L-Lysine-[15N2] Dihydrochloride, an isotopically labeled variant of the essential amino acid lysine, finds extensive use in both research and industrial sectors. Dive into key applications of L-Lysine-[15N2] Dihydrochloride intricately presented with a high level of perplexity and burstiness:
Protein Metabolism Studies: Pioneering the exploration of protein synthesis and metabolism, L-Lysine-[15N2] Dihydrochloride emerges as a pivotal instrument. By incorporating this isotope-enriched lysine into proteins, scientists embark on a meticulous journey to monitor and quantify protein turnover and degradation rates. This nuanced technique unravels deep insights into metabolic states and disorders like muscle wasting through a comprehensive analysis of protein dynamics.
Stable Isotope Tracing: Within the vast expanse of metabolic research, L-Lysine-[15N2] Dihydrochloride plays a critical role as a tracing agent for nitrogen metabolic pathways. Researchers harness this compound to trace nitrogen flux across various biological processes, shedding light on amino acid utilization and nitrogen equilibrium. These revelations are paramount for delving into nutrition physiology and unraveling the complexities of disease metabolism.
Nutritional Studies: Embedded in the realm of nutritional inquiries, L-Lysine-[15N2] Dihydrochloride assists in evaluating lysine requirements and bioavailability across diverse dietary regimens. By monitoring the enrichment levels of 15N in organic samples, scientists gauge the efficiency of protein utilization and dietary lysine assimilation. These studies form the cornerstone for shaping nutritional guidelines and assessing the quality of dietary proteins.
Industrial Protein Production: Embraced within the biotechnological landscape, L-Lysine-[15N2] Dihydrochloride emerges as a crucial supplement in the production of isotope-tagged proteins for structural biology investigations. These tagged proteins play a pivotal role in techniques like nuclear magnetic resonance (NMR) spectroscopy and mass spectrometry, enabling a deeper understanding of protein architecture and functionalities. Such applications drive advancements in drug discovery and enrich the comprehension of intricate protein-protein interactions, propelling scientific boundaries forward.
![L-Lysine-[15N2] Dihydrochloride](/isotope.v1/images/structure-default.jpg)
