The Endocrine System

The Endocrine System Anatomy Ch. 9

Hormones • Hormones are chemical substances that are secreted by endocrine cells into the extracellular fluids and regulate the metabolic activity of other cells in the body. • Nearly all hormones can be classified as either amino acid based molecules (proteins, peptides, and amines) or steroids. • All hormones are amino acid based except for sex hormones and the hormones of the adrenal cortex.

A hormone affects only certain tissue cells or organs which are called target cells or organs. • For a target cell to respond to a hormone the target cell must have specific protein receptors on the plasma membrane that the hormone can attach to.

The term hormone comes from the Greek word meaning “to arouse”. • Hormones bring about their effects on the body’s cells by altering the cells activity. • These alterations may include increasing or decreasing the rate of a normal metabolic process

Changes that occur due to hormone binding: • Permeability of the plasma membrane • Formation of proteins or enzymes in the cell • Activation or deactivation of enzymes • Stimulation of mitosis (cell division) • Increasing secretion

Mechanisms of hormone changes in the cell • Direct Gene Activation • Used by steroids • The steroids diffuse through the plasma membrane of the target cell • The steroid enters the nucleus • The steroid binds to a specific receptor in the nucleus • The new combination of the hormone and receptor binds to a specific site on the DNA • The binding with the DNA causes certain genes to form mRNA. • The mRNA sends information out of the nucleus and new proteins are made.

Second Messenger System • Used by acid based molecules • These hormones are not able to enter the target cell so they bind to hormone receptors on the target cells plasma membrane. • The hormone which is the first messenger binds to a membrane receptor. • This binding sets off a series of reactions that activates an enzyme. • The enzyme causes a reaction that will produce the second messenger in the cell. • The role of the second messenger is to oversee any changes in the cell and promote the response of the target cell to the hormone. • There are many different second messengers.

Control of hormone release • Negative feedback mechanisms are the primary means of regulating blood levels of nearly all hormones. • There are 3 categories of stimuli that activate endocrine organs: • Hormonal stimuli • The most common type of stimuli in which endocrine organs are prodded into action by other hormones • Humoral stimuli • Changing blood levels of certain ions and nutrients stimulate hormone release • Neural stimuli • Nerve fibers stimulate hormone release

The major endocrine organs • The major endocrine organs of the body include the: • Pituitary gland • Thyroid gland • Parathyroid gland • Adrenal gland • Pineal gland • Thymus • Pancreas • Gonads (testes and ovaries)

The hypothalamus is part of the nervous system but is also recognized as a major endocrine organ. • The function of some gland is purely endocrine (pituitary, thyroid, adrenals, and parathyroid). • Other glands, such as the pancreas and gonads, have both endocrine and exocrine functions. • Endocrine glands are ductless glands which means that hormones that are produced are released into blood or lymph. • Exocrine glands release products at the body’s surface or into body cavities through ducts.

Pituitary-hypothalamus relationship • The anterior pituitary gland controls the activities of so many other glands that it is sometimes called the master gland. • The release of each hormone from the pituitary gland is controlled by hormones produced by the hypothalamus. • The pituitary gland is connected to the hypothalamus. • The hypothalamus produces 2 hormones, oxytocin and antidiuretic, which are stored and released by the posterior pituitary gland.

Anterior Pituitary hormones • Growth Hormone (GH) • Growth of skeletal muscles and long bones • Prolactin (PRL) • Stimulates and maintains milk production in the mother’s breasts. • Adrenocorticotropic Hormone (ACTH) • Regulates the endocrine activity of the cortex portion of the adrenal gland • Thyroid-stimulating Hormone (TSH) • Influences the growth and activity of the thyroid gland • Follicle-stimulating Hormone (FSH) • Stimulates development of sperm and egg cells • Lutenizing Hormone (LH) • Triggers ovulation of the egg and produces progesterone and estrogen in females • Stimulates testosterone production in males

Posterior pituitary hormones • Oxytocin • Released in significant amounts only during childbirth and in nursing women. • Stimulates powerful contractions of the uterus during childbirth • Causes milk ejection in a nursing woman • Antidiuretic Hormone (ADH) • Causes the kidneys to reabsorb more water from forming urine. As a result urine volume decreases and blood volume increases. • Increases blood pressure by causing constriction of arterioles. Because of this function it is sometimes called vasopressin.

