S-P-MEBZ-L-Cysteine-[15N]

S-P-MEBZ-L-Cysteine-[15N], a stable isotope-labeled amino acid, finds extensive utility in both research and industrial settings. Here are key applications of S-P-MEBZ-L-Cysteine-[15N] explored with high perplexity and burstiness:

Proteomics Research: Delving into the realm of mass spectrometry-based proteomics, researchers harness S-P-MEBZ-L-Cysteine-[15N] to probe protein dynamics, structure, and function. By integrating this labeled amino acid into proteins, scientists can quantitatively examine protein turnover and post-translational modifications. This detailed analysis yields precise insights into protein biosynthesis and degradation, shedding light on intricate cellular processes and disease etiology.

Metabolic Flux Analysis: Within the domain of metabolic studies, the use of this labeled cysteine variant is indispensable for mapping sulfur metabolism pathways in diverse organisms. Researchers employ it to track the assimilation and conversion of sulfur into various metabolic products, offering valuable insights into metabolic efficiency and adaptive responses. This knowledge aids in optimizing metabolic pathways for biotechnological applications and unraveling disorders associated with sulfur metabolism.

Environmental and Isotope Studies: In the realm of environmental science, S-P-MEBZ-L-Cysteine-[15N] serves as a valuable tool for unraveling nitrogen and sulfur cycling dynamics within ecosystems. Its integration into organisms enables scientists to trace and quantify nitrogen flow, investigate nutrient assimilation processes, and evaluate ecosystem health. This application is instrumental in ecological research, helping in the assessment of environmental impacts, changes, and pollution effects on ecosystems.

Pharmaceutical Development: Playing a pivotal role in drug research and development, this stable isotope-labeled compound facilitates the exploration of drug metabolism and pharmacokinetics. By monitoring its integration into target tissues or proteins, researchers gain intricate insights into drug absorption, distribution, metabolism, and excretion patterns. This comprehensive understanding aids in designing more efficacious drugs with optimized therapeutic properties, shaping the landscape of pharmaceutical innovation.