The Biotinylated Anti-DNAM1 Antibody (HDLA058) is a key tool for researchers studying DNAM1, a cell surface receptor involved in the immune response and immune cell activation. This antibody is produced using advanced biotinylation technology, allowing for easy detection and analysis of DNAM1 in a variety of samples.The anti-DNAM1 antibody is raised in rabbits and has been validated for use in applications such as immunofluorescence, flow cytometry, and immunohistochemistry. It specifically binds to DNAM1, enabling researchers to accurately assess its expression and localization in different cell types and tissues.
DNAM1 is a critical molecule in immune surveillance, adhesion, and cytotoxicity, making it a valuable target for studies in immunology, cancer biology, and infectious diseases. By using the Biotinylated Anti-DNAM1 Antibody, researchers can gain insights into the role of DNAM1 in various physiological and pathological processes, ultimately advancing our understanding of immune regulation and potential therapeutic interventions.
SKU:
HDLA058
Size:
100 µg
Clonality:
Monoclonal
Clone:
DM96
Synonyms:
DNAM1, CD226, PTA1
Applications:
ELISA, Flow Cyt
Recommended Dilution:
ELISA 1:5000-10000; Flow Cyt 1:100
Host Species:
Rabbit
Isotype:
Rabbit IgG
Reactivity:
Human
Purification Method:
Purified from cell culture supernatant by affinity chromatography
Formulation:
Powder
Buffer:
1XPBS
Storage:
Store at -20°C to -80°C for 12 months in lyophilized form. After reconstitution, if not intended for use within a month, aliquot and store at -80°C (Avoid repeated freezing and thawing).Lyophilized antibodies are shipped at ambient temperature.
Usage:
Research use only
Background:
This gene encodes a glycoprotein expressed on the surface of NK cells, platelets, monocytes and a subset of T cells. It is a member of the Ig-superfamily containing 2 Ig-like domains of the V-set. The protein mediates cellular adhesion of platelets and megakaryocytic cells to vascular endothelial cells. The protein also plays a role in megakaryocytic cell maturation. Alternative splicing results in multiple transcript variants.
