Bacilysin, scientifically recognized by its CAS number 1395-22-8, is a compound that bridges the gap between natural microbial processes and advanced scientific research. As a metabolite produced by the bacterium Bacillus subtilis, it plays an intrinsic role in the microorganism's life cycle. Simultaneously, its distinct antibacterial properties position it as an invaluable research chemical, sought after for its potential in combating bacterial infections and understanding complex biochemical pathways.

The significance of Bacilysin as a metabolite lies in its production by Bacillus subtilis, a well-studied organism in microbiology. This dipeptide antibiotic is part of the organism's secondary metabolic arsenal, often produced under specific environmental conditions. Scientists study these metabolites to understand how microbes interact with their environment and each other, and how these natural compounds can be harnessed for human benefit. The ability to buy Bacilysin for research allows for direct investigation into these microbial strategies.

Furthermore, Bacilysin's primary mode of action – inhibiting glucosamine 6-phosphate synthase – makes it a potent tool for researchers. This specific enzyme is crucial for bacterial cell wall synthesis. By targeting this pathway, Bacilysin offers a clear mechanism for antibacterial activity that can be explored in drug discovery. Pharmaceutical companies and academic labs often utilize such well-characterized compounds to validate new research hypotheses or as starting points for developing more potent analogs. The chemical profile of Bacilysin, with its molecular formula C12H18N2O5 and molecular weight of 270.283, is well-documented, facilitating its integration into complex experimental designs.

The availability of Bacilysin from reliable manufacturers, particularly those in China, has democratized its use in laboratories worldwide. Whether for studying microbial ecology, screening for new antibacterial agents, or understanding enzyme kinetics, Bacilysin CAS 1395-22-8 provides a consistent and scientifically validated resource. Its dual nature as a natural metabolite and a targeted research chemical underscores its importance in both fundamental and applied scientific endeavors.