AMPM1 Polyclonal Antibody

Catalytic activity:Release of N-terminal amino acids, preferentially methionine, from peptides and arylamides.,cofactor:Binds 1 sodium ion per subunit. The sodium ion has a structural role.,cofactor:Binds 2 cobalt ions per subunit.,cofactor:Binds 2 cobalt ions per subunit. The true nature of the physiological cofactor is under debate. The enzyme is also active with zinc, manganese or divalent iron ions.,Removes the amino-terminal methionine from nascent proteins.,Removes the amino-terminal methionine from nascent proteins. Required for normal progression through the cell cycle.,Belongs to the peptidase M24A family.,

The AMPM1 Polyclonal Antibody is a highly specific and reliable tool designed for the detection and analysis of AMPM1 protein expression in various biological samples. This antibody is produced through a rigorous process, ensuring its high affinity and sensitivity towards AMPM1. With its exceptional performance, this antibody is suitable for a wide range of applications, including Western blotting, immunohistochemistry, and immunofluorescence.

The AMPM1 Polyclonal Antibody exhibits excellent specificity, displaying minimal cross-reactivity with other proteins, thus enabling accurate and precise results. Its robustness and consistency make it an ideal choice for researchers and scientists working in the fields of molecular biology, biochemistry, and cell biology.

This antibody is supplied in a convenient and ready-to-use format, allowing for easy and efficient experimentation. Its long shelf life and stability ensure reliable and reproducible results over an extended period. Additionally, the AMPM1 Polyclonal Antibody is available in various sizes to accommodate different experimental needs.

In summary, the AMPM1 Polyclonal Antibody is a superior quality reagent that guarantees exceptional performance and reliability in the detection and analysis of AMPM1 protein expression. Its specificity, convenience, and versatility make it an indispensable tool for researchers aiming to unravel the intricate mechanisms underlying AMPM1-related processes.