Preparing Feeder Cell Layers from STO or Mouse Embryo Fibroblast (MEF) Cells: Treatment with Mitomycin C

Generation of interspecies mouse-rat chimeric embryos by embryonic stem (ES) cell microinjection

Interspecies chimerism is a useful tool to study interactions between cells of different genetic makeup in order to elucidate the mechanisms underlying non-cell-autonomous processes, including evolutionary events. However, generating interspecies chimeras with high efficiency and chimerism level remains challenging. Here, we describe a protocol for generating chimeras between mouse and rat. Donor embryonic stem cells of one species are microinjected into early embryos of the other species (recipient), which are implanted into host foster mothers of the recipient species.

For complete details on the use and execution of this protocol, please refer to Stepien et al. (2020).

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Isolation of ES cells from mouse blastocysts and culture of rodent ES cells

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Microinjection of mouse ES cells into early rat embryos and vice versa

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Transfer of chimeric embryos into pseudo-pregnant foster mothers

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Generation of mouse-rat chimeric brains

Feeder-Dependent/Independent Mouse Embryonic Stem Cell Culture Protocol

Mouse embryonic stem cells (mESCs) were first derived and cultured nearly 30 years ago and have been beneficial tools to create transgenic mice and to study early mammalian development so far. Fibroblast feeder cell layers are often used at some stage in the culture protocol of mESCs. The feeder layer-often mouse embryonic fibroblasts (MEFs)-contribute to the mESC culture as a substrate to increase culture efficiency, maintain pluripotency, and facilitate survival and growth of the stem cells. Various feeder-dependent and feeder-independent culture and differentiation protocols have been established for mESCs. Here we describe the isolation, culture, and preparation feeder cell layers and establishment of feeder-dependent/independent protocol for mESC culture. In addition, basic mESC protocols for culture, storage, and differentiation were described.

Skin wound closure delay in metabolic syndrome correlates with SCF deficiency in keratinocytes

Poor wound closure due to diabetes, aging, stress, obesity, alcoholism, and chronic disease affects millions of people worldwide. Reasons wounds will not close are still unclear, and current therapies are limited. Although stem cell factor (SCF), a cytokine, is known to be important for wound repair, the cellular and molecular mechanisms of SCF in wound closure remain poorly understood. Here, we found that SCF expression in the epidermis is decreased in mouse models of delayed wound closure intended to mimic old age, obesity, and alcoholism. By using SCF conditionally knocked out mice, we demonstrated that keratinocytes' autocrine production of SCF activates a transient c-kit receptor in keratinocytes. Transient activation of the c-kit receptor induces the expression of growth factors and chemokines to promote wound re-epithelialization by increasing migration of skin cells (keratinocytes and fibroblasts) and immune cells (neutrophils) to the wound bed 24-48 h post-wounding. Our results demonstrate that keratinocyte-produced SCF is essential to wound closure due to the increased recruitment of a unique combination of skin cells and immune cells in the early phase after wounding. This discovery is imperative for developing clinical strategies that might improve the body's natural repair mechanisms for treating patients with wound-closure pathologies.

In vitro generation of mouse polarized embryo-like structures from embryonic and trophoblast stem cells

Mammalian embryogenesis requires the coordination of embryonic and extra-embryonic tissues to enable implantation into the uterus and post-implantation development to establish the body plan. Mouse embryonic stem cells (ESCs) are a useful tool for studying pluripotent embryonic tissue in vitro. However, they cannot undertake correct embryogenesis alone. Many attempts to model the early embryo in vitro involve the aggregation of ESCs into spheroids of variable size and cell number that undertake germ-layer specification but fail to recapitulate the characteristic architecture and arrangement of tissues of the early embryo. Here, we describe a protocol to generate the first embryo-like structures by directing the assembly of mouse ESCs and extra-embryonic trophoblast stem cells (TSCs) in a 3D extracellular matrix (ECM) into structures we call 'polarized embryo-like structures'. By establishing the medium and culture conditions needed to support the growth of both stem cell types simultaneously, embryonic architecture is generated within 4 d of co-culture. This protocol can be performed by those proficient in standard ESC culture techniques and can be used in developmental studies to investigate the interactions between embryonic and extra-embryonic tissues during mammalian development.

Testing Serum Batches for Mouse Embryonic Stem Cell Culture

The variability in embryonic stem (ES) cell culture is due primarily to serum. Serum is typically produced in large batches from many animals. However, samples may differ depending on the age and diet of the animals, the country of origin, and other factors creating lot-to-lot variations. Some vendors test FBS lots for compatibility with ES cell culture. Many laboratories prefer to test serum batches themselves to identify the lot giving optimal growth. In this protocol, small quantities of specific serum batches are obtained from different suppliers and tested for their ability to support ES cells in an undifferentiated state. A complete test includes the serum batches' influence on plating efficiency, cell morphology, toxicity, and, if possible, their ability to support generation of chimeras.

