TeSR™-E7™ Medium for Reprogramming (2-Component)
Feeder-free and animal component-free reprogramming medium for human iPS cell induction
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Overview
Data Figures

Figure 1. Schematic of Reprogramming Timeline
TeSR™-E7™ can be used during the entire induction phase of reprogramming (day 3 to 25+). Following reprogramming, iPS cell colonies can be isolated and propogated in feeder-free maintenance systems (eg. mTeSR™1 or TeSR™-E8™ media on Corning® Matrigel® or Vitronectin XF™ matrices).

Figure 2. Morphology of Representative iPS Cell Colonies Arising During the Induction Period in TeSR™-E7™
(A-B) Small clusters of colonies with an epithelial-like morphology will appear by one to two weeks following induction (see arrows). (C-D) These clusters expand into pre-iPS cell colonies by two to three weeks. (E-F) Larger ES cell-like colonies are clearly identifiable by three to four weeks. Representative colonies from adult human fibroblasts reprogrammed with episomal vectors containing OCT-4, SOX2, KLF-4, and L-MYC are shown.

Figure 3. Comparison of Primary iPS Cell Colonies Derived Using TeSR™-E7™ and KOSR-Based Medium
(A) TeSR™-E7™ generates colonies with defined borders and less overgrowth of background fibroblasts compared to (B) KOSR-based iPS cell induction medium. Representative colonies from adult human fibroblasts reprogrammed with episomal vectors containing OCT-4, SOX2, KLF-4, and L-MYC are shown.

Figure 4. Comparison of Primary iPS Cell Colonies Derived Using TeSR™-E7™ with Qualified vs Unqualified bFGF
(A) TeSR™-E7™ yields easily recognizable iPS cell colonies with defined borders. (B) Unqualified components can result in colonies that have poorly defined edges and higher levels of differentiation. Representative colonies from adult human fibroblasts reprogrammed with episomal vectors containing OCT-4, SOX2, KLF-4, and L-MYC are shown.

Figure 5. iPS Colonies Expanded in mTeSR™ or TeSR™-E8™
(A - D) iPS cell colonies generated in TeSR™-E7™ and expanded in either mTeSR™1 on Corning® Matrigel® (A-B) or TeSR™-E8™ on Vitronectin XF™ (C, D) exhibit classic ES cell morphology with dense colony centers, defined borders, prominent nucleoli and high nuclear-to-cytoplasmic ratios. (E) iPS cells express high levels of pluripotency markers after just two passages in either mTeSR™1 or TeSR™-E8™ as demonstrated by OCT-4 and SSEA-3 flow cytometry analysis. Data are expressed as mean ± SEM, n = 4.

Figure 6. TeSR™-E7™ Supports Reprogramming of Human Cell Types Including Adult Dermal Fibroblasts and Neonatal Fibroblasts
Reprogramming of (A) adult normal human dermal fibroblasts (NHDF, 33 year-old female) and (B) neonatal foreskin fibroblasts (BJ cells) with episomal reprogramming vectors are shown. TeSR™-E7™ demonstrated similar (in NHDF) or greater (in BJ cells) reprogramming efficiencies compared to KOSR-based iPS cell induction medium. TeSR™-E7™ demonstrated higher reprogramming efficiencies compared to TeSR™-E8™. Data are expressed as mean ± SEM, n ≥ 6, * p ≤ 0.05.

Figure 7. iPS Cells Derived in TeSR™-E7™ Display Normal Karyotype
iPS cell lines were generated in TeSR™-E7™ medium, maintained in mTeSR™1 or TeSR™-E8™ media for a minimum of 5 passages and karyotyped by G-banding karyotype analysis. Three iPS cell lines were analyzed and all demonstrated a normal karyotype; a representative karyogram is shown.

Figure 8. Directed Differentiation of iPS Cells to All Three Germ Layers
TeSR™-E7™-derived iPS cells were differentiated into all three germ layers. Endoderm specification was achieved using the STEMdiff™ Definitive Endoderm Kit, results demonstrated 93.6% SOX17 + CXCR4 + cells. Mesoderm specification was demonstrated using a STEMdiff™ APEL™ medium-based endothelial differentiation protocol, results demonstrated &ht;99% CD31 + cells (data not shown) and 84.8% VEGFR2 + CD105 + cells. Ectoderm specification was demonstrated using STEMdiff™ Neural Induction Medium, immunocytochemistry shows high levels of PAX6 staining with no detectable OCT-4 staining by day 9 of neural induction.
Protocols and Documentation
Find supporting information and directions for use in the Product Information Sheet or explore additional protocols below.
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Legal Statement:
This product was developed under license to intellectual property owned by WiCell™ Research Institute. This product is sold for research use only (whether the buyer is an academic or for-profit entity) under a non-transferable, limited-use license. Purchase of this product does not include the right to sell, use or otherwise transfer this product for commercial purposes (i.e., any activity undertaken for consideration, such as use of this product for manufacturing, or resale of this product or any materials made using this product, or use of this product or any materials made using this product to provide services) or clinical use (i.e., administration of this product or any material using this product to humans) or the right to implant any material made using this product into an animal by, or in collaboration with, a for-profit entity, for purposes other than basic pre-clinical research applications (including without limitation teratoma assays) to validate the function of the cells. Purchasers who do not agree to the terms and conditions set forth above should return the product in acceptable conditions to the seller for a refund.
Quality Statement:
PRODUCTS ARE FOR RESEARCH USE ONLY AND NOT INTENDED FOR HUMAN OR ANIMAL DIAGNOSTIC OR THERAPEUTIC USES UNLESS OTHERWISE STATED. FOR ADDITIONAL INFORMATION ON QUALITY AT STEMCELL, REFER TO WWW.STEMCELL.COM/COMPLIANCE.