CRISPR (Clustered Regularly Interspaced Short Palindromic Repeats), the term refers to a series of repetitive patterns in the DNA of bacteria and archaea that were extensively studied by Spanish scientist Francis Mojica in the ‘90s. These patterns are the basis of a primitive immune system that bacteria use to ‘remember’ the DNA of viral invaders by incorporating the DNA sequence of the virus within the CRISPR patterns. The Cas9 protein is then able to recognize the DNA sequence stored within CRISPR patterns and cut any DNA molecules with a matching sequence. Since 2012, the CRISPR/Cas systems was developed into easy-to-use and robust genome editing tool for basic research and clinics.
Three common strategies have been developed for genome editing with the CRISPR/Cas9 platform:
(1)The plasmid‐based CRISPR/Cas9 strategy, where a plasmid is used to encode Cas9 protein and sgRNA, assembles Cas9 gene as well as sgRNA into the same plasmid in vitro. However, the encoded plasmid needs to be introduced inside the nucleus of target cells, which is a key challenge in this system.
(2)Direct intracellular delivery of Cas9 messenger RNA (mRNA) and sgRNA, the greatest drawback of which lies in the poor stability of mRNA, which results in transient expression of mRNA and a short duration of gene modification;
(3)Directly delivery of Cas9 protein and sgRNA, which has several advantages, including rapid action, great stability, and limited antigenicity. Among the versatile CRISPR-based tools, CRISPR/Cas9 is the most widerly used one for studying gene functions. It has boost the generation of knockout cell lines for different applications.
Knockout cellular model applications:
There is a significant challenge in translating the abundance of genetic information. To date, it is possible to identify the role of genes, to understand basic biology, as well as linking to the role of mutations for understanding disease pathogenesis. A Knockout (KO) cell lines are excellent model systems to do this. The advantage of cell lines is the ability to use gene-editing to construct isogenic cell line pairs, where a mutant model can be probed alongside a wild-type control. The following are potential examples of how to get the most out of your research using KO cell lines:
1. Antibody specificity validation
2. Identify pathway players
3. Identify drug targets
4. Build disease models
5. Develop therapeutic tools
1. Antibody specificity validation
The research community believes that the use of excellent research tools impacts significantly the quality of research delivered. Antibodies are one of the most commonly used reagents in life-sciences, but despite their widespread use, there are no standard guidelines for how these invaluable biological tools should be validated prior to use. For example, poorly characterized antibodies may yield non-specific results, which are difficult to replicate even when the only difference is the antibody's production lot. However, the bar for antibody validation is rising and there are calls for the industry standard to show application-specific validation using KO cell lines. So, KO cell line has wide application in antibody validation. The parallel use of wildtype and KO cell lines provides a valuable tool to control for research reagents quality.
2. Identify pathway players
Often there are multiple related, but distinct molecules and processes present in a pathway. Gene-edited cell lines are a well-established tool to probe the role of a particular gene or mutation. For example, JAK1 is essential for signaling for certain cytokines and is thought to play a role in tumor metastasis. It is also known to have a functional and physical association with INF gamma receptors. When ligands bind with receptors, the receptor-associated JAKs become activated, leading to the recruitment of specific STATs (signal transducer and activator of transcription) from the cytoplasm. These STATs then become JAK substrates. Activated STATs are released from the receptor, which then translocates to the nucleus to bind to specific enhancer elements. These then affect the expression of target genes. The role of JAK1 in STAT phosphorylation can be confirmed by creating a frameshift mutation in the JAK1 gene and the KO cell line do not allow phosphorylation of STAT and this could be verified with westernblot analysis.