Culture and Expansion of Primary Undifferentiated Spermatogonial Stem Cells

This protocol describes a culture method for supporting the maintenance and expansion of a primary mouse undifferentiated spermatogonial population containing spermatogonial stem cells (SSCs). The doubling time for SSCs in culture is relatively slow. Once established, SSC lines are split 1:2 to 1:4 every 7 d. Therefore, the time required to generate sufficient SSCs for experimentation can be considerable and requires careful planning.

Cryopreserving and Thawing Spermatogonial Stem Cells

Spermatogonial stem cells (SSCs) can be cryopreserved and stored in liquid nitrogen, using relatively standard cryopreservation techniques. At a subsequent time, they can be thawed for subsequent culture and expansion and then transplanted to generate spermatogenesis.

Derivation and Culture of Epiblast Stem Cell (EpiSC) Lines

This protocol describes the derivation and culture of epiblast stem cells (EpiSCs) from early postimplantation epiblasts. EpiSCs can be maintained in an undifferentiated state and retain the ability to generate tissues from all three germ layers in vitro and to form teratomas in vivo. However, they seem unable to form chimeras. Whether this is due to differences in developmental status or a cellular incompatibility (e.g., cell adhesion) between EpiSCs and the host inner cell mass (ICM) is currently unclear. Other differences between mouse embryonic stem (ES) cells and EpiSCs also exist, including gene expression profiles and different growth factor requirements for self-renewal. Thus, EpiSCs provide an important in vitro model for studying the establishment and maintenance of pluripotency in postimplantation epiblast tissues.

Derivation and Culture of Extra-Embryonic Endoderm Stem Cell Lines

Whereas embryonic stem (ES) cells are isolated from the embryonic lineage of the blastocyst, other stable stem cell lines can be derived from the extraembryonic tissues of the early mouse embryo. Trophoblast stem (TS) cells are derived from trophectoderm and early postimplantation trophoblast, and extraembryonic endoderm stem (XEN) cells are derived from primitive endoderm. The derivation of XEN cell lines from 3.5-dpc mouse blastocysts, described here, is similar to the derivation of TS cell lines. TS and XEN cells can self-renew in vitro and differentiate in vitro and in chimeras (in vivo) in a lineage-appropriate manner, showing the developmental potential of their origin, thus providing important models to study the mouse extraembryonic lineages.

Isolation and handling of mouse embryonic fibroblasts

Primary mouse embryonic fibroblasts (MEFs) are the most commonly used feeder layers that help to support growth and maintain pluripotency of embryonic stem cells (ESC) in long-term culture. Feeders provide substrates/nutrients that are essential to maintain pluripotency and prevent spontaneous differentiation of ESC. Since embryonic fibroblasts stop dividing after a few passages, care must be taken to isolate them freshly. Here, we provide a protocol to derive MEFs and describe the method to inactivate the cells using mitomycin C treatment. The protocol also describes freezing, thawing, and passaging of MEFs. This basic protocol works well in our laboratory. However, it can be modified and adapted according to any user's particular requirement.

Slow turning lateral vessel bioreactor improves embryoid body formation and cardiogenic differentiation of mouse embryonic stem cells

Embryonic stem cells (ESCs) have the ability to form aggregates, which are called embryoid bodies (EBs). EBs mimic early embryonic development and are commonly produced for cardiomyogenesis. Here, we describe a method of EB formation in hydrodynamic conditions using a slow-turning lateral vessel (STLV) bioreactor and the subsequent differentiation of EBs into cardiomyocytes. EBs formed in the STLV were compared with conventional techniques, such as hanging drop (HD) or static suspension cell culture (SSC), for homogeneity of EB size, shape, proliferation, apoptosis, and in vitro cardiac differentiation. After 3 days of culture, a four-fold improvement in the yield of EB formation/mL, a six-fold enhancement in total yield of EB/mL, and a nearly 10-fold reduction of cells that failed to incorporate into EBs were achieved in STLV versus SSC. During cardiac differentiation, a 1.5- to 4.2-fold increase in the area of cardiac troponin T (cTnT) per single EB in STLV versus SSC and HD was achieved. These results demonstrate that the STLV method improves the quality and quantity of ES cells to form EBs and enhances the efficiency of cardiac differentiation. We have demonstrated that the mechanical method of cell differentiation creates different microenvironments for the cells and thus influences their lineage commitments, even when genetic origin and the culture medium are the same. Ascorbic acid (ASC) improved further cardiac commitment in differentiation assays. Hence, this culture system is suitable for the production of large numbers of cells for clinical cell replacement therapies and industrial drug testing applications.

Thawing embryonic stem (ES) cells from a 96-well plate

INTRODUCTION

The most widely used method to alter the genome of embryonic stem (ES) cells is to introduce a specifically designed DNA fragment using electroporation. The DNA will then integrate into the genome of ES cells. Colonies of cells containing the exogenous DNA are then picked, expanded, replica-plated, frozen in 96-well plates, and used as a source for genomic DNA preparation for genotyping. After ES candidate clones are identified by genomic Southern blot or polymerase chain reaction (PCR), the method of rescue of the cells from the frozen 96-well plates is very important. This protocol describes a method for thawing such cells.