CLEC12A Knockout HEK293 Cell Line

CLEC12A Knockout HEK293 Cell Line
Cat.No.:

EDC07543

Species:

Human

Cell Name:

HEK293

Gene:

CLEC12A

Gene ID:

160364

Size:

1×10⁶cells

CLEC12A Knockout Cell Line (HEK293) is an exclusive upgraded CRISPR/Cas9 system-mediated gene knockout cell, with the advantages of Optimized Strategy Design, Efficient Cell Transfection, High-Performance Cas9 Protein and Hassle-Free Cell Selection.
Cat.No. EDC07543
Product Name CLEC12A Knockout Cell Line (HEK 293)
Cell Line HEK293
Cellosaurus ID CVCL_0045
Cell Line Synonyms Hek293, HEK-293, HEK/293, (HEK)293, HEK 293, HEK,293, 293, 293 HEK, 293 Ad5, Graham 293, Graham-293, Human Embryonic Kidney 293
Gene CLEC12A
NCBI Gene ID
Gene Synonyms CD371|CLL-1|CLL1|DCAL-2|MICL|hKLRL1
Summary
This gene encodes a member of the C-type lectin/C-type lectin-like domain (CTL/CTLD) superfamily. Members of this family share a common protein fold and have diverse functions, such as cell adhesion, cell-cell signaling, glycoprotein turnover, and roles in inflammation and immune response. The protein encoded by this gene is a negative regulator of granulocyte and monocyte function. Several alternatively spliced transcript variants of this gene have been described, but the full-length nature of some of these variants has not been determined. This gene is closely linked to other CTL/CTLD superfamily members in the natural killer gene complex region on chromosome 12p13. [provided by RefSeq, May 2011]
Associated Diseases Non-tumor
Morphology Adherent
Passage Ratio 1/5,2days
Complete Culture Medium DMEM + 10% FBS
Freezing Medium 95% Complete culture medium+ 5% DMSO
QC Indels validated by Sanger sequencing; sterility confirmed via microbial testing.
* For research use only. Not intended for use in humans or animals, including clinical, therapeutic, or diagnostic purposes.
LociSTR Info (Sample Cell)
Sample Cell Line: HEK293
STR Info (Cell bank)
Cell Line: HEK293
Allele1Allele2Allele1Allele2
Amelogenin X X
CSF1P0 12 11 12
D2S1338 19 19
D3S1358 15 17 15 17
D5S818 8 8 9
D7S820 11 12 11 12
D8S1179 12 14 12 14
D13S317 12 14 12 14
D16S539 9 13 9 13
D18S51 17 18 17 18
D19S433 15 18 15 18
D21S11 28 30.2 28 30.2
FGA 23 23
Penta D 9 10 9 10
Penta E 7 15 7 15
TH01 7 9.3 7 9.3
TPOX 11 11
vWA 16 19 16 19
D6S1043 11 11
D12S391 19 21 11 15
D2S441 11 15 11 15
* STR authentication data of this cell line matches with that of cell lines sourced from ATCC, DSMZ, JCRB, and RIKEN databases.
Conclusion: The STR identification of this cell is correct.

