Abcam, ab109720, Complex I Enzyme Activity Dipstick Assay Kit

Size: 48Test
Complex I Enzyme Activity Dipstick Assay Kit is a dipstick assay designed to measure Complex I (mitochondria) activity in human, mouse, rat and bovine samples. - 48 tests format - Activity assay not sensitive to retonone for more specificity and simplicity - Read on dipstick reader - use of standard imaging system also possible
Key facts
Sample types:Cell culture extracts, Tissue, Cell culture supernatant,
Reacts with:Mouse, Rat, Cow, Human,
Assay type:Enzyme activity,
Assay Platform:Reagents

Product details:
Contains 48 dipsticks and necessary components to quantify the activity of the Complex I enzyme complex in human, bovine, rat and mouse samples. The kit includes sufficient materials to generate a standard curve and evaluate several unknown samples.
In this assay the specificity of anti-Complex I monoclonal antibodies (mAbs) is combined with the well-characterized Complex I in-gel activity assay that is not rotenone sensitive. First, Complex I is immunocaptured (i.e. immuno-precipitated in active form) on the dipstick. Second, the dipstick is immersed in Complex I activity buffer solution containing NADH as a substrate and nitrotetrazolium blue (NBT) as the electron acceptor. Immunocaptured Complex I oxidizes NADH and the resulting H+ reduces NBT to form a blue-purple precipitate at the Complex I antibody line on the dipstick. The signal intensity of this precipitate corresponds to the level of Complex I enzyme activity in the sample. Combined with dipstick assay kit for measuring Complex I quantity (
ab109722
/MS131 for human sample;
ab109875
/MS133 for rodent samples), it is possible to determine the relative specific activity of immunocaptured Complex I. The signal intensity is best measured by a dipstick reader or may be analyzed by a standard imaging system.

Properties and Storage Information:
Shipped at conditions-Blue Ice, Appropriate short-term storage conditions-+4°C, Appropriate long-term storage conditions-+4°C, Storage information-+4°C

Supplementary Information:
This supplementary information is collated from multiple sources and compiled automatically.
Complex I also known as NADH dehydrogenase or NADH:ubiquinone oxidoreductase is a large enzyme complex with a molecular mass of approximately 1000 kDa. It is expressed in the inner mitochondrial membrane of eukaryotic cells. As the first enzyme in the mitochondrial respiratory chain Complex I plays a critical mechanical role in cellular respiration. It transfers electrons from NADH to ubiquinone coupled with the translocation of protons across the inner mitochondrial membrane contributing to the generation of a proton gradient used to produce ATP.
Biological function summary
Complex I acts as an integral component of the mitochondrial respiratory chain which is a series of protein complexes involved in cellular energy production. As part of this complex system Complex I is essential for effective oxidative phosphorylation. Its activity is assessed using protein activity assays including immunocapture or complex activity assays and microplate assays. Complex I activity influences the overall efficiency of ATP production affecting energy-dependent cellular processes.
Pathways
Complex I functions within the electron transport chain one of the major pathways in cellular respiration. This pathway is vital for ATP synthesis providing the energy currency required by cells. Complex I works closely with other electron transport chain complexes such as Complex II (succinate dehydrogenase complex) and Complex III (cytochrome c reductase) to drive oxidation-reduction reactions and maintain cellular metabolism.
Defects in Complex I are linked with mitochondrial diseases and neurodegenerative disorders such as Leigh syndrome and Parkinson's disease. Mutations in Complex I subunits disrupt normal electron transport and ATP production leading to increased oxidative stress and neuronal cell damage. Other mitochondrial proteins such as cytochrome c oxidase are also implicated in these conditions emphasizing the interconnected nature of mitochondrial dysfunction in disease progression.