Date published: 2026-7-4

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ACSL4 Lentiviral Activation Particles (h): sc-401649-LAC

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Datasheets
  • Target species: human
  • 200 µl of transduction-ready, high-titer CRISPR/dCas9 Lentiviral Activation Particles
  • ACSL4 Lentiviral Activation Particles (h) is a synergistic activation mediator (SAM) transcription activation system designed to specifically and efficiently upregulate gene expression via lentiviral transduction of cells
  • ACSL4 Lentiviral Activation Particles (h) contain the following SAM Activation elements: a deactivated Cas9 (dCas9) nuclease (D10A and N863A) fused to the transactivation domain VP64, an MS2-p65-HSF1 fusion protein and a target-specific 20 nt guide RNA. They also contain the blasticidin, hygromycin and puromycin resistance genes
  • Upon transduction, the SAM complex binds to a site-specific region approximately 200-250 nt upstream of the transcriptional start site and provides robust recruitment of transcription factors for highly efficient gene activation
  • gRNAs encoded by ACSL4 Lentiviral Activation Plasmid (h) and ACSL4 Lentiviral Activation Plasmid (h2) target distinct regulatory regions of the ACSL4 promoter. One or both designs may be available
  • Following transfection, gene activation efficiency can be assayed by WB, IF or IHC using antibody: ACSL4 Antibody (F-4): sc-365230
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    Ordering Information

    Product NameCatalog #UNITPriceQtyFAVORITES

    ACSL4 Lentiviral Activation Particles (h)

    sc-401649-LAC
    200 µl
    $455.00

    ACSL4 (acyl-CoA synthetase long-chain family member 4) is a human acyl-CoA ligase that preferentially activates polyunsaturated fatty acids such as arachidonic acid, channeling them into phospholipid remodeling and lipid mediator biosynthesis. By shaping membrane phospholipid composition, ACSL4 influences ferroptosis sensitivity, oxidative stress responses, and eicosanoid-linked signaling, connecting lipid metabolism to regulated cell death and inflammatory programs. Dysregulated ACSL4 activity and expression have been associated with altered lipid peroxidation dynamics observed across cancer biology, neurodegeneration, and metabolic disease models, making it a relevant target for mechanistic studies of lipid-driven phenotypes. ACSL4 is therefore widely studied in pathways integrating fatty acid activation, membrane remodeling, and cell fate regulation.

    ACSL4 Lentiviral Activation Particles (h) address this need by packaging the complete synergistic activation mediator (SAM) transcriptional activation system into transduction-ready, high-titer lentiviral particles, enabling efficient ACSL4 upregulation across a broader range of human cell types.

    ACSL4 Lentiviral Activation Particles (h) deliver all functional components of the synergistic activation mediator (SAM) system via lentiviral transduction. The system comprises three particle preparations co-transduced into target cells: one encoding catalytically inactive dCas9 (D10A and N863A mutations) fused to the VP64 transactivation domain with a blasticidin resistance gene; one encoding the MS2-p65-HSF1 fusion protein with a hygromycin resistance gene; and one encoding a target-specific 20 nt sgRNA fused to two MS2 RNA aptamers with a puromycin resistance gene. Following lentiviral transduction and genomic integration of the expression cassettes, the SAM components are stably expressed and assemble at the target locus within the proximal promoter region upstream of the ACSL4 transcriptional start site, where VP64, p65, and HSF1 act cooperatively to recruit endogenous transcriptional machinery and drive sustained upregulation of endogenous ACSL4 expression. The use of nuclease-inactive dCas9 avoids the introduction of double-strand DNA breaks and preserves the native ACSL4 genomic locus and regulatory architecture.

    The lentiviral format offers several practical advantages: stable genomic integration supports heritable activation across cell divisions; high-titer particle preparations eliminate the need for in-house viral production; and compatibility with primary, non-dividing, and transfection-resistant cell types expands experimental accessibility. Successful transduction can be confirmed and enriched through triple antibiotic selection using puromycin, hygromycin, and blasticidin.

    For Research Use Only. Not Intended for Diagnostic or Therapeutic Use.