What Is Proline?
Also known as L-proline, it is an imino acid or a molecule that comprises both the carboxyl and imine functional groups. It is also a part of the twenty most crucial amino acids as humans and other animals biosynthesize it. The primary amine present on the carbon of the glutamate semialdehyde generally forms a Schiff base from which the aldehyde reduces, thus generating proline. The proline contains a secondary amine group (the only natural amino acid having a secondary amine), giving its unique helix rings in the structure. The proteins synthesized from proline also have discrete secondary structures and, therefore, appear different from that of the proteins synthesized from open-chain proteins.
It was in 1900 that Nobel-laureate Richard M. Willstätter came up with the D, L-racemate synthesized from N-methylproline. Generally considered as an asymmetrical catalyst in numerous protein synthesis, Harvard University researchers often referred to proline as the 'simplest enzyme,' which was then elaborated as proline being one the few catalysts enabling prebiotic evolution.
Proline Structure
Considered highly unusual for an amino acid to be cyclic in its structure (because of the secondary amine), proline forms a peptide bond that does not contain hydrogen on the α amino group. This is why prolines cannot give away its Hydrogen bond to balance the α helix or the β sheet. For prolines found at the end of the α helix, the absence of hydrogen atom creates a bend in the helix structure and can exist in isoenergetic cis and trans variations.
For the biological systems in animals and humans, the amino acids are crucial components, because of its life-giving features and attributes. Found diversely across cells, muscles, eggs, and other animal processes, these can help in regulating the insulin generation, heal muscle tissues as well as contribute to our body metabolism. Often represented as one-lettered format P, these amino acids are made from an amino group and a carboxyl group, as well as an R-group, bonded with the central Carbon atom to form a helix structure.
The L-proline belongs from the pyrrolidine (a cyclic amine) where the pro-S Hydrogen atom gets replaced by a carboxyl group. It has a structure that makes it an enantiomer to D-proline and has the conjugate acid of that of the L-prolinate.
As the R-group in a proline gets bonded with the Nitrogen atom of the amino group, this is what gives proline its unique structure, distinct from other amino acids. Here’s how proline chemical structure appears in shape:
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Proline Synthesis
Proline requires a carbon-nitrogen double bond (as it is an imino acid) and can be easily synthesized from Glutamic acid. The γ-carboxyl group gets reduced into an aldehyde, forming glutamate semialdehyde, which then further reacts to the α-amino group, producing water and Schiff base (a sub-class of imines). It is the Schiff base that gets also reduced to generate proline.
The proline formula for the same is:
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Properties of Proline
The nitrogen atom in a peptide proline doesn't remain attached to the hydrogen and therefore makes a considerable influence in the susceptibility of peptide bonds and stimulates activity. The proline can form aggregation due to hydrophobic interaction of the pyrrolidine ring. Here are some properties of proline:
Prolines are aliphatic and hydrophobic, contributing to the intracellular signalling in biosystems.
The peptidases that get formed in the process of proline-involved biological processes, help in regulating the generation of proline throughout its lifetime, in its aminopeptidase P, prolidase forms.
The HIV-I protease enzyme can lead to the generation of a Xaa-Pro peptide bond formation in the process that can be critical components in several immunological processes.
The proline can display a variety of properties that may not be similar to other lighter molecular weight compounds in its aqueous form in terms of its solubility, density, and viscosity. There is strong hydrogen bonding with water that is observed in proline solutions.
The proline solutions can enhance the solubility of other proteins by enabling a hydrophobic interaction with the protein surface, leading to the rise in the hydrophilic area.
Uses of Proline
There are several uses of L-Proline. Some of them are:
L-Proline is popularly used as a precursor to the L-glutamate and therefore known for its energy fuel pertaining capabilities.
It is one of the primary amino acids present in human cartilage that helps in achieving youthful skin, and facilitate faster muscle repairs, crucial to the all-round working of the human joints and tendons, including strengthening of heart muscles and connective tissues.
Sometimes L-Proline can also get oxidized in our kidney from Glycogenic, which on further oxidation yields L-Glutamic acid that plays an essential role in fighting the conditions of arthrosis and chordae.
L-Proline can also be found in several dietary supplements in the form of crystalline Proline, which can contribute to body metabolism.
FAQs on Proline
1. What is proline and what are its main functions in the body?
Proline is a non-essential proteinogenic amino acid, meaning the human body can synthesise it. Its primary functions include being a critical building block for collagen, the main structural protein in skin, cartilage, and bones. It also plays a vital role in protein synthesis and structure, wound healing, and supporting metabolic processes.
2. What is unique about the structure of proline compared to other amino acids?
The structure of proline is unique among the 20 standard amino acids because its side chain loops back and bonds to its own backbone nitrogen atom. This forms a rigid five-membered ring called a pyrrolidine ring. As a result, the alpha-amino group is a secondary amine, unlike the primary amine found in all other proteinogenic amino acids.
3. Why is proline often called an 'alpha-helix breaker' in protein secondary structures?
Proline is known as an 'alpha-helix breaker' because its rigid ring structure restricts rotation around the N-Cα bond. This structural rigidity prevents it from adopting the required bond angles to fit neatly into the regular, repeating spiral of an alpha-helix. Its presence in a polypeptide chain introduces a significant kink or bend, disrupting the helical formation.
4. Is proline acidic, basic, or neutral in charge?
At physiological pH (approximately 7.4), proline is considered a neutral amino acid. It exists as a zwitterion, where its carboxyl group (-COOH) is deprotonated to form a negative carboxylate ion (-COO⁻), and its secondary amino group is protonated to form a positive ion (-NH₂⁺-). The opposing charges within the molecule cancel each other out, resulting in a net neutral charge.
5. How does the role of proline in plants differ from its role in humans?
While proline is a protein component in both, its specialised roles differ significantly. In humans, its primary importance is as a structural component of collagen for connective tissues. In plants, proline acts as a crucial osmoprotectant. Plants accumulate proline in high concentrations to protect cells from environmental stresses such as drought, high salinity, and extreme temperatures by maintaining cell turgor and stabilising proteins.
6. Since proline has a secondary amine, why is it still classified as an amino acid and not an imino acid?
From a strict chemical standpoint, proline is technically an imino acid due to its secondary amine group. However, in the context of biochemistry and the study of proteins, it is universally classified as an amino acid. This is because it is incorporated into proteins via peptide bonds during translation, functioning alongside the other 19 standard amino acids. The classification is based on its biological function as a protein building block rather than its precise chemical group.
7. What are some important applications and uses of proline?
Proline has several important applications across different fields. Its key uses include:
- Dietary Supplements: Used in supplements aimed at supporting joint health and skin elasticity due to its role in collagen synthesis.
- Pharmaceuticals: Employed as a precursor in the synthesis of certain drugs.
- Biotechnology: Used as a stabilising agent for proteins and enzymes and as a cryoprotectant to protect cells during freezing.
- Organic Chemistry: Acts as an important catalyst in certain asymmetric synthesis reactions.
