The Kidney and Function of the Nephron

Question 1

What is the cortex?

Answer 1

Outer region of the kidney made of Bowman’s capsules, tubules and blood vessels.

Question 2

What is the medulla?

Answer 2

Darker, inner region of the kidney made from loops of Henle, collecting ducts and blood vessels.

Question 3

What is the pelvis?

Answer 3

A cavity within the kidney where urine starts to collect.

Question 4

What is the ureter?

Answer 4

A tube that carries urine from the kidney to the bladder.

Question 5

What is Bowman’s capsule?

Answer 5

The structure found at one end of the nephron that contains the glomerulus.

Question 6

What type of cells line the inside of Bowman’s capsule?

Answer 6

Podocytes

Question 7

What is the proximal convoluted tubule?

Answer 7

A tubule that connects the glomerulus to the loop of Henle.

Question 8

What is the loop of Henle?

Answer 8

A loop that extends from the cortex, through the medulla, and back into the cortex again.

Question 9

What is the distal convoluted tubule?

Answer 9

The tubule closest to the collecting duct

Question 10

What is the collecting duct?

Answer 10

The tube from which many nephrons are connected to, which transports urine into the pelvis.

Question 11

Where is the afferent arteriole and what does it do?

Answer 11

Supplies the nephron with blood and its capillaries extend into the glomerulus.

Question 12

Where is the efferent arteriole and what does it do?

Answer 12

Leaves Bowman’s capsule and supplies the loop of Henle with blood

Question 13

Name the 4 stages of osmoregulation.

Answer 13

Formation of glomerular filtrate
Reabsorption by the proximal convoluted tubule
Maintenance of ion gradient by loop of Henle
Reabsorption of water by distal convoluted tubule

Question 14

Describe the structure of glomerular capillaries.

Answer 14

Endothelial cells with pores between them so substances can leak out

Question 15

Why does hydrostatic pressure build in the glomerulus?
How does this lead to formation of filtrate?

Answer 15

Diameter of afferent arteriole greater then efferent arteriole.
This causes glomerular filtrate to squeeze out between pores in capillaries.

Question 16

What makes up glomerular filtrate?

Answer 16

Water, ions, glucose

Question 17

Why are blood cells and proteins not squeezed out of capillaries during the formation of glomerular filtrate?

Answer 17

They are too large

Question 18

Why do epithelial cells in the proximal convoluted tubule have microvilli?

Answer 18

Large SA for reabsorption from filtrate

Question 19

Why do epithelial cells in the proximal convoluted tubule have infoldings in their bases?

Answer 19

To increase SA so reabsorbed substances can be transferred to capillaries

Question 20

Why do epithelial cells in the proximal convoluted tubule have high numbers of mitochondria?

Answer 20

To produce ATP for active transport

Question 21

Name the ion actively transported out of cells lining the proximal convoluted tubule.
Is the conc of this ion now higher or lower in these cells?

Answer 21

Na+ actively transported out.
Na+ conc lower inside cells lining proximal convoluted tubule.

Question 22

Na+ leaves the lumen of the proximal convoluted tubule by what transport process?
Where do the Na+ ions end up?

Answer 22

Na+ leaves the lumen by facilitated diffusion in carrier proteins and ends up in the epithelial cells lining the tubule.

Question 23

Explain how cotransport of glucose/amino acids is involved in reabsorption in proximal convoluted tubule.

Answer 23

Facilitated diffusion of Na+ often happens alongside glucose or amino acids, so glucose/amino acids also enter cells lining the proximal convoluted tubule.

Question 24

Explain how glucose/amino acids are absorbed into the blood during reabsorption from proximal convoluted tubule.

Answer 24

Once they have co transported into epithelial cells lining the proximal convoluted tubule, they diffuse into the blood.

Question 25

What is the main responsibility of the loop of Henle?

Answer 25

Absorbs water from the collecting duct, concentrating urine and ensuring it has a lower water potential than the blood.

Question 26

Describe the structure and permeability of the descending limb of the loop of Henle.

Answer 26

Thin narrow walled. Highly permeable to water, impermeable to salts .

Question 27

Describe the structure and permeability of the ascending limb of the loop of Henle.

Answer 27

Wider and thicker walls. Walls impermeable to water but permeable to ions.

Question 28

Why does water leave the descending limb by osmosis?
Where does this water go?

Answer 28

Because walls are highly permeable to water.
Water then enters capillaries

Question 29

As you go down the descending limb, how does water potential of filtrate change?

Answer 29

Water potential decreases, leaving the filtrate highly concentrated.

Question 30

Whereabouts in the loop of Henle will water potential be at its lowest?

Answer 30

At the tip

Question 31

As water leaves the descending limb the loop of Henle, how does the water potential of the medulla compare to the water potential of the descending limb?

Answer 31

Water potential of medulla higher than in descending limb.

Question 32

At the base of the ascending limb, where do sodium ions start to move and by what transport process?

Answer 32

Na+ ions leave the ascending limb by diffusion as the filtrate is highly concentrated.

Question 33

As you go up the ascending limb, sodium ions to leave the filtrate by what transport process and how does this change the water potential of the filtrate?

Answer 33

Sodium ions leave by active transport and water potential of filtrate raises.

Question 34

Describe the water potential gradient between the cortex and medulla between the ascending limb and collecting duct.

Answer 34

Water potential is higher in the cortex and lower in the medulla.

Question 35

As the filtrate reaches the collecting duct, water starts to leave by osmosis - where does it go?
How does this change water potential of the filtrate?

Answer 35

Water passes into surrounding capillaries.
This lowers water potential of the filtrate.

Question 36

Why do cells in the distal convoluted tubule contain microvilli and lots of mitochondria?

Answer 36

Microvilli maximise surface area.
Mitochondria produce ATP for active transport

Question 37

What does the distal convoluted tubule do for reabsorption?

Answer 37

Makes final adjustments to water/salts absorbed and controls blood pH by selecting the ions reabsorbed.