Histidine is an essential amino acid crucial for protein biosynthesis, immune response, and metal ion detoxification. It supports tissue growth, repair, and pH regulation, while also serving as a precursor to histamine, aiding in allergic reactions and inflammation. Non-natural histidine derivatives, such as methyl-histidine and phosphorylated histidine, are widely used in pharmaceuticals, biotechnology, and biomaterials. These derivatives enhance drug stability, enzyme function, and are pivotal in protein purification and targeted drug delivery systems. Their unique biochemical properties make histidine and its analogs indispensable in various industrial applications.
Histidine is an essential amino acid that plays a vital role in various biological functions, particularly in protein biosynthesis. As one of the 20 standard amino acids, histidine's importance spans several industries, from biotechnology to pharmaceuticals, making it a crucial component in various metabolic and synthetic pathways. In addition to natural histidine, non-natural histidine derivatives are synthesized and modified to cater to a wide array of industrial applications. These derivatives, which are designed to meet specific requirements in industries such as pharmaceuticals and material sciences, offer enhanced functionalities that exceed those of natural histidine.
At the molecular level, histidine contains an α-amino group (-NH3+ under biological conditions), a carboxyl group (-COO−), and an imidazole side chain. Its chemical formula is C6H9N3O2, and it has a molecular weight of 155.16 g/mol. The most notable feature of histidine is its imidazole side chain, which gives histidine unique properties, such as acting as a proton donor or acceptor, making it highly reactive and essential for enzyme function and other biochemical processes. In addition, the pKa of histidine's imidazole ring is around 6.0, making it one of the few amino acids with a side chain that can donate or accept protons at physiological pH. This feature enables histidine to function as a buffer in biological systems, maintaining pH homeostasis in cells. This acid-base behavior makes it a critical component in enzyme catalysis and metalloprotein binding, where it stabilizes transition states and facilitates biochemical reactions.
Fig. 1. Histidine amino acid structure.
Histidine is aromatic at all pH levels, owing to the π-electron delocalization within its imidazole ring. This aromatic nature enhances its ability to participate in π-stacking interactions, though these are rare in physiological conditions due to histidine's positive charge. Moreover, histidine's resonance structures distribute the positive charge across the nitrogen atoms of the imidazole ring, making it highly flexible in its interactions with other molecules. This flexibility is critical for histidine's role in enzyme active sites and protein-ligand binding.
Histidine is essential for several physiological functions and offers numerous health benefits, particularly in growth, immunity, and metabolism. As an amino acid that cannot be synthesized by the body, it must be obtained through dietary intake or supplements.
Histidine exists in two stereoisomeric forms: L-Histidine and D-Histidine, which differ in their molecular arrangement around the central carbon atom. These isomers play distinct roles in both biological processes and industrial applications. In addition to L-Histidine and D-Histidine, there are non-natural histidine derivatives that have been developed for enhanced functionality. These non-natural histidine derivatives are highly valuable in a variety of scientific and industrial applications. In drug development, they are used to create more targeted therapies with improved pharmacokinetics. In biotechnology, histidine variants are utilized in enzyme engineering to enhance catalytic efficiency and binding specificity. Their ability to bind metal ions more effectively than natural histidine makes them indispensable in designing metal-chelating agents for therapeutic and diagnostic purposes.
L-Histidine is the naturally occurring form found in proteins, and it is vital for numerous physiological functions. It is incorporated into proteins during the process of translation and plays a key role in enzyme activity, metal ion binding, and structural integrity within biological systems. L-Histidine's role in hemoglobin is especially significant, as it helps regulate oxygen transport by coordinating with iron in heme groups. Moreover, it participates in the biosynthesis of histamine, an important compound involved in immune responses and neurotransmission.
Name | CAS | Catalog | Price |
1-Methyl-L-Histidine | 332-80-9 | BAT-003860 | Inquiry |
H-N-3-Methyl-L-histidine | 368-16-1 | BAT-003944 | Inquiry |
Nα-Fmoc-L-histidine | 116611-64-4 | BAT-003660 | Inquiry |
Benzoyl-L-histidine | 5354-94-9 | BAT-004104 | Inquiry |
Boc-L-histidine | 17791-52-5 | BAT-002783 | Inquiry |
Nα-Z-L-histidine | 14997-58-1 | BAT-003224 | Inquiry |
In contrast, D-Histidine is a synthetic form that is not typically found in nature. It is produced through chemical synthesis and has specialized applications in pharmaceuticals and biotechnology. D-Histidine is used in certain peptide drugs and enzyme assays due to its distinct stereochemistry, which can improve stability and bioavailability in therapeutic formulations. Although it does not play a direct role in human biology, its controlled use in industrial settings offers advantages in drug design and protein engineering.
