Chapter 18

Chapter 18

I. COMPARISON of the CONTROL by the NERVOUS and ENDOCRINE SYSTEM

A. Together the nervous and endocrine systems coordinate functions of all body systems.

1. The nervous system controls body actions through nerve impulses.

2. The endocrine system controls body activities by releasing mediator molecules called hormones.

3. The science concerned with the structure and function of the endocrine glands and the diagnosis and treatment of endocrine disorders is called endocrinology.

B. The nervous and endocrine systems act as a coordinated interlocking supersystem, the neuroendocrine system.

1. Parts of the nervous system stimulate or inhibit the release of hormones.

2. Hormones may promote or inhibit the generation of nerve impulses.

C. The nervous system causes muscles to contract or glands to secrete. The endocrine system affects virtually all body tissues by altering metabolism, regulating growth and development, and influencing reproductive processes.

D. Table 18.1 compares the characteristics of the nervous and endocrine systems.

II. ENDOCRINE GLAND

A. The body contains two kinds of glands: exocrine and endocrine.

1. Exocrine glands secrete their products into ducts, and the ducts carry the secretions to the target site.

2. Endocrine glands secrete their products (hormones) into the interstitial fluid surrounding the secretory cells from which they diffuse into capillaries to be carried away by blood.

B. Endocrine glands constitute the endocrine system and include the pituitary, thyroid, parathyroid, adrenal, and pineal glands (Figure 18.1). Other organs also have endocrine tissue associated with them. Examples include the pancreas, ovaries, testes, stomach, kidneys, etc.

III. HORMONE ACTIVITY

A. Hormones have powerful effects when present in very low concentrations.

B. Hormone Receptors

1. Although hormones travel in blood throughout the body, they affect only specific target cells.

2. Target cells have specific protein or glycoprotein receptors to which hormones bind.

3. Receptors are constantly being synthesized and broken down.

a. When a hormone is present in excess, down-regulation, the decrease in the number of receptors, may occur.

b. When a hormone is deficient, up-regulation, an increase in the number of receptors, may occur.

C. Circulating and Local Hormones

1. Hormones that travel in blood and act on distant target cells are called circulating hormones or endocrines.

2. Hormones that act locally without first entering the blood stream are called local hormones.

a. Those that act on neighboring cells are called paracrines.

b. Those that act on the same cell that secreted them are termed autocrines.

3. Figure 18.2 compares the site of action of circulating and local hormones.

D. Chemical Classes of Hormones

1. Table 18.2 provides a summary of the hormones.

2. Lipid-soluble hormones include the steroids, thyroid hormones, and nitric oxide, which acts as a local hormone in several tissues.

3. Water-soluble hormones include the amines; peptides, proteins, and glycoproteins; and eicosanoids.

E. Hormone Transport in Blood

1. Most water-soluble hormones circulate in plasma in a free, unattached form.

2. Most lipid-soluble hormones bind to transport proteins to be carried in blood.

3. The transport proteins improve the transportability of lipid-soluble hormones by making them temporarily water-soluble, retard passage of the small hormone molecules through the kidney filter thus slowing the rate of hormone loss in urine, and provide a ready reserve of hormone already present in blood.

IV. MECHANISMS OF HORMONE ACTION

A. The response to a hormone depends on both the hormone and the target cell; various target cells respond differently to different hormones.

B. Action of Lipid-Soluble Hormone

1. Lipid-soluble hormones bind to and activate receptors within cells.

2. The activated receptors then alter gene expression which results in the formation of new proteins.

3. The new proteins alter the cells activity and result in the physiological responses of those hormones.

4. Figure 18.3 shows this mechanism of action. Refer to lecture notes for more detail.

C. Action of Water-Soluble Hormones

1. Water-soluble hormones alter cell functions by activating plasma membrane receptors, which set off a cascade of events inside the cell.

a. The water-soluble hormone that binds to the cell membrane receptor is the first messenger.

b. A second messenger is released inside the cell where hormone stimulated response takes place.

2. A typical mechanism of action of a water-soluble hormone using cyclic AMP as the second messenger is seen in Figure 18.4.

a. The hormone binds to the membrane receptor.

b. The activated receptor activates a membrane G-protein which turns on adenylate cyclase.

c. Adenylate cyclase converts ATP into cyclic AMP which activates protein kinases.

d. Protein kinases phosphorylate enzymes which catalyze reactions that produce the physiological response.

3. Since hormones that bond to plasma membrane receptors initiate a cascade of events, they can induce their effects at very low concentrations. Please refer to lecture notes for further detail.

