88 9.3 Endocrine Hormones

Created by CK-12 Foundation/Adapted by Christine Miller

Figure 9.3.1
Figure 9.3.1 Pills from pee?

Pills from Pee

The medication pictured in Figure 9.3.1 with the brand name Progynon was a drug used to control the effects of menopause in women. The pills first appeared in 1928 and contained the human sex hormone estrogen. Estrogen secretion declines in women around the time of menopause and may cause symptoms like mood swings and hot flashes. The pills were supposed to ease the symptoms by supplementing in the body. The manufacturer of Progynon obtained estrogen for the pills from the urine of pregnant women, because it was a cheap source of the hormone. Progynon is still used today to treat menopausal symptoms. Although the drug has been improved over the years, it still contains estrogen, which is an example of an endocrine hormone.

How Do Endocrine Hormones Work?

Endocrine hormones like estrogen are messenger molecules secreted by endocrine glands into the bloodstream. They travel throughout the body in the circulation. Although they reach virtually every cell in the body in this way, each hormone affects only certain cells, called target cells. A  is the type of cell on which a hormone has an effect. A target cell is affected by a particular hormone because it has receptor proteins — either on the cell surface or within the cell — that are specific to that hormone. An endocrine hormone travels through the bloodstream until it finds a target cell with a matching receptor to which it can bind. When the hormone binds to the receptor, it causes changes within the cell. The manner in which it changes the cell depends on whether the hormone is a steroid hormone or a non-steroid hormone.

Steroid Hormones

(such as estrogen) is made of . It is fat soluble, so it can diffuse across a target cell’s , which is also made of lipids. Once inside the cell, a steroid hormone binds with receptor proteins in the . As you can see in Figure 9.3.2, the steroid hormone and its receptor form a complex — called a steroid complex — which moves into the , where it influences the expression of genes. Examples of steroid hormones include , which is secreted by the , and sex hormones, which are secreted by the .

 

Steroid Hormone regulates gene expression
Figure 9.3.2 A steroid hormone crosses the plasma membrane of a target cell, binds with a receptor protein within the cytoplasm, and forms a complex that moves to the nucleus, where it affects gene expression.

Non-Steroid Hormones

Figure 9.3.3 A non-steroid hormone binds with a receptor on the plasma membrane of a target cell. Then, a secondary messenger affects cell processes.

is made of . It is not fat soluble, so it cannot diffuse across the plasma membrane of a target cell. Instead, it binds to a receptor protein on the cell membrane. In the Figure 9.3.3 diagram, you can see that the binding of the hormone with the receptor activates an  in the cell membrane. The enzyme then stimulates another molecule, called the second messenger, which influences processes inside the cell. Most endocrine hormones are non-steroid hormones. Examples include and , both produced by the .

Regulation of Endocrine Hormones

Endocrine hormones regulate many body processes, but what regulates the secretion of endocrine hormones? Most endocrine hormones are controlled by s. A feedback mechanism is a loop in which a product feeds back to control its own production. Feedback loops may be either negative or positive.

  • Most endocrine hormones are regulated by loops. Negative feedback keeps the concentration of a hormone within a relatively narrow range, and maintains .
  • Very few endocrine hormones are regulated by loops. Positive feedback causes the concentration of a hormone to become increasingly higher.

Regulation by Negative Feedback

Figure 9.3.4 This diagram shows how the thyroid gland is regulated by a negative feedback loop that also involves the hypothalamus and pituitary gland.

