



Ordering Information
| Product Name | Catalog # | UNIT | Price | Qty | FAVORITES | |
ACADS Double Nickase Plasmid (h) | sc-405458-NIC | 20 µg | $410.00 | |||
ACADS Double Nickase Plasmid (h2) | sc-405458-NIC-2 | 20 µg | $410.00 |
ACADS encodes short-chain acyl-CoA dehydrogenase, a mitochondrial flavoprotein that catalyzes the initial dehydrogenation step in β-oxidation of short-chain fatty acyl-CoAs, linking fatty acid catabolism to energy production during fasting and metabolic stress. By transferring electrons to the electron transfer flavoprotein system and downstream respiratory chain components, ACADS supports mitochondrial redox balance and efficient flux through fatty acid oxidation pathways. Altered ACADS function is associated with impaired short-chain fatty acid oxidation, metabolic acidosis, and neuromuscular symptoms observed in short-chain acyl-CoA dehydrogenase deficiency, making it relevant to studies of inborn errors of metabolism. ACADS also provides a useful node for investigating mitochondrial metabolism, oxidative stress responses, and lipid-derived signaling in human cells.
ACADS Double Nickase Plasmid (h) consists of a matched pair of plasmids engineered for high-specificity editing of the ACADS locus in human cell lines. Each plasmid expresses a Cas9 D10A nickase and a distinct sgRNA targeting opposite DNA strands within ACADS. When directed to adjacent sites on opposite DNA strands, the two nickases generate offset single-strand nicks that together produce a staggered double-strand break, requiring coordinated on-target activity from both guides. The resulting DNA break is resolved by endogenous cellular repair pathways, most commonly through non-homologous end joining (NHEJ), leading to insertions or deletions that disrupt ACADS function. By requiring dual sgRNA engagement at the target locus, the double nicking approach enhances editing specificity and provides a complementary CRISPR strategy for applications where additional control over targeting precision is desired.
To support efficient identification of edited cells, one plasmid encodes GFP for fluorescent visualization of transfected populations, while the companion plasmid carries a puromycin resistance gene for antibiotic selection. Together, these features support efficient enrichment of co-transfected populations and simplify the validation of ACADS-disrupted clones.
For Research Use Only. Not Intended for Diagnostic or Therapeutic Use.