D. Hormonal Interactions

1. The responsiveness of a target cell to a hormone depends on the hormone’s concentration, the abundance of the target cell’s hormone receptors, and influences exerted by other hormones.

2. Three hormonal interactions are the permissive effect, the synergistic effect, and the antagonist effect. Please refer to lecture notes for further detail.

V. CONTROL OF HORMONE SECRETIONS

A. Most hormones are released in short bursts, with little or no release between bursts. Regulation of hormone secretion normally maintains homeostasis and prevents overproduction or underproduction of a particular hormone; when these regulating mechanisms do not operate properly, disorders result.

B. Hormone secretion is controlled by signals from the nervous system, by chemical changes in the blood, and by other hormones.

C. Most often, negative feedback systems regulate hormonal secretions.

VI. HYPOTHALAMUS AND PITUITARY GLAND

A. The hypothalamus is the major integrating link between the nervous and endocrine systems.

B. The hypothalamus and the pituitary gland (hypophysis) regulate virtually all aspects of growth, development, metabolism, and homeostasis.

C. The pituitary gland is located in the sella turcica of the sphenoid bone and is differentiated into the anterior pituitary (adenohypophysis), and the posterior pituitary (neurohypophysis), (Figures 18.5 and 18.21b).

1. Anterior Pituitary Gland (Adenohypophysis)

a. Hormones of the anterior pituitary are controlled by releasing or inhibiting hormones produced by the hypothalamus. See Table 18.3

b. The blood supply to the anterior pituitary is from the superior hypophyseal arteries. See lecture notes for detail on the hypophyseal portal system.

c. Hormones of the anterior pituitary and the cells that produce them are as follows.

1) Human growth hormone (hGH) is secreted by somatotrophs.

2) Thyroid-stimulating hormone (TSH) is secreted by thyrotrophs.

3) Follicle-stimulating hormone (FSH) and luteinizing hormone (LH) are secreted by gonadotrophs.

4) Prolactin (PRL) is secreted by lactrotrophs.

5) Adrenocorticotrophic hormone (ACTH) and melanocyte-stimulating hormone (MSH) are secreted by corticotrophs.

d. The hormones of the anterior pituitary gland are summarized in Table 18.3.

e. Secretion of anterior pituitary gland hormones is regulated by hypothalamic regulating hormones and by negative feedback mechanisms (Figure 18.6, Table 18.3).

f. Human Growth Hormone and Insulinlike Growth Factors

1) Human growth hormone (hGH) is the most plentiful anterior pituitary hormone.

2) It acts indirectly on tissues by promoting the synthesis and secretion of small protein hormones called insulinlike growth factors (IGFs).

3) IGFs stimulate general body growth and regulate various aspects of metabolism. See lecture notes for details on the actions of IGFs and growth hormone on metabolism.

4) Various stimuli promote and inhibit hGH production (Figure 18.7).

5) One symptom of excess hGH is hyperglycemia (diabetogenic effect).

g. Thyroid-stimulating hormone (TSH) regulates thyroid gland activities and is controlled by TFH (thyrotropin releasing hormone).

h. Follicle-Stimulating Hormone (FSH)

1) In females, FSH initiates follicle development and secretion of estrogens in the ovaries.

2) In males, FSH stimulates sperm production in the testes.

i. Luteinizing Hormone (LH)

1) In females, LH stimulates secretion of estrogen by ovarian cells to result in ovulation and stimulates formation of the corpus luteum and secretion of progesterone.

2) In males, LH stimulates the interstitial cells of the testes to secrete testosterone.

j. Prolactin (PRL), together with other hormones, initiates and maintains milk secretion by the mammary glands. See lecture notes for further details.

k. Adrenocorticotrophic hormone (ACTH) controls the production and secretion of hormones called glucocorticoids by the cortex of the adrenal gland. See lecture notes and Figure18.6 for details on the negative feedback regulation.

l. Melanocyte-stimulating hormone (MSH) increases skin pigmentation although its exact role in humans is unknown.

m. Table 18.4 summarizes the principal actions of the anterior pituitary gland hormones.

2. Posterior Pituitary Gland (Neurohypophysis)

a. Although the posterior pituitary gland does not synthesize hormones, it does store and release two hormones.

b. The neural connection between the hypothalamus and the posterior pituitary is via the hypothalamohypophyseal tract from the supraoptic and paraventricular nuclei (Figure 18.8).

c. Hormones made by the hypothalamus and stored in the posterior pituitary are oxytocin (OT) and antidiuretic hormone (ADH).

