5:1:4 Hormonal Communication

Question 1

What is the endocrine system

Answer 1

A system of endocrine glands which produce hormones, which are chemical messengers to be carried in the blood and transfer information to control functions

Question 2

Label the endocrine system

Answer 2

Question 3

What do hormones do

Answer 3

• They are transported directly into the bloodstream, by endocrine glands
• They are transported around the body to target cells/tissues to bring about a response
• They only affect cells with receptors that the specific hormone can bind to to create and effect (complementary binding)

Question 4

Describe how hormones are first and second messengers

Question 5

Describe how first and second messengers carry out the action of a hormone

Answer 5

• The first messenger is the hormone that brings the information from the endocrine gland, and bind to the receptor on the cell surface membrane
• The second messenger inside the camel causes the effect (e.g. cAMP)

Question 6

Describe the structure and function of the adrenal glands

Answer 6

• Situated above each kidney, and consist of a central medulla and outer cortex
• Cortex produces steroid hormones (e.g. aldosterone to regulate salt/water in blood, and cortisol the stress hormone to regulate metabolism)
• Medulla produces adrenaline, which is produced at times of stress/excitement to prepare the body for emergency situations (fight or flight)

Question 7

What is the pancreas

Answer 7

• Organ found in the abdomen of animals
• Functions as an endocrine and exocrine gland

Question 8

What is the difference between endocrine and exocrine glands

Answer 8

Endocrine glands secrete hormones directly into the blood, whilst exocrine glands secrete substances via a duct

Question 9

What is the exocrine function of the pancreas

Answer 9

• To produce pancreatic juice (contains digestive enzymes) to be delivered to the small intestine to assist digestion
• These enzymes are secreted by exocrine tissue

Question 10

What is the endocrine function of the pancreas

Answer 10

• To product the hormones glucagon and insulin
• Islets of langerhans produce hormones within the pancreas, which contain alpha cells which secrete glucagon, and beta cells which secrete insulin

Question 11

How is the histology of the pancreas studied

Answer 11

• Sections are stained and viewed under the microscope

Question 12

What are the factors affecting blood glucose concentration

Answer 12

• Absorption in the gut following carbohydrate digestion
• Hydrolysis of glycogen stores
• Non-carbohydrates that have been converted to glucose

Question 13

How is blood glucose concentration controlled

Answer 13

• If the concentration of glucose in the blood decreases, cells may not have enough glucose to respire
• If the concentration of glucose in the blood increases, this can disrupt the normal function of cells
• Blood glucose in controlled by two hormones secreted by the islets of langherhans in the pancreas
• The islets of langherhans contain alpha cells which secrete glucagon, and beta cells which secret insulin
• These hormones act as receptors to control blood glucose levels

Question 14

Describe how the body responds to a decrease in blood glucose concentration

Answer 14

• The decrease is detected by the alpha cells, which start secreting glucagon and the beta cells which stop secreting insulin
• The decrease of blood insulin conc. reduces the use of glucose by liver and muscle cells
• Glucagon binds to receptors in the cell surface membrane of liver cells, causing a conformational change that activates the G protein
• The activated G protein activates enzyme adenylyl cyclase, which catalyses the conversion of ATP to the second messenger cyclic AMP
• cAMP binds to protein kinase A enzymes and activated them, causing them to activate glycogen phosphorylase enzymes which catalyse the breakdown of glycogen to glucose in a process called glycogenolysis

Question 15

How does adrenaline increase blood glucose concentration

Answer 15

• It binds to different receptors on the surface of liver cells that activate the same enzyme cascade and lead to glycogenolysis to produce glucose
• It also stimulates the breakdown of glycogen stores in muscles during exercise

Question 16

Describe how the body responds to an increase in blood glucose concentration

Answer 16

• The beta cells in the pancreas detect the increase in blood glucose levels, due to the glucose molecules entering the beta cells via facilitated diffusion
• The cells respire the glucose and produce ATP
• High ATP levels cause the potassium channels in the beta cells to close, changing the membrane potential
• This change causes the voltage gated calcium channels to open, and the beta cells recieve an influx of Ca2+ ions
• This causes the beta cells to secrete insulin, which moves in vesicles through the bloodstream and stimulates the uptake of glucose by muscle and fat cells and the liver