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Nα-Fmoc-Nim-Boc-D-histidine | 159631-28-4 | BAT-004509 | Inquiry |
Nim-Trityl-D-histidine | 199119-46-5 | BAT-003538 | Inquiry |
Nα-Fmoc-D-histidine | 157355-79-8 | BAT-003655 | Inquiry |
Nim-Benzyl-D-histidine | 2022956-35-8 | BAT-000438 | Inquiry |
Nα-Boc-D-histidine | 50654-94-9 | BAT-002939 | Inquiry |
Nα-Z-D-histidine | 67424-93-5 | BAT-003211 | Inquiry |
Histidine and its non-natural derivatives find wide-ranging applications across various industries, owing to their versatile biochemical properties. These applications span from drug development and biotechnology to food supplements, biomaterials, and catalysis, showcasing the broad impact of histidine in both natural and modified forms.
Histidine plays a crucial role in pharmaceutical research, especially in the design and formulation of peptide-based drugs. Its ability to bind metal ions and participate in enzyme catalysis makes it an essential component in developing enzyme inhibitors, antiviral agents, and anti-inflammatory drugs. For example, histidine analogs are used in the creation of proton pump inhibitors (PPIs), which are commonly prescribed to treat gastric acid-related disorders. Non-natural histidine derivatives, such as phosphorylated histidine, are used in signal transduction research and are crucial in developing targeted therapies for diseases like cancer.
In the field of biotechnology, histidine and its derivatives are vital in protein purification and enzyme engineering. Polyhistidine tags (His-tags) are widely employed in recombinant protein production to facilitate the purification of proteins via immobilized metal affinity chromatography (IMAC). This process uses the strong affinity between histidine and nickel or cobalt ions to isolate proteins of interest from complex mixtures, making it a standard technique in biopharmaceutical production. Furthermore, non-natural histidine variants are used to enhance protein stability and binding specificity, leading to more efficient enzymes for industrial biocatalysis.
As an essential amino acid, histidine is commonly found in dietary supplements, especially in formulations aimed at athletes and individuals requiring increased muscle recovery. L-Histidine is critical for protein synthesis and tissue repair, and its role in the production of histamine makes it beneficial for immune system support. Histidine supplements are often included in products targeting joint health, cognitive function, and antioxidant defense. Non-natural derivatives, such as methyl-histidine, are used in nutritional studies to monitor protein metabolism and assess the effectiveness of dietary interventions.
In the field of biomaterials, histidine's ability to act as a metal-binding ligand makes it an attractive component for biocompatible materials. For instance, histidine-functionalized polymers are used in the development of drug delivery systems that target specific tissues or organs. These polymers can be engineered to release drugs in response to pH changes or metal ion concentrations, enhancing the efficacy of treatments while minimizing side effects. Additionally, histidine-containing hydrogels are employed in tissue engineering and wound healing due to their ability to support cell growth and regeneration.
Histidine and its non-natural derivatives are also widely used as catalysts in chemical reactions and biocatalysis. The imidazole side chain of histidine is particularly effective in facilitating proton transfers and metal ion coordination, which are essential in many enzymatic reactions. Histidine-based catalysts are used in industrial biocatalysis to accelerate reactions in a more environmentally friendly and cost-effective manner. Non-natural histidine derivatives, such as histidine analogs, have been engineered to improve catalytic efficiency in synthetic chemistry, enabling the production of more complex molecules for use in pharmaceuticals and fine chemicals.
1. Is histidine aromatic?
Yes, histidine is considered aromatic. The aromatic nature of histidine arises from its imidazole ring, which has 6 π-electrons. These π-electrons are delocalized in a conjugated system, fulfilling the Hückel's rule for aromaticity. This property is important for interactions such as π-π stacking and coordination with metal ions in various biological systems, particularly in metalloproteins.
2. Is histidine polar or nonpolar?
Histidine is classified as a polar amino acid. Its imidazole side chain contains nitrogen atoms capable of forming hydrogen bonds, which contribute to its polarity. The ability of the imidazole group to accept or donate protons makes histidine highly versatile in both hydrophilic interactions and enzymatic catalysis, where it often participates as a proton donor or acceptor.
3. Is histidine acidic or basic?
Histidine is generally classified as basic due to its imidazole side chain, which can accept protons, especially at physiological pH (around 7.4). However, it exhibits a pKa value around 6.0, meaning the imidazole ring can also act as an acid under certain conditions, giving histidine the ability to function as a buffer in biological systems, switching between protonated and deprotonated forms.
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