Git5 Recombinant Protein: A Powerful Tool for Functional and Mechanistic Studies


The Schizosaccharomyces pombe protein git5, expressed recombinantly (git5 recombinant, SKU: GEN000105035 ), presents a valuable tool for researchers investigating cellular processes in yeasts and potentially other eukaryotic organisms. Recombinant protein technology allows for the controlled production of highly purified proteins, offering significant advantages over their native counterparts isolated from complex cellular environments.

git5 Recombinant

Key Advantages of git5 Recombinant:

 Targeted Functionality: git5 recombinant is likely engineered to possess a specific function or bind to a particular molecule within the cell. This targeted functionality allows researchers to dissect specific cellular pathways with greater precision. Depending on its function, git5 recombinant could be used to:

Activate or inhibit specific signaling cascades.
Modulate protein-protein interactions.
Probe the function of specific cellular compartments.

High Purity: Recombinant proteins like git5 are typically subjected to rigorous purification procedures, minimizing contamination from other cellular components. This enhanced purity ensures that the observed effects in experiments are specifically due to git5's activity, leading to more reliable data and a clearer understanding of its role in the cell.

 Controlled Expression:  Genetic engineering techniques allow researchers to control the production and modification of git5 recombinant. This enables the creation of:

  • Mutant variants with altered properties to dissect the structure-function relationship of the protein.
  • Fusion proteins containing tags for easy detection, purification, or localization within the cell.
  • Isotope-labeled versions for structural analysis techniques like X-ray crystallography or mass spectrometry.
  •  The Git5 Gb and git11 Gg Form an Atypical Gbg Dimer Acting in the Fission Yeast Glucose/ cAMP Pathway

Applications of git5 Recombinant:

 The specific applications of git5 recombinant will depend on its known or predicted function. However, some potential applications include:

  • In vitro assays: Studying the enzymatic activity or binding properties of git5 with its target molecules.
  • Cellular assays: Investigating the impact of git5 overexpression or depletion on various cellular processes.
  • Protein-protein interaction studies: Identifying and characterizing potential binding partners of git5 using techniques like co-immunoprecipitation or mass spectrometry.


git5 recombinant offers a powerful tool for researchers in the field of cell biology. Its targeted functionality, high purity, and controlled expression capabilities make it valuable for dissecting cellular processes, elucidating protein function, and ultimately advancing our understanding of the intricate workings of the cell.