Human IFIT1 Knockout Cell Line-HEK293T
Cat.No. : CSC-RT2788
Host Cell: HEK293T Target Gene: IFIT1
Size: 1x10^6 cells/vial, 1mL Validation: Sequencing
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Cell Line Information
Cell Culture Information
Safety and Packaging
| Cat. No. | CSC-RT2788 |
| Cell Line Information | This cell is a stable cell line with a homozygous knockout of human IFIT1 using CRISPR/Cas9. |
| Target Gene | IFIT1 |
| Host Cell | HEK293T |
| Size Form | 1 vial (>10^6 cell/vial) |
| Shipping | Dry ice package |
| Storage | Liquid Nitrogen |
| 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
Case Study
Applications
The IFIT1 gene, also known as interferon-induced tetratricopeptide repeat 1 protein, is located on chromosome 10 and is known to encode a protein with a specific repeat sequence called tetratricopeptide repeat (TPR). The main function of the IFIT1 protein is to act as an antiviral agent. It is part of the body's innate immune system and is primarily induced by type I interferons. Interferons are proteins released by host cells, usually in response to the presence of pathogens such as viruses. Once induced, IFIT1 can inhibit the initiation of viral replication and translation processes, effectively helping to prevent the spread of viruses within the host.
In addition, IFIT1 is involved in a variety of other biological processes, including regulating viral genome replication, cellular responses to exogenous double-stranded RNA (dsRNA), and regulating helicase activity. It operates primarily within the cytoplasm and cytosol of host cells, interacting with viral components to exert its antiviral effects. Interestingly, IFIT1 has been found to bind RNA, which is essential for its recognition and combating of viral infections. Variations and mutations in the IFIT1 gene can affect the body's response to viral infections and have an impact on viral pathogenesis and immunity. For example, IFIT1 has been implicated in the regulation of immune responses in diseases such as chronic hepatitis C virus infection.
IFIT is an interferon-inducible protein that binds to the 5'-triphosphate or ribose unmethylated capped ends of mRNAs to inhibit translation. Although some viruses circumvent IFIT by synthesizing RNAs with eukaryotic-like caps, no viral proteins have been identified that antagonize IFIT. Here, researchers show that the N-terminal and C-terminal portions of C9, a protein required for vaccinia virus resistance to the type I interferon-induced state in humans, bind IFIT and the ubiquitin regulatory complex, respectively. The two C9 domains co-target IFIT for proteasomal degradation, thereby conferring interferon resistance similar to that of IFIT knockout. Furthermore, ectopic expression of C9 rescues the interferon sensitivity of a vaccinia virus mutant with an inactive cap-1-specific ribose methyltransferase that is otherwise unable to express early proteins. In contrast, a C9 deletion mutant expresses early proteins but is blocked by IFIT at the subsequent genome uncoating/replication step. Thus, poxviruses exploit mRNA cap methylation and proteasomal degradation to defeat multiple antiviral activities of IFIT.
Studies have shown that the role of IFIT in inhibiting vΔC9 is distinct from that resulting from the lack of ribose methylation of the mRNA cap structure. Previous studies have shown that viral DNA replication is severely inhibited in IFN-treated A549 cells infected with vΔC9. In addition, there is evidence of impaired release of viral DNA from the nucleus. Here, further experiments were performed to assess whether these steps would be rescued in IFN-treated A549 IFIT1 knockout and IFIT3 knockout (KO) cells infected with vΔC9 (Figure 1A). In control mock-infected A549 cells, background I3 staining was not detected and only EdU labeled nuclear DNA (Figure 1B). In contrast to the results obtained with unmodified A549 cells, the I3 and EdU staining patterns of IFIT1 KO cells infected with vΔC9 were not reduced by IFN pretreatment, indicating that IFIT1 is required for the inhibition of genome replication (Figure 1B). Under the same conditions, IFIT3 KO cells were less protected from IFN, while IFIT2 KO cells showed little or no protection from IFN. In AraC-treated cells infected with vΔC9, resistance to IFN-mediated inhibition of uncoating was also greatest in IFIT1 KO cells, followed by IFIT3 and IFIT2 KO cells (Figures 1B and 1C). Compared with A549 cells, the fold increase in genome copy number in IFN-treated and vΔC9-infected IFIT1, IFIT2, and IFIT3 KO cells was approximately 16-fold, 3-fold, and 9-fold, respectively (Figure 1D). Thus, the beneficial effects of IFIT KO on genome uncoating and replication in IFN-pretreated cells were IFIT1 > IFIT3 > IFIT2. Furthermore, inhibition of genome replication could fully explain the reduction of VACV intermediate and late mRNAs and their translation products in vΔC9-infected cells pretreated with IFN.
Figure 1. Restoration of VACV DNA replication in IFN-β-pretreated A549 IFIT1 knockout and IFIT3 knockout cells. (Liu R, et al., 2019)
Viral Infection Studies: IFIT1 is known to be an interferon-stimulated gene that plays a crucial role in the antiviral response. By knocking out IFIT1, researchers can investigate the specific contributions of this gene to viral replication and immune evasion strategies, thereby enhancing our understanding of viral pathogenesis and host immune responses.
Gene Function Analysis: By comparing cellular responses in wild-type and knockout contexts, researchers can discern the specific cellular processes and pathways influenced by IFIT1, offering insights into its broader biological roles.
Drug Screening and Development: The cell line serves as a valuable tool for screening potential antiviral drugs. With disrupted IFIT1 function, it is possible to identify compounds that either mimic its activity or compensate for its absence, thereby paving the way for novel therapeutic interventions.
Protein-Protein Interaction Studies: By using the IFIT1 knockout cell line, scientists can study the interactions between IFIT1 and other cellular proteins.
Cancer Research: Since the IFIT1 gene is involved in cell proliferation and apoptosis, knocking out IFIT1 in HEK293T cells provides a model to study its role in cancer biology.
For research use only. Not intended for any clinical use.