3. Identify drug targets
Pharmacological interventions are commonly used to interrogate pathways. For example, the chemotherapeutic 6-thioguanine (6-TG) is used to probe the effect of DNA damage response. To maintain genomic integrity, cells are equipped with a myriad of mechanisms that are each specific for different types of damage. The efficiency of these DDR pathways plays an essential role in the effectiveness of cytotoxic treatments. 6-TG is a growth inhibitory antimetabolite that requires an active DNA mismatch repair (MMR) system to be effective. One study showed that HPRT+ cells are sensitive to 6-thioguanine (6-TG), which can be converted to the nucleotide form by HPRT and incorporated into DNA by DNA polymerase, killing cells by a process involving postreplicative mismatch repair. The strategy is to transfect cells with two plasmids that express respectively a HPRT guide RNA and a guide RNA for the gene of interest. Cas9 can be expressed from the gene on a separate plasmid, a plasmid carrying the HPRT gRNA or integrated into the chromosome (if such a cell line is already available). If a cell becomes resistant to 6-TG, it would suggest that this cell should also be competent to target the gene of interest as long as the gRNA is effective. Thus if the targeted gene is not altered in the resulting 6-TG resistant cells, it would suggest that the guide RNA is ineffective. On the other hand, if no 6-TG resistant cells can be obtained by co-targeting, it would suggest that the gene of interest might be essential. Thus KO cell lines that are devoid of key proteins are used to confirm the target of the 6-TG.
4. Build disease models
After identifying mutations of interest in a patient population, the next steps are to probe the biological mechanisms that result in the disease phenotype or the response to treatment. KO cell lines, combined with simple molecular biology techniques, allows the researcher to rescue the gene of interest to restore phenotype and complement the Knockout cell line with a functional mutation, such as a point mutation observed in a patient population. One example of disease modeling is MAGEC2 knockout in melanoma cancer cell line. MAGEC2, a member of the type I melanoma-associated antigen family, is expressed in a wide variety of cancer types but not in normal somatic cells. Reserchers generated MAGEC2-knockout A375 melanoma cell lines using the CRISPR/Cas9 system. They found that knockout or knockdown of the MAGEC2 gene sensitized melanoma cells to tumor necrosis factor-α-induced apoptosis. Their study sheds a light on the molecular pathway by which MAGEC2 promotes tumor development.
Earlier studies reported that Nuclear Factor Erythroid 2-Related Factor (NRF2) is a master regulator of 100–200 target genes involved in cellular responses to oxidative and/or electrophilic stress. NRF2 is also known to regulate the expression of genes involved in protein degradation and detoxification, and it is negatively regulated by Kelch-like ECH-associated protein 1 (KEAP1), a substrate adaptor for the Cul3-dependent E3 ubiquitin ligase complex. One research group used CRISPR/Cas9 to disable the NRF2 gene in lung cancer cells by disrupting the NRF2 nuclear export signal (NES) domain; phenotypically, the protein is largely blocked from transiting into the nucleus after translation. Cells with this gene knockout were found to have a reduced proliferation phenotype and are more sensitive to chemotherapeutic agents, such as cisplatin and carboplatin. They also found that homozygous knockout cells proliferate at a slower rate than the wild-type cells, even in the absence of drug treatment.
5. Develop therapeutic tools
During the past few years, the team represented by China and the United States have conducted a series of clinical trials of gene editing, such as producing more effective CAR T cells for the treatment of cancer and the knockout of the erythroid-specific enhancer of BCL11A to upregulate gamma globulin in autologous erythroid HSCs as a potential therapy for sickle cell disease and β-thalassemia. To date, several ongoing clinical trials applying the concept of PD-1 knockout autologous T cells to treat cancers, including prostate cancer (NCT02867345), esophageal cancer (NCT03081715), and renal cell cancer (NCT02867332). These trials are considered proof-of-concept studies to apply the in vitro CRISPR/Cas9 gene knockout technique in cancer therapy.
In summary, KO cell lines are a versatile tool for helping us understand basic biology, as well as identifying the role of mutations in disease pathogenesis. Ultimately, this has led to advances in disease treatment and patient prognosis.
Reference:
Enriching CRISPR-Cas9 targeted cells by co-targeting the HPRT gene. Nucleic Acids Res. 2015. 43(20): e134.
Establishment of MAGEC2-knockout cells and functional investigation of MAGEC2 in tumor cells. Cancer Sci 2016. 107(12):1888-1897.
Functional Gene Knockout of NRF2 Increases Chemosensitivity of Human Lung Cancer A549 Cells In Vitro and in a Xenograft Mouse Model. Molecular Therapy: Oncolytics. 2018 11:75-89.
Applications of genome editing technology in the targeted therapy of human diseases: mechanisms, advances and prospects. Signal Transduct Target Ther .2020 Jan 3;5(1):1.
No comments:
Post a Comment