53BP1(Phospho-Ser1778) Rabbit Polyclonal Antibody

53BP1(Phospho-Ser1778) Rabbit Polyclonal Antibody

Introducing the 53BP1(Phospho-Ser1778) Rabbit Polyclonal Antibody, a highly specialized and meticulously crafted product designed to cater to the discerning needs of the scientific community. This antibody, derived from rabbit polyclonal sources, exhibits exceptional specificity and sensitivity, making it an invaluable tool for researchers in the field.

The 53BP1(Phospho-Ser1778) Rabbit Polyclonal Antibody has been meticulously developed to target the phosphorylated serine 1778 residue of the 53BP1 protein. This phosphorylation event plays a crucial role in various cellular processes, including DNA damage response and repair mechanisms. By specifically recognizing and binding to this phosphorylated site, this antibody enables researchers to investigate and elucidate the intricate molecular pathways involved in these fundamental biological processes.

With its superior specificity, this antibody ensures minimal cross-reactivity with non-phosphorylated forms of 53BP1, thereby providing accurate and reliable results. Its exceptional sensitivity allows for the detection of even low levels of phosphorylated 53BP1, facilitating precise quantification and analysis.

The 53BP1(Phospho-Ser1778) Rabbit Polyclonal Antibody has undergone rigorous quality control measures to ensure optimal performance and consistency. Each batch is meticulously tested to guarantee batch-to-batch reproducibility, ensuring reliable and consistent results across experiments.

This antibody is supplied in a convenient and user-friendly format, allowing for easy integration into various experimental protocols. Its versatility enables its utilization in a wide range of applications, including immunohistochemistry, immunofluorescence, and Western blotting.

In summary, the 53BP1(Phospho-Ser1778) Rabbit Polyclonal Antibody stands as a testament to our commitment to providing cutting-edge research tools to the scientific community. Its exceptional specificity, sensitivity, and reliability make it an indispensable asset for researchers seeking to unravel the complexities of DNA damage response and repair mechanisms.