A loop controls the synthesis and secretion of hormones by the . This loop includes the and , in addition to the thyroid, as shown in the diagram (Figure 9.3.4). When the levels of thyroid hormones circulating in the blood fall too low, the hypothalamus secretes (TRH). This hormone travels directly to the pituitary gland through the thin stalk connecting the two structures. In the pituitary gland, TRH stimulates the pituitary to secrete (TSH). TSH, in turn, travels through the bloodstream to the thyroid gland, and stimulates it to secrete thyroid hormones. This continues until the blood levels of thyroid hormones are high enough. At that point, the thyroid hormones feed back to stop the hypothalamus from secreting TRH and the pituitary from secreting TSH. Without the stimulation of TSH, the thyroid gland stops secreting its hormones. Eventually, the levels of thyroid hormones in the blood start to fall too low again. When that happens, the hypothalamus releases TRH, and the loop repeats.

 

Regulation by Positive Feedback

is a non-steroid endocrine hormone secreted by the . One of the functions of prolactin is to stimulate a nursing mother’s  to produce milk. The regulation of prolactin in the mother is controlled by a that involves the , , , and . Positive feedback begins when a baby suckles on the mother’s nipple. Nerve impulses from the nipple reach the hypothalamus, which stimulates the pituitary gland to secrete prolactin. Prolactin travels in the blood to the mammary glands and stimulates them to produce milk. The release of milk causes the baby to continue suckling, which causes more prolactin to be secreted and more milk to be produced. The positive feedback loop continues until the baby stops suckling at the breast.

 

Lactation Positive Feedback Loop
Figure 9.3.5 The positive feedback loop for lactation involves the suckling, the breast and the pituitary gland.

Feature: Myth vs. Reality

are synthetic versions of the naturally occurring male sex hormone . Male hormones have androgenic (or masculinizing) effects, but they also have anabolic (or muscle-building) effects. The anabolic effects are the reason that synthetic steroids are used by athletes. In addition to building muscles, they also accelerate the development of  and , increase endurance so athletes can train harder and longer, and speed up muscle recovery. Unfortunately, these benefits of steroid use come with costs. If you ever consider taking anabolic steroids to build muscles and improve athletic performance, consider the following myths and corresponding realities.

Myth 

Reality

“Steroids are safe.” Steroid use may cause several serious side effects. Prolonged use may increase the risk of liver cancer, heart disease, and high blood pressure.
“Steroids will not stunt your growth.” Teens who take steroids before they have finished growing in height may have their growth stunted so they remain shorter throughout life than they would otherwise have been. Such stunting occurs because steroids increase the rate at which skeletal maturity is reached. Once skeletal maturity occurs, additional growth in height is impossible.
“Steroids do not cause drug dependency.” Steroid use may cause dependency, as evidenced by the negative effects of stopping steroid use. These negative effects may include insomnia, fatigue, and depressed mood, among others.
“There is no such thing as ‘roid rage.'” Steroid use has been shown to increase aggressiveness in some people. It has also been implicated in a number of violent acts committed by people who had not demonstrated violent tendencies until they started using steroids.
“Only males use steroids.” Although steroid use is more common in males than females, some females also use steroids. They use them to build muscle and improve physical performance, generally either for athletic competition or for self-defense.

 

9.3 Summary

  • Endocrine hormones are messenger molecules secreted by endocrine glands into the bloodstream. They travel throughout the body but affect only certain cells, called , which have receptors specific to particular hormones.
  • such as are endocrine hormones made of  that cross  and bind to receptors inside target cells. The hormone-receptor complexes then move into the , where they influence .
  •  (such as ) are endocrine hormones made of  that bind to receptors on the surface of target cells. This activates an  in the plasma membrane, and the enzyme controls a second messenger molecule, which influences cell processes.
  • Most endocrine hormones are controlled by in which rising levels of a hormone feed back to stop its own production — and vice-versa. For example, a negative feedback loop controls production of hormones. The loop includes the , and thyroid gland.
  • Only a few endocrine hormones are controlled by , in which rising levels of a hormone feed back to stimulate continued production of the hormone. , the pituitary hormone that stimulates milk production by mammary glands, is controlled by a positive feedback loop. The loop includes the , hypothalamus, pituitary gland, and .

