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As an essential amino acid, leucine has a big impact on human health and a lot of industrial uses. It is a branched-chain amino acids (BCAAs) that is considered essential because the body is unable to synthesis it and has to get it from food. Its primary role lies in protein synthesis, where it serves as a key regulator of muscle growth and repair. Beyond its biological functions, leucine's unique properties have led to its extensive use in pharmaceuticals, biotechnology, and materials science.
Leucine is one of the three essential BCAAs, a category of amino acids that also includes isoleucine and valine. It plays a crucial role in various physiological processes and has wide-ranging applications across different industries. It has numerous applications in a variety of industries and is essential to many physiological functions. Leucine is an important amino acid that the body cannot produce on its own; it needs to come from food. This makes it a critical component for maintaining overall health and well-being. In the biochemical context, leucine's significance extends beyond its basic role in protein synthesis. It has been recognized for its involvement in metabolic pathways that affect muscle growth, tissue repair, and energy production. This makes leucine a valuable nutrient in fields ranging from sports nutrition to clinical applications.
The chemical formula of Leucine is C₆H₁₁NO₂ and its molecular weight is 131.17 g/mol. It is classified as a non-polar, aliphatic amino acid. Its chemical structure includes an α-amino group, an α-carboxylic acid group, and a unique side chain. The side chain is an isobutyl group, which distinguishes leucine from other amino acids. The presence of the branched side chain allows leucine to be metabolized differently than other amino acids. It is primarily metabolized in muscle tissue rather than the liver, which impacts its role in energy production and muscle protein synthesis.
Fig. 1. Structure of leucine amino acid.
Leucine is a vital BCAA that is important for many physiological processes and has several health advantages. Leucine is one of the nine necessary amino acids that the body cannot produce on its own; instead, it must come from food sources including meat, dairy, and legumes. Its primary physiological function is to promote muscle protein synthesis, making it vital for muscle growth, repair, and maintenance.
In addition to natural leucine, unnatural leucine or synthetic leucine has attracted much attention due to its role in medical and research applications. Unlike naturally derived leucine, which the body assimilates through food, non-natural leucine is produced through chemical synthesis processes. This synthetic form is especially useful in studying metabolic disorders and muscle degenerative diseases due to its predictable and consistent properties. Researchers utilize non-natural leucine to explore various metabolic pathways, understanding its involvement in protein synthesis and muscle degradation.
L-Leucine is an essential amino acid crucial for protein biosynthesis. This α-amino acid contains a protonated α-amino group, a deprotonated α-carboxylic acid group, and a non-polar isobutyl side chain. As an essential nutrient, it cannot be synthesized by the human body and must be obtained from dietary sources such as meat, dairy, soy products, and legumes. L-Leucine plays a significant role in muscle protein synthesis by activating the mTOR pathway, making it a popular supplement among athletes and bodybuilders. While L-Leucine is naturally occurring, synthetic non-natural L-Leucine finds applications in medical research to explore protein metabolism and potential therapeutic effects for muscle-wasting conditions.
| Name | CAS | Catalog | Price |
| Phthaloyl-L-Leucine | 2419-38-7 | BAT-003457 | Inquiry |
| L-Leucine amide | 687-51-4 | BAT-003991 | Inquiry |
| Acetyl-L-leucine | 1188-21-2 | BAT-003868 | Inquiry |
| Boc-L-leucine methyl ester | 63096-02-6 | BAT-002792 | Inquiry |
| Z-N-methyl-L-leucine | 33099-08-0 | BAT-003399 | Inquiry |
| Z-L-leucine | 2018-66-8 | BAT-003356 | Inquiry |
D-Leucine is the enantiomer of L-Leucine, consisting of the same molecular structure but with a different spatial arrangement. Unlike L-Leucine, D-Leucine is not commonly found in nature and is primarily synthesized for research and potential therapeutic applications. Both D-Leucine and its natural counterpart have been shown to protect against epileptic seizures in animal studies. Remarkably, D-Leucine can terminate seizure activity without the sedative effects characteristic of traditional medications like diazepam. This unique property positions D-Leucine as a promising candidate for developing novel antiepileptic therapies. Additionally, its role in studying protein folding and stability highlights its significance beyond natural biology, extending into advanced biochemical research.
