AffiAB® Goat Anti-Rab9 Polyclonal IgG Antibody
- 3 to 5 Days Shipment
- 600 µg
- 3 mg/ml
AffiAB® Goat Anti-Rab9 Polyclonal IgG Antibody is a high-quality antibody ideal for the detection and quantification of Rab9 proteins. This antibody provides a reliable and reproducible way to analyze Rab9 in various cell types and tissues.
The AffiAB® Goat Anti-Rab9 Polyclonal IgG Antibody is an antibody specifically designed to target and bind to the Rab9 protein. Rab9 is a small GTPase that plays a crucial role in regulating intracellular vesicle trafficking and protein transport between the trans-Golgi network (TGN) and late endosomes.
This polyclonal antibody is generated by immunizing goats with purified Rab9 protein or a specific peptide derived from Rab9. The resulting antibodies are then purified from the goat serum to ensure high specificity and quality.
The AffiAB® Goat Anti-Rab9 Polyclonal IgG Antibody is widely used in research to investigate the expression, localization, and function of Rab9 in various cellular processes. By specifically detecting and visualizing Rab9, researchers can gain insights into its role in vesicle trafficking, protein sorting, and the maintenance of organelle integrity.
Researchers utilize techniques such as immunoblotting, immunofluorescence, immunohistochemistry, and immunoprecipitation using this antibody to analyze Rab9 protein expression, subcellular localization, and interactions with other proteins or cellular components.
It is important to note that the AffiAB® Goat Anti-Rab9 Polyclonal IgG Antibody is specifically designed to recognize Rab9 and may not cross-react with other Rab proteins or related molecules. Researchers should validate the antibody's performance and specificity in their specific experimental conditions by conducting appropriate controls and assays.
In summary, the AffiAB® Goat Anti-Rab9 Polyclonal IgG Antibody is a valuable tool for studying the expression, localization, and function of Rab9 in various cellular processes. By specifically detecting Rab9, researchers can further our understanding of vesicle trafficking, protein transport, and organelle dynamics, contributing to fields such as cell biology, molecular biology, and immunology.