Abcam, ab291074, Anti-Kir6.2/BIR antibody [EPR25229-115]

Size: 20µL / 100µL / 1mL
Rabbit Recombinant Monoclonal Kir6.2/BIR antibody. Suitable for IHC-P and reacts with Rat, Mouse samples.
Key facts
Host species:Rabbit,
Clonality:Monoclonal,
Clone number:EPR25229-115,
Isotype:IgG,
Carrier free:No,
Reacts with:Mouse, Rat,
Applications:IHC-PSee reactivity dataSee the reactivity data table below for information on validated species and application combinations.,
Immunogen:The exact immunogen used to generate this antibody is proprietary information.

Product details:
Patented technology
Our RabMAb
technology is a patented hybridoma-based technology for making rabbit monoclonal antibodies. For details on our patents, please refer to
RabMAb® patents
What are the advantages of a recombinant monoclonal antibody?
This product is a recombinant monoclonal antibody, which offers several advantages including:
- High batch-to-batch consistency and reproducibility
- Improved sensitivity and specificity
- Long-term security of supply
- Animal-free batch production
For more information, read more on
recombinant antibodies

Properties and Storage Information:
Form-Liquid, Purification technique-Affinity purification Protein A, Storage buffer-pH: 7.2 - 7.4Preservative: 0.01% Sodium azideConstituents: PBS, 40% Glycerol (glycerin, glycerine), 0.05% BSA, Shipped at conditions-Blue Ice, Appropriate short-term storage duration-1-2 weeks, Appropriate short-term storage conditions-+4°C, Appropriate long-term storage conditions--20°C, Aliquoting information-Upon delivery aliquot, Storage information-Avoid freeze / thaw cycle

Supplementary Information:
This supplementary information is collated from multiple sources and compiled automatically.
Kir6.2 also known by alternate names KCNJ11 and 2BIR is part of the ATP-sensitive potassium channel (K-ATP channel) complex specifically the pore-forming subunit. This protein has a molecular mass of approximately 43 kDa. Expression of Kir6.2 occurs in various tissues most notably in pancreatic beta cells cardiac muscle and neuronal tissues. These channels play an important role in cell membrane potential regulation and excitability modulating insulin release and muscle contraction by responding to intracellular levels of ATP and ADP.
Biological function summary
Kir6.2 functions by coupling cellular metabolic states to electrical activity via its role in the K-ATP channel complex. This complex integrates Kir6.2 with the sulfonylurea receptor SUR1 or SUR2 forming an important connection between cellular metabolism and membrane excitability. Kir6.2 helps manage glucose-induced insulin secretion in pancreatic beta cells contributing to the temporal burst of insulin after meals. Its function in neurons and muscle fibers includes balancing cellular energy levels and physiological processes such as neurotransmitter release and muscle contraction.
Pathways
Kir6.2 plays a significant role in insulin secretion and cardiac muscle contraction pathways. It interacts closely with various proteins including SUR1 in the insulin release pathway and SUR2 in cardiovascular regulation. The activity of Kir6.2 links it with processes such as glucose-stimulated insulin secretion where its modulation significantly impacts the entry of calcium ions through voltage-dependent calcium channels further altering the exocytosis of insulin granules. The reactivity to intracellular ATP levels means Kir6.2 acts as a metabolic sensor influencing these pathways accordingly.
Kir6.2 is linked to conditions such as neonatal diabetes mellitus and congenital hyperinsulinism. Mutations in the gene encoding Kir6.2 can disrupt normal K-ATP channel functioning leading to these diseases. In neonatal diabetes Kir6.2 alterations impair insulin secretion due to disrupted ATP binding or channel closure while in congenital hyperinsulinism dysfunction of Kir6.2 in hyperactive channels results in excessive insulin production. This exposes strong connections with proteins like insulin within these conditions highlighting its important influence on glucose metabolism and energy homeostasis.