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Hub AI
Prohormone AI simulator
(@Prohormone_simulator)
Hub AI
Prohormone AI simulator
(@Prohormone_simulator)
Prohormone
A prohormone is a committed precursor of a hormone consisting of peptide hormones synthesized together that has a minimal hormonal effect by itself because of its expression-suppressing structure, often created by protein folding and binding additional peptide chains to certain ends, that makes hormone receptor binding sites located on its peptide hormone chain segments inaccessible[clarification needed].
Prohormones can travel the blood stream as a hormone in an inactivated form, ready to be activated later in the cell by post-translational modification.
The body naturally produces prohormones as a way to regulate hormone expression, making them an optimal storage and transportation unit for inactive hormones. Once prohormones are needed to be expressed, prohormone convertase, a protein, cleaves the prohormones and separates them into one or more active hormones. Often in nature, this cleaving process happens immediately, and a prohormone is quickly converted to a set of one or more peptide hormones.
Examples of natural, human prohormones include proinsulin and pro-opiomelanocortin, but the most widespread prohormones in use are synthetic and labeled as anabolic steroid precursors, used as ergogenic or anabolic agents for muscle growth. A commonly consumed example of said precursors are androstenedione and androstenediol, both of which are currently banned substances in the United States. However, several illegal steroids, such as 1-testosterone, are still being produced legally under different chemical names, and the majority have not undergone clinical studies.
Prohormones vary considerably in length and design, as do peptide hormones, but their base structure is the same. They consist of one or more inactive peptide hormones or hormone chains attached to each other in a way that prevents hormone expression, often by making the chains' binding ends inaccessible via folding and binding of other chains to said ends. For hormonal expression to be induced, the binding ends of hormones but either bind to receptors in the cell membrane, or in the case of steroids, bind to steroid receptor proteins in the cell, both of which mediate hormone expression.
Some prohormones contain structures other than inactive peptide hormones for the purpose of keeping hormone expression suppressed. For example, proinsulin contains an extra non-hormonal chain called C-peptide that binds two insulin peptide chains together, designed to keep both chains inactive by binding to their ends, specifically, their C-domain junctions, which have been proposed to be their site of binding to hormone-expression receptors in the cell. Despite the restrictions it enables, the C-peptide folds the proinsulin chains to make their junction ends accessible to be cleaved by prohormone convertases later, making the folding of the proinsulin chain containing C-peptide essential for the proper cleavage of proinsulin to successfully produce insulin.
Prohormones allow for transport and storage of usually-active proteins as inactive peptide chains, though they are much more commonly found in nature as a stable intermediate in the protein-synthesizing process of the cell. Proinsulin, for example, is seen in nature as a brief precursor to insulin, as it is produced on the ribosomes of the cell, transported to the Golgi apparatus as proinsulin, then is converted to insulin immediately after reaching the Golgi apparatus. It is also primarily stored as insulin.
However, other inactive proteins travel in their prohormone form, such as vitamin D, also known as calciferol, which can be produced by the human body via sunlight.
Prohormone
A prohormone is a committed precursor of a hormone consisting of peptide hormones synthesized together that has a minimal hormonal effect by itself because of its expression-suppressing structure, often created by protein folding and binding additional peptide chains to certain ends, that makes hormone receptor binding sites located on its peptide hormone chain segments inaccessible[clarification needed].
Prohormones can travel the blood stream as a hormone in an inactivated form, ready to be activated later in the cell by post-translational modification.
The body naturally produces prohormones as a way to regulate hormone expression, making them an optimal storage and transportation unit for inactive hormones. Once prohormones are needed to be expressed, prohormone convertase, a protein, cleaves the prohormones and separates them into one or more active hormones. Often in nature, this cleaving process happens immediately, and a prohormone is quickly converted to a set of one or more peptide hormones.
Examples of natural, human prohormones include proinsulin and pro-opiomelanocortin, but the most widespread prohormones in use are synthetic and labeled as anabolic steroid precursors, used as ergogenic or anabolic agents for muscle growth. A commonly consumed example of said precursors are androstenedione and androstenediol, both of which are currently banned substances in the United States. However, several illegal steroids, such as 1-testosterone, are still being produced legally under different chemical names, and the majority have not undergone clinical studies.
Prohormones vary considerably in length and design, as do peptide hormones, but their base structure is the same. They consist of one or more inactive peptide hormones or hormone chains attached to each other in a way that prevents hormone expression, often by making the chains' binding ends inaccessible via folding and binding of other chains to said ends. For hormonal expression to be induced, the binding ends of hormones but either bind to receptors in the cell membrane, or in the case of steroids, bind to steroid receptor proteins in the cell, both of which mediate hormone expression.
Some prohormones contain structures other than inactive peptide hormones for the purpose of keeping hormone expression suppressed. For example, proinsulin contains an extra non-hormonal chain called C-peptide that binds two insulin peptide chains together, designed to keep both chains inactive by binding to their ends, specifically, their C-domain junctions, which have been proposed to be their site of binding to hormone-expression receptors in the cell. Despite the restrictions it enables, the C-peptide folds the proinsulin chains to make their junction ends accessible to be cleaved by prohormone convertases later, making the folding of the proinsulin chain containing C-peptide essential for the proper cleavage of proinsulin to successfully produce insulin.
Prohormones allow for transport and storage of usually-active proteins as inactive peptide chains, though they are much more commonly found in nature as a stable intermediate in the protein-synthesizing process of the cell. Proinsulin, for example, is seen in nature as a brief precursor to insulin, as it is produced on the ribosomes of the cell, transported to the Golgi apparatus as proinsulin, then is converted to insulin immediately after reaching the Golgi apparatus. It is also primarily stored as insulin.
However, other inactive proteins travel in their prohormone form, such as vitamin D, also known as calciferol, which can be produced by the human body via sunlight.