| Name | CAS | Catalog | Price |
| N-α-Formyl-D-leucine | 44978-39-4 | BAT-006018 | Inquiry |
| Acetyl-D-leucine | 19764-30-8 | BAT-003463 | Inquiry |
| D-Leucine amide | 15893-47-7 | BAT-003527 | Inquiry |
| Fmoc-D-leucine | 114360-54-2 | BAT-003641 | Inquiry |
| Boc-N-methyl-D-leucine | 89536-84-5 | BAT-002827 | Inquiry |
| Z-D-leucine | 28862-79-5 | BAT-003295 | Inquiry |
As an essential amino acid, leucine cannot be synthesized by the human body and must be obtained from external sources. The availability of leucine in various forms-from dietary sources to biosynthetic and chemical production-ensures that individuals can meet their physiological needs and leverage its benefits for health and performance. Understanding these sources is crucial for optimizing dietary intake, supporting clinical applications, and advancing scientific research.
Leucine comes from a variety of dietary sources, including animal and plant proteins. Animal protein sources including meat, poultry, fish, eggs, and dairy products are rich sources of leucine. These foods provide high-quality protein containing all the essential amino acids, including leucine. Plant protein sources including soy products, beans, and nuts are important plant sources of leucine.
Leucine is synthesized in the human body through a series of biochemical processes that convert precursor molecules into leucine. The biosynthesis of leucine primarily involves the transamination of pyruvate and α-ketoglutarate, two key intermediates in the amino acid metabolism. In this process, the enzyme branched-chain aminotransferase (BCAT) facilitates the transfer of an amino group from α-ketoglutarate to pyruvate, producing leucine. This biosynthetic pathway occurs mainly in the liver and muscle tissues. The ability to synthesize leucine from these precursors is crucial for maintaining adequate levels of this amino acid, particularly in conditions where dietary intake might be insufficient. However, the body's capacity to synthesize leucine is limited, making it essential to obtain it from dietary sources to ensure optimal physiological function and health.
Chemical synthesis of leucine and its derivatives plays a significant role in research and industry. Leucine can be synthesized in the laboratory through various chemical reactions that mimic natural biosynthetic processes. This involves the use of starting materials such as α-ketoisovalerate and ammonia, which are chemically transformed into leucine through a series of steps that include reduction and condensation reactions. Additionally, non-natural leucine derivatives, such as leucine analogues, can be produced chemically to explore their unique properties and potential applications. These derivatives are often used in biochemical research to study their effects on protein synthesis, enzyme activity, and metabolic pathways. Chemical synthesis ensures a controlled and reproducible supply of leucine and its analogues for use in pharmaceuticals, supplements, and scientific research, contributing to advancements in various fields of study.
Beyond its well-known benefits in muscle protein synthesis and metabolic regulation, leucine, particularly its non-natural derivatives, has found significant applications in research, pharmaceuticals, and industrial processes. These applications highlight the versatility and importance of leucine in advancing health, enhancing performance, and supporting technological innovations.
In the sports and nutrition industry, leucine is widely used in dietary supplements aimed at improving muscle growth, recovery, and exercise performance. Its role in activating the mechanistic target of rapamycin (mTOR) pathway makes it a key ingredient in many protein powders, pre-workout supplements, and post-workout recovery formulations. Leucine supplements are designed to promote muscle protein synthesis, reduce muscle breakdown, and enhance overall exercise outcomes. For example, products containing leucine, such as BCAA supplements, are popular among athletes and bodybuilders seeking to optimize their training results and recovery.