Thyroid hormones • Thyroxine (T4) & Triiodothyronine (T3) • Both control the rate at which glucose is burned and converted into body heat and energy. • Every tissue in the body is a target • Important for normal tissue growth and development • The major metabolic hormones • Difference is in the number of bound iodine atoms. • Calcitonin • Decreases blood calcium levels by causing calcium to be deposited in the bones

Parathyroid hormones • Parathyroid Hormone (PTH) • The most important regulator of calcium levels in blood. • Stimulates the breakdown of bone matrix to release calcium into the blood and increase blood calcium levels.

Adrenal Cortex Hormones • Aldosterone (outer most of the cortex) • Regulates mineral content of the blood, particularly sodium and potassium. • The target is the tubules of the kidneys that either reabsorb minerals or allow them to be flushed out of the body as urine. • When aldosterone levels rise the kidneys reabsorb more sodium and secrete more potassium. • When more sodium is reabsorbed then more water is absorbed. • Aldosterone regulates both water and electrolyte balance.

Aldosterone also assists in the regulation of blood pressure. • Renin is an enzyme produced in the kidneys when blood pressure drops and causes the release of aldosterone. Blood pressure increases. • A hormone released by the heart called atrial natriuretic peptide (ANP) prevents aldosterone release and therefore reduces blood pressure.

Cortisone and Cortisol (middle layer of the cortex) • Increase blood glucose levels (hyperglycemic) • Decrease inflammation and reduce pain by inhibiting pain causing molecules called prostaglandins • Often prescribed as drugs to suppress inflammation.

Androgens and Estrogens (inner most cortex) • Sex hormones • Androgens (males) • Estrogens (females)

Adrenal medulla hormones • Epinephrine (adrenaline) • Norepinephrine (noradrenaline) • Both are released as part of the sympathetic division of the ANS (fight or flight) • Both are pumped into the blood stream in enhance and prolong the effects of the sympathetic division. • Increase heart rate, blood pressure, and blood glucose levels, and dilate the small passageways of the lungs • The result is more oxygen and glucose in the blood. • Both hormones help the body to deal with short term stressful situations.

The hormones of the medulla help the body to cope with brief short term stressors. • The hormones of the cortex help the body to deal with prolonged stressors.

Pancreas hormones • Insulin • High levels of glucose in the blood cause the release of insulin into the blood • Insulin is responsible for the storage of glucose as glycogen when blood levels are too high • Insulin is hypoglycemic because it decrease the levels of glucose in blood. • Glucagon • Low levels of glucose in the blood cause the release of glucagon into the blood • Glucagon causes the breakdown of glycogen • Glucagon is hyperglycemic because it increases glucose levels. • Target organ is the liver

Pineal hormone • Melatonin • Levels rise and fall during the night and day • Peak levels occur at night making us drowsy and sleepy. • The lowest levels occur during the daylight hours peaking around noon. • Sleep trigger that plays a role in establishing the body’s day and night cycle. • Helps to coordinate the hormones of fertility. • Inhibits the reproductive system until adult body size has been reached.

Thymus hormone • The thymus is largest in infants and children and decreases in size as you reach adulthood. • Thymosin • Are essential for normal development of T- lymphocytes (white blood cells). • Important in the immune response of children.

gonads • Ovaries • Estrogen • Development of sex characteristics in women (primarily growth and maturation of reproductive organs). • Responsible for appearance of secondary sex characteristics. • Development of breasts • Pubic hair • Widening of the hips • Increased body fat

Progesterone • Acts with estrogen to bring about the menstrual cycle and breast development. • Quiets the muscles of the uterus so that an implanted embryo will not be aborted. • Helps prepare breast tissue for lactation.

Testes • Androgens: male sex hormones • Testosterone • Promotes the growth and maturation of the reproductive organs • Causes secondary sex characteristics • Facial hair • Development of bones and muscles • Lowering voice • Continuous production of sperm

The Endocrine System