Question 17

Describe the action of insulin

Answer 17

• Muscle, fat, and liver cells possess glucose transporter protein, which are the target cells of insulin
• They allow the uptake of glucose molecules via facilitated diffusion, and are insulin sensitive
• Insulin binds to receptors on the target cells, which stimulates then to activate more glucose transporter proteins to their cell surface membrane, increasing the rate of glucose uptake
• Additionally, insulin increases the uptake of glucose in the liver by stimulating glycogenesis
• As glucose enters the liver an enzyme converts it to glucose phosphate, then to glycogen, lowering the glucose concentration

Question 18

How is blood glucose concentration regulated by a negative feedback control mechanism

Answer 18

• Receptors (alpha and beta cells) detect whether glucose levels are too high/low
• This is communicated through the hormone system (using glucagon and insulin)
• Effectors (liver/muscle/fat cells) react to bring the level back to normal

Question 19

What is glycogenesis

Answer 19

• The synthesis of glycogen from glucose molecules
• Insulin triggers this process after it detects high blood glucose molecules

Question 20

What is glycogenolysis

Answer 20

• The breakdown of glycogen to produce glucose molecules
• Glucagon triggers this process after detecting low blood glucose levels

Question 21

What is gluconeogenesis

Answer 21

• The synthesis of glucose molecules from non-carbohydrate molecules
• Triggered by glucagon which activates enzymes in the liver which convert the non-carbohydrate molecules

Question 22

What is diabetes

Answer 22

• A condition in which the homeostatic control of blood glucose has failed or deteriorated
• Insulin function is disrupted allowing blood glucose concentration to rise
• Type I and type II

Question 23

What is type I diabetes

Answer 23

• A condition where the pancreas fails to produce sufficient insulin to control blood glucose levels, normally beginning in childhood as an autoimmune response by attacking the beta cells
• The lack of insulin affects glucagon stores, resulting in fatigue
• High levels of blood glucose can result in organ damage

Question 24

How is type I diabetes treated

Answer 24

• Insulin injections after monitoring blood glucose levels and diabetes appropriate diet
• Insulin injections can be fast or slow acting depending on the different levels of control

Question 25

What is type II diabetes

Answer 25

• More common and usually develops in those aged 40 and over
• Pancreas still produces insulin, but the receptors have reduced/don’t respond therefore have reduced sensitivity to insulin
• This causes a reduced glucose uptake which leads to high blood glucose concentrations, leading to beta cells producing excess insulin which damages them

Question 26

What are treatments for type II diabetes

Answer 26

• Sugar and fat controlled diets
• Exercise regimes

Question 27

What are known risk factors of type II diabetes

Answer 27

• Obesity
• Physical inactivity
• High blood pressure
• High blood cholesterol
• Generics

Question 28

Why is high blood pressure associated with diabetes

Answer 28

• High blood glucose concentration lowers the water potential of the blood, causing water to move into the tissues via osmosis
  X Causing a larger volume of blood in the circulatory system

Question 29

How can stem cells produce insulin

Answer 29

• Stem cells can be treated to differentiate into pancreatic beta cells
• These cells can be transplanted into the pancreas of the diabetic individual to allow them to produce insulin
• This is only an early stage research idea

Question 30

How can insulin be produced using GM bacteria

Answer 30

• DNA can be altered by adding nucleotides from another source
• The transgenic organism is classed as GM, and it’s recombinant DNA is used to produce proteins which can be manipulated to the original form of insulin
• Bacteria plasmids are modified to include the human insulin gene, which are then inserted into bacteria and then the body
• Administered intravenously instead of orally so the enzyme protease doesn’t digest it before it reaches the bloodstream

Question 31

What are the advantages of producing insulin using GM bacteria

Answer 31

• Identical to human insulin
• Reliable supply available
• Fewer ethical/moral/religious concerns
• Fewer rejection problems, side effects or allergic reactions
• Cheaper to produce
• Useful for those who have animal insulin intolerance