed to differentiate into motor neurons, the cell type destroyed in ALS.