1) Oxytocin stimulates contraction of the uterus and ejection (let-down) of milk from the breasts. It is regulated by positive feedback. See lecture notes for more detail on this.

2) Nursing a baby after delivery stiumlates oxytocin release promoting uterine contractions and the expulsion of the placenta.

3) Antidiuretic hormone stimulates water reabsorption by the kidneys and arteriolar constriction.

a) The effect of ADH is to decrease urine volume and conserve body water. It can also raise blood pressure.

b) ADH is controlled primarily by osmotic pressure of the blood (Figure 18.9). See lecture notes and Figure 18.9 for more detail on regulation.

d. Table 18.5 lists the posterior pituitary gland hormones and summarizes their principal actions and the control of their secretions.

VII. THYROID GLAND

A. The thyroid gland is located just below the larynx and has right and left lateral lobes (Figure 18.10a).

B. Histologically, the thyroid consists of the thyroid follicles composed of follicular cells, which secrete the thyroid hormones thyroxine (T₄) and triiodothyronine (T₃), and parafollicular cells, which secrete calcitonin (CT) (Figures 18.10b and 18.13c).

C. Formation, Storage, and Release of Thyroid Hormones

1. Thyroid hormones are synthesized from iodine and tyrosine within a large glycoprotein molecule called thyroglobulin (TGB) and are transported in the blood by plasma proteins, mostly thyroxine-binding globulin (TBG).

2. The formation, storage, and release steps include iodide trapping, synthesis of thyroglobulin, oxidation of iodide, iodination of tyrosine, coupling of T₁ and T₂, pinocytosis and digestion of colloid, secretion of thyroid hormones, and transport in blood (Figure 18.11). See lecture notes for more detail.

D. Thyroid hormones regulate oxygen use and basal metabolic rate, cellular metabolism, and growth and development. See lecture notes for more detail.

E. Secretion of thyroid hormone is controlled by the level of iodine in the thyroid gland and by negative feedback systems involving both the hypothalamus and the anterior pituitary gland (Figure 18.12).

F. Calcitonin lowers the blood level of calcium. Secretion is controlled by calcium levels in the blood.

G. Table 18.6 summarizes the hormones produced by the thyroid gland, their principal actions, and control of secretion.

VIII. PARATHYROID GLANDS

A. The parathyroid glands are embedded on the posterior surfaces of the lateral lobes of the thyroid and contain principal cells, which produce parathyroid hormone, and oxyphil cells, whose function is unknown (Figure 18.13).

B. Parathyroid hormone (PTH) regulates the homeostasis of calcium and phosphate by increasing blood calcium level and decreasing blood phosphate level.

1. PTH increases the number and activity of osteoclasts, increases the rate of Ca⁺² and Mg⁺² from reabsorption from urine and inhibits the reabsorption of HPO₄^-2 so more is secreted in the urine, and promotes formation of calcitriol, which increases the absorption of Ca⁺², Mg⁺²,and HPO₄^-2 from the GI tract.

2. Blood calcium level directly controls the secretion of calcitonin and parathyroid hormone via negative feedback loops that do not involve the pituitary gland (Figure 18.14).

C. Table 18.7 summarizes the principal actions and control of secretion of parathyroid hormone.

IX. ADRENAL GLANDS

A. The adrenal glands are located superior to the kidneys (Figure 18.15); they consists of an outer cortex and an inner medulla.

B. Adrenal Cortex

1. The adrenal cortex is divided into three zones, each of which secretes different hormones (Figure 18.15).

a. The zona glomerulosa (outer zone) secretes mineralocorticoids.

b. The zona fasciculata (middle zone) secretes glucocorticoids.

c. The zona reticularis (inner zone) secretes androgens.

2. Mineralocorticoids

a. Mineralocorticoids (e.g., aldosterone) increase sodium and water reabsorption and decrease potassium reabsorption, helping to regulate sodium and potassium levels in the body.

b. Secretion is controlled by the renin-angiotensin pathway (Figure 18.16) and the blood level of potassium. We will cover this pathway when we do the urinary system. You are not responsible for the details at this point.

3. Glucocorticoids

a. Glucocorticoids (e.g., cortisol) promote breakdown of proteins, formation of glucose, lipolysis, resistance to stress, anti-inflammatory effects, and depression of the immune response.

b. Secretion is controlled by CRH (corticotropin releasing hormone) and ACTH (adrenocorticotropic hormone) from the anterior pituitary (Figure 18.17).