In clinical settings, leucine and its analogues have been explored for their therapeutic potential in managing various health conditions. Non-natural leucine derivatives, such as β-hydroxy β-methylbutyrate (HMB), have shown promise in treating muscle-wasting diseases, including cachexia associated with cancer and chronic obstructive pulmonary disease (COPD). HMB, derived from leucine, is used to prevent muscle loss and improve muscle mass in patients undergoing severe physical stress or illness. Additionally, leucine's impact on metabolic pathways has led to its investigation in managing type 2 diabetes and obesity, where it aids in regulating blood sugar levels and improving metabolic health.
One of the most significant applications of non-natural leucine is in the pharmaceutical industry. D-Leucine's unique properties make it a valuable tool in drug development and formulation. For instance, D-Leucine can be used to create chiral pharmaceuticals where the enantiomeric form can influence the drug's efficacy and safety profile. The ability to use D-Leucine to create specific isomeric forms of a drug can enhance the precision of therapeutic treatments and reduce side effects. An example of this is in the development of enzyme inhibitors. D-Leucine has been utilized in the synthesis of certain peptide-based inhibitors that target specific enzymes involved in disease pathways. These inhibitors can be more selective and have improved pharmacokinetic properties compared to their L-Leucine counterparts.
Leucine's unique biochemical properties make it a valuable subject of research in various scientific disciplines. Non-natural leucine derivatives are frequently employed in biochemical studies to investigate their effects on protein synthesis, enzyme activity, and metabolic processes. For example, researchers use leucine analogues to explore their impact on mTOR signaling and their potential applications in drug development. These studies contribute to a deeper understanding of leucine's role in cellular functions and its potential therapeutic applications.
In the industrial sector, leucine and its derivatives are utilized in the production of pharmaceuticals, specialty chemicals, and materials. Chemical synthesis of leucine and its non-natural analogues enables the development of compounds with specific properties for use in drug formulations and industrial processes. For instance, leucine derivatives are used as chiral auxiliaries in asymmetric synthesis, aiding in the production of enantiomerically pure compounds for pharmaceutical applications. Additionally, leucine-based materials are being explored for their potential use in biodegradable plastics and advanced materials due to their unique chemical properties.
| Feature | Isoleucine | Leucine |
| Chemical Structure | Isomer with a branch at the second carbon atom | Isomer with a branch at the first carbon atom |
| Side Chain | Isopropyl group | Isobutyl group |
| Classification | Non-polar, aliphatic amino acid | Non-polar, aliphatic amino acid |
| Essentiality | Essential amino acid | Essential amino acid |
| Metabolic Role | Important for energy production and hemoglobin synthesis | Key for protein synthesis and muscle repair |
| Function in Proteins | Involved in maintaining muscle and tissue structure, energy production | Stimulates protein synthesis, regulates blood sugar levels |
| Sources | Meat, fish, eggs, dairy products, legumes | Meat, fish, eggs, dairy products, legumes |
| Unique Characteristics | Critical for glucose regulation and energy production | Strong role in muscle growth and repair, often used in supplements |
| Deficiency Symptoms | Muscle wasting, fatigue, irritability | Muscle loss, fatigue, poor recovery from exercise |
| Usage in Supplements | Often included in sports supplements for energy and muscle maintenance | Popular in bodybuilding and recovery supplements for muscle growth |
| Clinical Significance | Deficiency can lead to hypoglycemia and impaired immune function | Important for managing muscle disorders and promoting muscle anabolism |
In summary, leucine stands out as an essential amino acid with broad implications for both health and industry. Its role in protein synthesis and muscle repair underscores its importance for athletes and individuals seeking to maintain muscle mass and metabolic health. The chemical structure of leucine, with its distinctive branched-chain configuration, facilitates its various functions, making it indispensable in numerous biological processes. Moreover, leucine's applications extend beyond basic nutrition, finding relevance in pharmaceutical formulations, biotechnology innovations, and advanced materials development. As research continues to uncover new uses and benefits of leucine, its significance in both scientific and commercial realms remains firmly established, reflecting its versatility and crucial role in modern science and industry.
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