Human DMD Knockout Cell Line-HEK293T
Cat.No. : CSC-RT2773
Host Cell: HEK293T Target Gene: DMD
Size: 1x10^6 cells/vial, 1mL Validation: Sequencing
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Cell Line Information
Cell Culture Information
Safety and Packaging
| Cat. No. | CSC-RT2773 |
| Cell Line Information | This cell is a stable cell line with a homozygous knockout of human DMD using CRISPR/Cas9. |
| Target Gene | DMD |
| Host Cell | HEK293T |
| Size Form | 1 vial (>10^6 cell/vial) |
| Shipping | Dry ice package |
| Storage | Liquid Nitrogen |
| Species | Human |
| Revival | Rapidly thaw cells in a 37°C water bath. Transfer contents into a tube containing pre-warmed media. Centrifuge cells and seed into a 25 cm2 flask containing pre-warmed media. |
| Media Type | Cells were cultured in DMEM supplemented with 10% fetal bovine serum. |
| Growth Properties | Cells are cultured as a monolayer at 37°C in a humidified atmosphere with 5% CO2. Split at 80-90% confluence, approximately 1:3-1:6. |
| Freeze Medium | Complete medium supplemented with 10% (v/v) DMSO |
| Mycoplasma | Negative |
| Format | One frozen vial containing millions of cells |
| Storage | Liquid nitrogen |
| Safety Considerations |
The following safety precautions should be observed. 1. Use pipette aids to prevent ingestion and keep aerosols down to a minimum. 2. No eating, drinking or smoking while handling the stable line. 3. Wash hands after handling the stable line and before leaving the lab. 4. Decontaminate work surface with disinfectant or 70% ethanol before and after working with stable cells. 5. All waste should be considered hazardous. 6. Dispose of all liquid waste after each experiment and treat with bleach. |
| Ship | Dry ice |
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Background
Applications
DMD, or the dystrophin gene, is one of the largest genes in humans. The DMD gene is located on the X chromosome, spans approximately 2.4 million DNA base pairs, and contains 79 exons. The gene encodes dystrophin, a protein that is essential for maintaining the integrity of muscle cell membranes. In skeletal and cardiac muscle, dystrophin is an important component of a large group of proteins called the dystrophin-associated protein complex. This complex strengthens muscle fibers and protects them from damage when muscles contract and relax. The dystrophin complex acts like an anchor, connecting the structural framework of each muscle cell (the cytoskeleton) to the lattice of proteins and other molecules outside the cell (the extracellular matrix). The dystrophin complex may also play a role in cell signaling by interacting with proteins that send and receive chemical signals.
DMD gene mutations result in missing or dysfunctional dystrophin, which can lead to severe muscle-related diseases, most notably Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD). Duchenne muscular dystrophy is a devastating X-linked recessive genetic disease that primarily affects boys and is characterized by rapid progression of muscle degeneration and weakness. The disease typically manifests in early childhood, leading to loss of the ability to walk by early adolescence and often leading to life-threatening cardiopulmonary complications by early adulthood. Becker muscular dystrophy, on the other hand, is less severe and has a later onset than Duchenne muscular dystrophy because a partially functional dystrophin protein is produced.
The Human DMD Knockout Cell Line - HEK293T is a powerful model for scientific research investigating Duchenne Muscular Dystrophy (DMD) and other related muscle diseases. Here are the key applications of this cell line:
Duchenne Muscular Dystrophy Mechanistic Studies: This knockout cell line is essential for exploring the molecular and cellular mechanisms of DMD. By studying how the absence of dystrophin affects cellular processes, researchers can gain insight into the pathology and progression of the disease.
Drug Screening and Development: DMD Knockout HEK293T cells provide a robust platform for high-throughput drug screening to identify potential therapeutic compounds that can compensate for the absence of dystrophin or slow muscle degeneration.
Protein Interaction Studies: Understanding how dystrophin interacts with other proteins within muscle cells is essential for deciphering the protein networks that are disrupted by DMD. Knockout cell lines help identify and validate these interactions.
Pathway Analysis: Researchers can use this knockout model to study signaling pathways and stress responses that are activated in the absence of dystrophin. This information can help identify new therapeutic targets and pathways that are either compensatory or detrimental in DMD.
For research use only. Not intended for any clinical use.