4. Androgens secreted by the adrenal cortex usually have minimal effects.

C. Adrenal Medulla

1. The adrenal medulla consists of hormone-producing cells, called chromaffin cells, which surround large blood-filled sinuses.

2. Medullary secretions are epinephrine and norepinephrine (NE), which produce effects similar to sympathetic responses.

3. They are released under stress by direct innervation from the autonomic nervous system. Like the glucocorticoids of the adrenal cortex, these hormones help the body resist stress. However, unlike the cortical hormones, the medullary hormones are not essential for life.

D. Table 18.8 summarizes the hormones produced by the adrenal glands, the principal actions, and control of secretion.

X. PANCREATIC ISLETS

A. The pancreas is a flattened organ located posterior and slightly inferior to the stomach and can be classified as both an endocrine and an exocrine gland (Figure 18.18).

B. Histologically, it consists of pancreatic islets or islets of Langerhans (Figure 18.19) and clusters of cells (acini) (enzyme-producing exocrine cells).

C. Cell Types in the Pancreatic Islets

1. Alpha cells secrete the hormone glucagon which increases blood glucose levels.

2. Beta cells secrete the hormone insulin which decreases blood glucose levels.

3. Delta cells secrete growth hormone inhibiting hormone or somatostatin, which acts as a paracrine to inhibit the secretion of insulin and glucagon.

4. F-cells secrete pancreatic polypeptide, which regulates release of pancreatic digestive enzymes.

D. Regulation of glucagon and insulin secretion is via negative feedback mechanisms (Figure 18.19). See lecture notes for more detail.

E. Table 18.9 summarizes the hormones produced by the pancreas, their principal actions, and control of secretion.

XI. OVARIES AND TESTES

A. Ovaries are located in the pelvic cavity and produce sex hormones (estrogens and progesterone) related to development and maintenance of female sexual characteristics, reproductive cycle, pregnancy, lactation, and normal reproductive functions. The ovaries also produce inhibin and relaxin.

B. Testes lie inside the scrotum and produce sex hormones (primarily testosterone) related to the development and maintenance of male sexual characteristics and normal reproductive functions. The testes also produce inhibin.

C. Table 18.10 summarizes the hormones produced by the ovaries and testes and their principal actions.

XII. PINEAL GLAND

A. The pineal gland (epiphysis cerebri) is attached to the roof of the third ventricle, inside the brain (Figure 18.1).

B. The pineal secrets melatonin in a diurnal rhythm linked to the dark-light cycle. Light inhibits its secretion. In darkness, norepinephrine released by sympathetic fibers stimulates synthesis and secretion of melatonin, which may promote sleepiness.

C. Seasonal affective disorder (SAD), a type of depression that arises during the winter months when day length is short, is thought to be due, in part, to over-production of melatonin. Bright light therapy, repeated doses of several hours exposure to artificial light as bright as sunlight, may provide relief for this disorder and for jet lag.

XIII. THYMUS GLAND

A. The thymus gland secretes several hormones related to immunity .

B. Thymosin, thymic humoral-factor, thymic factor, and thymopoietin promote the proliferation and maturation of T cells, a type of white blood cell involved in immunity.

XIV. OTHER HORMONES and GROWTH FACTORS

A. Other endocrine cells

1. Several body tissues other than those usually classified as endocrine glands also contain endocrine tissue and thus secrete hormones.

B. Eicosanoids

1. Eicosanoids, (prostaglandins [PGs] and leukotrienes [LTs]) act as paracrines and autocrines in most body tissues by altering the production of second messengers, such as cyclic AMP.

2. Prostaglandins have a wide range of biological activity in normal physiology and pathology.

3. Aspirin and related nonsteroidal anti-inflammatory drugs (NSAIDS), such as ibuprofen and acetaminophen, inhibit a key enzyme in prostaglandin synthesis and are used to treat a wide variety of inflammatory disorders.

C. Growth Factors

1. Growth factors are hormones that stimulate cell growth and division.

2. Examples include epidermal growth factor (EGF), platelet-derived growth factor (PDGF), fibroblast growth factor (FGF), nerve growth factor (NGF), tumor angiogenesis factors (TAFs), insulinlike growth factor (IFG), and cytokines.

XIV. DISORDERS: HOMEOSTATIC IMBALANCES

You are responsible for knowing the various endocrine disorders described on pp. 625 – 627 as they will help in your understanding of the functioning of the endocrine system.