9.3 Review Questions

 

  1. Explain how steroid hormones influence target cells.
  2. How do non-steroid hormones affect target cells?
  3. Compare and contrast negative and positive feedback loops.
  4. Outline the way feedback controls the production of thyroid hormones.
  5. Describe the feedback mechanism that controls milk production by the mammary glands.
  6. People with a condition called hyperthyroidism produce too much thyroid hormone. What do you think this does to the level of TSH? Explain your answer.
  7. Which is more likely to maintain homeostasis— negative feedback or positive feedback? Explain your answer.
  8. Does testosterone bind to receptors on the plasma membrane of target cells or in the cytoplasm of target cells? Explain your answer.

9.3 Explore More

Great Glands – Your Endocrine System: CrashCourse Biology #33, CrashCourse, 2012.

https://www.youtube.com/watch?v=qXaDDa3FB5Q&feature=emb_logo

National Geographic | Benefits and Side Effects of Steroids Use 2015, 24 Physic.

 

Attributions

Figure 9.3.1

L0058274 Glass bottle for ‘Progynon’ pills, United Kingdom, 1928-1948 by Wellcome Collection gallery (2018-03-29)/ Science Museum, London on Wikimedia Commons is used under a  CC-BY-4.0 (https://creativecommons.org/licenses/by/4.0/) license.

Figure 9.3.2

Regulation_of_gene_expression_by_steroid_hormone_receptor.svg by Ali Zifan on Wikimedia Commons is used under a CC BY-SA 4.0  (https://creativecommons.org/licenses/by-sa/4.0/deed.en) license.

Figure 9.3.3

Non-steroid hormone pathway by CK-12 Foundation, Biology for High School is used under a CC BY-NC 3.0 (https://creativecommons.org/licenses/by-nc/3.0/) license.

©CK-12 Foundation Licensed under CK-12 Foundation is licensed under Creative Commons AttributionNonCommercial 3.0 Unported (CC BY-NC 3.0) • Terms of Use • Attribution

Figure 9.3.4

Thyroid Negative Feedback Loop by CK-12 Foundation, College Human Biology is used under a CC BY-NC 3.0 (https://creativecommons.org/licenses/by-nc/3.0/) license.

©CK-12 Foundation Licensed under CK-12 Foundation is licensed under Creative Commons AttributionNonCommercial 3.0 Unported (CC BY-NC 3.0) • Terms of Use • Attribution

Figure 9.3.5

Lactation Positive Feedback Loop by Christinelmiller on Wikimedia Commons is used under a CC BY-SA 4.0 (https://creativecommons.org/licenses/by-sa/4.0/deed.en) license.

References

24 Physic. (2015,July 19). National Geographic | Benefits and side effects of steroids use 2015. YouTube. https://www.youtube.com/watch?v=qXaDDa3FB5Q&feature=youtu.be

Brainard, J/ CK-12 Foundation. (2016, August 15). Figure 4 Thyroid negative feedback loop [digital image]. In CK-12 College Human Biology (Section 11.3 Endocrine hormones). CK12.org. https://www.ck12.org/book/ck-12-human-biology/section/11.3/

CK-12 Foundation. (2019, March 5). Figure 3 A non-steroid hormone binds with a receptor on the plasma membrane of a target cell [digital image]. In Flexbook 2.0: CK-12 Biology For High School (Section 13.21 Hormone). CK12. https://flexbooks.ck12.org/cbook/ck-12-biology-flexbook-2.0/section/13.21/primary/lesson/hormones-bio

CrashCourse. (2012, September 10). Great glands – Your endocrine system: CrashCourse Biology #33. YouTube. https://www.youtube.com/watch?v=WVrlHH14q3o&feature=youtu.be

TED-Ed. (2018, June 21). How do your hormones work? – Emma Bryce. YouTube. https://www.youtube.com/watch?v=-SPRPkLoKp8&feature=youtu.be

License

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Human Biology by Christine Miller is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License, except where otherwise noted.

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