1. Chapter 45 Chemical Signals in Animals

2. Hormones are chemical signals.  The endocrine system consists of:  Endocrine cells which are hormone-secreting cells and  Endocrine glands which are hormone- secreting organs. Specific target cells respond to specific hormones.

3. Homeostasis Growth and Development Reproduction Energy Metabolism Behavior

4. blood glucose low stimulates glucagon from pancreas glucose release from liver stimulates blood glucose high inhibits

6. response endocrine cell target cell hormones receptor protein

7. response endocrine cell target cell hormones intracellular receptor

8. Tropic hormones- stimulate the production and secretion of hormones by other endocrine glands; ex. TSH Nontropic hormones- stimulates cellular growth, metabolism, or other functions; ex. thyroxine

9.  Invertebrates have a wide variety of hormones that are involved in the regulation of homeostasis. Invertebrate nervous systems clearly illustrate endocrine and nervous system interactions

10.  An example from hydra:  One hormone stimulate asexual reproduction.  Another hormone prevents sexual reproduction.  An example from a mollusk:  The hormone that regulates egg laying also inhibits feeding and locomotion.

11.  Arthropods have extensive endocrine systems regulating molting in insects and crustaceans.  The regulation of molting in insects.  Ecdysone also promotes the development of adult features.  Neurosecretory cells in the brain produce Prothoracicotropic hormone (PTTH), which regulates the secretion of ecdysone. Juvenile hormone (JH) promotes the retention of larval characteristics.

13. Different signal-transduction pathways in different cells can lead to different responses to the same signal.

14. Frog Metamorphosis thyroxin

15. Fig. 45-10 Major endocrine glands: Adrenal glands Hypothalamus Pineal gland Pituitary gland Thyroid gland Parathyroid glands Pancreas Kidney Ovaries Testes Organs containing endocrine cells: Thymus Heart Liver Stomach Kidney Small intestine

16. pineal gland hypothalamus pituitary gland

17. Secreted directly in CSF to blood High levels at night make us sleepy; low level during day Pineal gland is stimulated by darkness and inhibited by light Function in regulating circadian rhythms (sleep, body temp, appetite)  biological clock Produces melatonin (synthesized from seratonin, a derivative of tryptophan)

18. hypothalamus anterior pituitary posterior pituitary

19. Hypothalamus Anterior Pituitary Posterior Pituitary

20. Antidiuretic Hormone (ADH) Oxytocin (+ feedback)

21. Hypothalamus Posterior Pituitary Anterior Pituitary

22. Growth Hormone (GH) - Dwarfism - Gigantism & Acromegaly Thyroid Stimulating Hormone (TSH) Adrenocorticotropic Hormone (ACTH) Gonadotropins (FSH, ICSH, LH) Prolactin (PRL) Melanocyte-stimulating Hormone (MSH)

23. Acts on the liver, stimulating it to release several polypeptide hormones. Stimulates amino acid uptake and protein synthesis in target cells. Ultimately stimulates cell growth (cell size and number), especially in muscle and bone. Also stimulates fat breakdown.

24. GH Levels awake sleep strenuous exercise

25. hyposecretion of GH Dwarfism Kenadie - worlds smallest girl due to primordial dwarfism Little People Big World

26. hypersecretion of GH Gigantism Bao Xishun, a 7ft 8.95in herdsman from Inner Mongolia

27. Acromegaly hypersecretion of GH 7 ft 1 ¼ inches

28. Thyroid-Stimulating Hormone (TSH) Acts on the thyroid gland, stimulating it to release T3 & T4 These thyroid hormones increase glucose catabolism and body heat production. Negative feedback mechanism involved in regulating levels.

29. Adrenocorticotropic Hormone (ACTH) Acts on the adrenal cortex, stimulating it to secrete glucocorticoids (e.g., cortisol). Glucocorticoids promote the synthesis of glucose from noncarbohydrate sources such as amino acids, and fatty acids Negative feedback mechanism involved in regulating levels.

