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Completely active hormones can be released into the bloodstream (as seen in insulin and growth hormones, but some travel as prohormones that must be activated in specific cells through a series of activation steps that are commonly highly regulated.^[1]

Hormone producing cells are found in the endocrine glands, such as the thyroid gland, ovaries, and testes.^[2] Exocytosis and other methods of membrane transport are used to secrete hormones when the endocrine glands are signaled. The hierarchical model is an oversimplification of the hormonal signaling process. Cellular recipients of a particular hormonal signal may be one of several cell types that reside within a number of different tissues, as is the case for insulin, which triggers a diverse range of systemic physiological effects. Different tissue types may also respond differently to the same hormonal signal.

At the neurological level, behavior can be inferred based on hormone concentration, which in turn are influenced by hormone-release patterns; the numbers and locations of hormone receptors; and the efficiency of hormone receptors for those involved in gene transcription. Hormone concentration does not incite behavior, as that would undermine other external stimuli; however, it influences the system by increasing the probability of a certain event to occur.^[3]

Not only can hormones influence behavior, but also behavior and the environment can influence hormone concentration.^[4] Thus, a feedback loop is formed, meaning behavior can affect hormone concentration, which in turn can affect behavior, which in turn can affect hormone concentration, and so on.^[5] For example, hormone-behavior feedback loops are essential in providing constancy to episodic hormone secretion, as the behaviors affected by episodically secreted hormones directly prevent the continuous release of said hormones.^[6]

There are various clear distinctions between hormones and neurotransmitters:^[7][8][9]

• A hormone can perform functions over a larger spatial and temporal scale than can a neurotransmitter, which often acts in micrometer-scale distances.^[10]
• Hormonal signals can travel virtually anywhere in the circulatory system, whereas neural signals are restricted to pre-existing nerve tracts.^[10]
• Assuming the travel distance is equivalent, neural signals can be transmitted much more quickly (in the range of milliseconds) than can hormonal signals (in the range of seconds, minutes, or hours). Neural signals can be sent at speeds up to 100 meters per second.^[11]
• Neural signalling is an all-or-nothing (digital) action, whereas hormonal signalling is an action that can be continuously variable as it is dependent upon hormone concentration.

Neurohormones are a type of hormone that share a commonality with neurotransmitters.^[12] They are produced by endocrine cells that receive input from neurons, or neuroendocrine cells.^[12]

Hormone transport and the involvement of binding proteins is an essential aspect when considering the function of hormones.

The formation of a complex with a binding protein has several benefits: the effective half-life of the bound hormone is increased, and a reservoir of bound hormones is created, which evens the variations in concentration of unbound hormones (bound hormones will replace the unbound hormones when these are eliminated). An example of the usage of hormone-binding proteins is in the thyroxine-binding protein which carries up to 80% of all thyroxine in the body, a crucial element in regulating the metabolic rate.^[13]

1. Miller, Benjamin Frank (1997). Miller-Keane Encyclopedia & dictionary of medicine, nursing & allied health. Claire Brackman Keane (6th ed.). Philadelphia: Saunders. ISBN 0-7216-6278-1. OCLC 36465055.
2. Wisse, Brent (June 13, 2021). "Endocrine glands". MedlinePlus. Retrieved November 18, 2021.
3. Nelson, R. J. (2021). Hormones & behavior. In R. Biswas-Diener & E. Diener (Eds), Noba textbook series: Psychology. Champaign, IL: DEF publishers. Retrieved from http://noba.to/c6gvwu9m
4. Nelson, R.J. (2010), "Hormones and Behavior: Basic Concepts", Encyclopedia of Animal Behavior, Elsevier, pp. 97–105, doi:10.1016/b978-0-08-045337-8.00236-9, ISBN 978-0-08-045337-8, retrieved 2021-11-18
5. PRE-EXISTING: Garland T, Zhao M, Saltzman W (August 2016). "Hormones and the Evolution of Complex Traits: Insights from Artificial Selection on Behavior". Integrative and Comparative Biology. 56 (2): 207–24. doi:10.1093/icb/icw040. PMC 5964798. PMID 27252193.
6. Principles of hormone/behavior relations. Donald W. Pfaff, Robert Terry Rubin, Jill E. Schneider, Geoffrey A. Head (2nd ed.). London, United Kingdom: Academic Press. 2018. ISBN 0-12-802667-7. OCLC 1022119040.
7. Reece JB, Urry LA, Cain ML, Wasserman SA, Minorsky PV, Jackson RB, Campbell NA (2014). Campbell biology (Tenth ed.). Boston. ISBN 9780321775658. OCLC 849822337.
8. PRE-EXISTING: Reece JB, Urry LA, Cain ML, Wasserman SA, Minorsky PV, Jackson RB, Campbell NA (2014). Campbell biology (Tenth ed.). Boston. ISBN 9780321775658. OCLC 849822337.
9. PRE-EXISTING: Siegel A, Sapru H, Hreday N, Siegel H (2006). Essential neuroscience. Philadelphia: Lippincott Williams & Wilkins. ISBN 0781750776. OCLC 60650938.
10. PRE-EXISTING: Silverthorn DU, Johnson BR, Ober WC, Ober CW (2016). Human physiology : an integrated approach(Seventh ed.). [San Francisco]. ISBN 9780321981226. OCLC 890107246.
11. Neuroscience. Dale Purves, S. Mark Williams (2nd ed.). Sunderland, Mass.: Sinauer Associates. 2001. ISBN 0-87893-742-0. OCLC 44627256.
12. PRE-EXISTING: Alberts B (2002). Molecular biology of the cell. Johnson, Alexander,, Lewis, Julian,, Raff, Martin,, Roberts, Keith,, Walter, Peter (4th ed.). New York: Garland Science. ISBN 0815332181. OCLC 48122761.
13. Life, the science of biology. Purves, William K. (William Kirkwood), 1934- (6th ed.). Sunderland, MA: Sinauer Associates. 2001. ISBN 0716738732. OCLC 45064683.
15. Oppenheimer, Jack H. (1968-05-23). "Role of Plasma Proteins in the Binding, Distribution and Metabolism of the Thyroid Hormones". New England Journal of Medicine. 278 (21): 1153–1162. doi:10.1056/NEJM196805232782107. ISSN 0028-4793.

A prohormone is a committed precursor of a hormone, usually having minimal hormonal effect by itself but rather circulating in the blood stream as a hormone in an inactivated form, ready to be activated later by post-translational modification.^[14] Examples of natural, human prohormones include proinsulinand pro-opiomelanocortin.

For peptide hormones, the conversion process from prohormone to hormone (pro-protein to protein) typically occurs after being exported to the endoplasmic reticulum and often requires multiple processing enzymes. Proamylin, which is cosecreted with proinsulin, requires the above three factors and an amidating monooxygenase.^[15]

1. Miller, Benjamin Frank (1997). Miller-Keane Encyclopedia & dictionary of medicine, nursing & allied health. Claire Brackman Keane (6th ed.). Philadelphia: Saunders. ISBN 0-7216-6278-1. OCLC 36465055.
2. "Amylin Proprotein Processing Generates Progressively More Amyloidogenic Peptides that Initially Sample the Helical State". Biochemistry. 47: 9900–9910. August 19, 2008 – via American Chemical Society.

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