FAIM Antibodies

FAIM (Fas Apoptotic Inhibitory Molecule) is a protein involved in apoptosis regulation, specifically inhibiting the Fas-mediated apoptotic pathway. It plays a critical role in protecting cells from Fas-induced cell death, especially in immune cells like B cells and neurons. The FAIM protein has two isoforms: FAIM-L (long) and FAIM-S (short), which display distinct roles in immune response modulation and neuronal survival.

Content

FAIM antibodies are developed to specifically bind to FAIM proteins for their detection, quantification, and study in various biological processes. These antibodies can be monoclonal or polyclonal, and they are highly useful in immunohistochemistry (IHC), Western blotting, immunoprecipitation (IP), and flow cytometry to investigate FAIM expression patterns. These antibodies provide insights into the molecular pathways that protect cells from apoptosis, making them valuable tools for research in immunology, cancer, and neurobiology.

Applications

• Apoptosis Research: FAIM antibodies are crucial in studying apoptotic signaling pathways, particularly in understanding how cells resist Fas-induced apoptosis. This is critical for researching autoimmune diseases, neurodegenerative conditions, and cancer, where dysregulated apoptosis plays a key role.
• Cancer Studies: The modulation of FAIM expression is linked to tumorigenesis. FAIM antibodies are used to study the relationship between apoptosis resistance and cancer cell survival, especially in tumors where the Fas pathway is deregulated.
• Immunology: FAIM is important in B cell differentiation and survival. FAIM antibodies allow for the detailed analysis of immune responses, including the understanding of how B cells evade apoptosis during immune reactions, providing insights into autoimmune disorders.
• Neurobiology: FAIM has a protective role in neurons, particularly under stress conditions. Antibodies against FAIM are used to explore its function in preventing neuronal apoptosis, with potential implications in neurodegenerative diseases like Alzheimer's and Parkinson's.

By employing FAIM antibodies in experimental setups, researchers can dissect the precise molecular mechanisms underlying apoptosis inhibition, offering a deeper understanding of cellular protection mechanisms across different biological contexts.