30. thyroid trachea larynx

32. Thyroxine (T 4 ) Triiodothyronine (T 3 ) Both control metabolic rate and cellular oxidation Calcitonin (from parafolicular cells)- lowers blood CA ++ levels and causes CA ++ reabsorption in bone Thyroid gland selectively uptakes iodine to produce T 3 & T 4

33. Thyroid Hormone Regulation

34. -Hyperthyroidism (Grave’s, Goiter) -Hypothyroidism (Cretinism, Myxedima) Thyroid Disorders

35. Goiter Lack of iodine in diet hyposecretion of T3 & T4

36. Cretinism

37. Myxedema hyposecretion of T3 & T4 myxedema After thyroid treatment

38. Exophthalmos- hyperthyroidism

40. PTH release: 1)stimulates osteoclasts 2)enhances reabsorption of Ca ++ by kidneys 3)increases absorption of Ca ++ by intestinal mucosal cells Hyperparathyroidism- too much Ca ++ drawn out of bone; could be due to tumor Hypoparathyroidism- most often follow parathyroid gland trauma or after removal of thyroid--- tetany, muscle twitches, convulsions; if untreated  respiratory paralysis and death

43. Regulates glucose uptake by cells Controlled via negative feedback: insulin & glucagon Blood sugar level: 90 mg/mL

45. Produced by the  cells of the Islets of Langerhan Catalyze oxidation of glucose for ATP production Lowers blood glucose levels by promoting transport of glucose into cells. Stimulates glucose uptake by the liver and muscle cells. Stimulates glycogen synthesis in the liver and muscle cells. Also stimulates amino acid uptake and protein synthesis of muscle tissue

46. Produced by the  cells of the Islets of Langerhans Stimulates change of glycogen to glucose in the liver. Synthesis of glucose from lactic acid and non carbohydrate molecules such as fatty acids and amino acids Causes  in blood glucose concentration hypoglycemic- low blood sugar  ; deficient in glucagon

49. Type I Diabetes hyposecretion of insulin insulin dependant juvenile onset Type II Diabetes late onset (adult) insensitivity of cells to insulin manage by exercise & diet

50. Adrenal Glands adrenal cortex adrenal medulla

52. Hormones of the Adrenal Medulla Adrenalin (epinephrine): converts glycogen to glucose in liver Noradrenalin (norepinephrine): increases blood pressure (sympathetic nervous system) Corticosteroids:  glucose levels)

53. Hormones of the Adrenal Cortex Glucocorticoids- cortisol 1.Decrease protein synthesis 2.Increase release and use of fatty acids 3.Stimulates the liver to produce glucose from non carb’s Mineralcorticoids- aldosterone 1.Stimulates cells in kidney to reabsorb Na+ from filtrate 2.Increases water reabsorption in kidneys 3.Increases blood pressure Sex Steroids- small amts (androgens) 1.Onset of puberty 2.Sex drive

54. Cushing’s Syndrome Hypersecretion of cortisone; may be caused by an ACTH releasing tumor in pituitary Symptoms: trunkal obesity and moon face, emotional instability Treatment: removal of adrenal gland and hormone replacement

55. Addison’s Disease Hyposecretion of glucocorticoids and mineral corticoids; Symptoms- wt loss, fatigue, dizziness, changes in mood and personality, low levels of plasma glucose and Na+ levels, high levels of K+ Treatment- corticosteroid replacement therapy

56. Located anterior to the heart Produces- thymopoetin and thymosin  helps direct maturation and specialization of T-lymphocytes (immunity) Thymus

57. Ovaries- produce estrogen and progesterone  responsible for maturation of the reproductive organs and 2ndary sex characteristics in girls at puberty Gonads

58. Female Reproductive System

59. Testes- produce sperm and testosterone (initiates maturation of male repro organs and 2ndary sex characteristics in boys at puberty) Gonads

60. Male Reproductive System