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Application Area

Ac-beta-chloro-D-Ala-Ome

* Please kindly note that our products are not to be used for therapeutic purposes and cannot be sold to patients.

Category

D-Amino Acids

Catalog number

BAT-008687

CAS number

327064-63-1

Molecular Formula

C6H10ClNO3

Molecular Weight

179.6

Specification
Application

IUPAC Name

methyl (2S)-2-acetamido-3-chloropropanoate; (S)-methyl 2-(acetylamino)-3-chloropropionate

Synonyms

Ac-D-Ala(Cl)-Ome; Ac beta chloro D Ala Ome

Ac-beta-chloro-D-Ala-Ome, a derivative of D-alanine, boasts a myriad of captivating applications in bioscience and its related domains. Here are the key applications of Ac-beta-chloro-D-Ala-Ome, presented with high perplexity and burstiness:

Antibacterial Research: Serving as a potent research tool, Ac-beta-chloro-D-Ala-Ome plays a pivotal role in unraveling the intricacies of bacterial cell wall synthesis. By integrating this analogue into bacterial growth media, scientists delve deep into the mechanisms governing peptidoglycan assembly and explore how modifications impact bacterial viability. This profound knowledge lays the foundation for the development of novel antibiotics targeting resilient bacterial strains.

Enzyme Inhibition Studies: This unique compound serves as a cornerstone in the investigation of bacterial enzyme inhibition, particularly those involved in cell wall biosynthesis like D-Ala-D-Ala ligase. Researchers harness Ac-beta-chloro-D-Ala-Ome to pinpoint and characterize enzyme inhibitors, facilitating the creation of antimicrobial agents. These detailed studies unveil fresh therapeutic targets for combatting bacterial infections, pushing the boundaries of antimicrobial research.

Biochemical Pathway Analysis: Delving into microbial systems, Ac-beta-chloro-D-Ala-Ome acts as a catalyst for probing diverse biochemical pathways. By introducing this compound into experimental setups, scientists track its impact on metabolic processes and cellular responses, shedding light on bacterial adaptation to environmental stresses and antimicrobial agents. This application aids in deciphering the intricate dance of bacteria in response to external stimuli, deepening our understanding of microbial resilience.

Antimicrobial Resistance Studies: An indispensable asset in antimicrobial resistance research, this derivative plays a critical role in unraveling the mechanisms underlying resistance development. Through exposure of bacterial cultures to Ac-beta-chloro-D-Ala-Ome, researchers witness firsthand the evolution of resistance and pinpoint genetic mutations conferring resilience. These invaluable insights pave the way for strategic interventions to combat the proliferation of resistant pathogens and optimize the use of antibiotics, safeguarding public health on a global scale.