FAQ

The choice depends on whether you are studying CLEC12A (CD371, MICL)'s role as an inhibitory C-type lectin receptor or modeling its emerging functions as an AML therapy target. The Knockout line is the standard tool for asking whether CLEC12A is required for these processes — CLEC12A is a C-type lectin-like ITIM-containing inhibitory receptor expressed on myeloid cells (granulocytes, monocytes, DCs) and importantly on AML leukemic stem cells (LSCs); CLEC12A recognizes monosodium urate crystals released from dying cells as a damage-associated molecular pattern. Overexpression is useful for studying CLEC12A in heterologous expression contexts. For AML therapy research, the EDITGENE CLEC12A Knockout in HEK293 is uniquely valuable — CLEC12A is selectively expressed on AML leukemic stem cells with minimal expression on normal hematopoietic stem cells, making it one of the most validated AML-specific therapy targets. Rescue with wild-type or ITIM-mutant CLEC12A enables structure-function studies. The knockout is a critical specificity tool for ⭐ tepoditamab/MCLA-117 (anti-CLEC12A × CD3 bispecific T-cell engager, clinical development for AML), CLEC12A-targeted CAR-T cells, and emerging CLEC12A-targeted AML therapeutics — CLEC12A may enable AML therapy with reduced HSC toxicity.
Primary applications: • AML LSC-targeted therapy specificity: critical genetic control for tepoditamab (MCLA-117 anti-CLEC12A×CD3 bispecific), CLEC12A-CAR-T cells, and emerging CLEC12A-targeted AML therapeutics. • Inhibitory ITIM signaling: in heterologous myeloid contexts, phospho-SHP1/SHP2 recruitment and ITIM-mediated inhibitory signaling. • Monosodium urate crystal recognition: in heterologous innate immune contexts, MSU crystal-induced CLEC12A signaling. • CLEC12A-targeted ADC development: anti-CLEC12A antibody-drug conjugate specificity validation. EDITGENE recommends this model as the gold-standard genetic specificity control for emerging AML-targeted CLEC12A therapeutics.
Yes. CLEC12A rescue experiments require attention to ITIM signaling architecture: • Construct design: use a codon-modified CLEC12A sequence with a small intracellular C-terminal tag (FLAG, HA). CLEC12A has extracellular C-type lectin-like domain, transmembrane span, and intracellular ITIM (immunoreceptor tyrosine-based inhibitory motif) — preserve all elements. • Surface localization validation: confirm plasma membrane localization before functional assays. • ITIM-mutant rescue: tyrosine-to-phenylalanine mutation in the ITIM (Y7F) abolishes SHP1/SHP2 recruitment. • Functional readout: rescue should restore inhibitory signaling and anti-CLEC12A bispecific/CAR-T compound binding. HEK293 transduces efficiently with lentivirus and supports stable rescue line generation for CLEC12A-targeted compound testing.
* Research Use Disclaimer: Content is generated from publicly available research data, bioinformatic resources, and computational analyses for research reference only.

Related Publications

IF=4.9
International journal of molecular sciences
CLEC12A is a myeloid inhibitory receptor that negatively regulates inflammation in mouse models of autoimmune and autoinflammatory arthritis. Reduced CLEC12A expression enhances myeloid cell activation and inflammation in CLEC12A knock-out mice with collagen antibody-induced or gout-like arthritis. Similarly to other C-type lectin receptors, CLEC12A harbours a stalk domain between its ligand binding and transmembrane domains. While it is presumed that the cysteines in the stalk domain have multimerisation properties, their role in CLEC12A expression and/or signaling remain unknown. We thus used site-directed mutagenesis to determine whether the stalk domain cysteines play a role in CLEC12A expression, internalisation, oligomerisation, and/or signaling. Mutation of C118 blocks CLEC12A transport through the secretory pathway diminishing its cell-surface expression. In contrast, mutating C130 does not affect CLEC12A cell-surface expression but increases its oligomerisation, inducing ligand-independent phosphorylation of the receptor. Moreover, we provide evidence that CLEC12A dimerisation is regulated in a redox-dependent manner. We also show that antibody-induced CLEC12A cross-linking induces flotillin oligomerisation in insoluble membrane domains in which CLEC12A signals. Taken together, these data indicate that the stalk cysteines in CLEC12A differentially modulate this inhibitory receptor's expression, oligomerisation and signaling, suggestive of the regulation of CLEC12A in a redox-dependent manner during inflammation.
This KO model may be useful for: - Investigating the role of stalk region cysteine residues in regulating CLEC12A expression and oligomerisation - Elucidating the molecular mechanisms of CLEC12A-mediated inhibitory signaling - Functional studies of receptor maturation and post-translational modifications - Pathway analysis of immune checkpoint regulation in myeloid cells - Validation of therapeutic antibodies targeting CLEC12A

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