Formation of urine

Question 1

What are the 5 major stages of urine formation?

Answer 1

1: Glomerulus: Filtration of blood
2: Proximal tubule:

• Reabsorption of filtrate
• Secretion into tubule

3: Loop of Henle: Concentration of urine
4: Distal tubule: Modification of urine
5: Collecting duct: Final modification of urine

Question 2

What are the 3 major functions of the nephron?

Answer 2

FILTRATION of blood to produce a filtrate

REABSORPTION of water, ions and organic nutrients

from filtrate

SECRETION of waste products into tubular fluid

Question 3

Answer 3

Question 4

What is the force for filtration?

Answer 4

–Blood pressure

–Differing diameter of afferent and efferent arterioles

Question 5

What is glomerular filtration rate?

Answer 5

Glomerular Filtration

Rate (GFR) = 125 mL/min (º 180 L/day)

Normal plasma volume = 2-3 L

= Rate at which glomerular filtrate is produced

• GFR can be measured clinically and used as an

indicator of renal function

Question 6

What is the first stage of urine formation?

Answer 6

Ultrafiltration: filtration on a molecular scale

All small molecules are filtered:

• Electrolytes
• Amino acids
• Glucose,
• Metabolic waste
• Some drugs, metabolites

Cells and large molecules remain in the blood:

• Red blood cells
• Lipids
• Proteins,
• Most drugs, metabolites

Question 7

What is filtration dependant on?

Answer 7

Filtration is dependent on two factors:

blood pressure

renal blood flow

Question 8

What does the filtrate have to pass through during glomerular filtration?

Answer 8

Filtrate has to pass through

(in sequence):

1: Pores in glomerular capillary endothelium
2: The basement membrane of Bowman’s capsule

(includes contractile mesangial cells)

3: Epithelial cells of Bowman’s capsule (Podocytes) via filtration slits into capsular space

Question 9

What are the 4 types of pressure in the glomerulus?

Answer 9

Question 10

What are the equations for pressure in and out of the glomerulus?

Answer 10

Question 11

What is the equation for filtration pressure?

Answer 11

Question 12

What type of pressure is shown?

Answer 12

Question 13

How does filtration pressure change from the start of the glomerulus to the end?

Answer 13

Question 14

How does blood pressure change GFR?

Answer 14

GFR generally remains constant even when systemic BP changes

This involves a regulatory mechanisms known as autoregulation of renal blood flow

Question 15

What is autoregulation of renal blood flow?

Answer 15

Renal blood flow subject to autoregulation over broad range of systemic BPs (90-200 mmHg)

Autoregulation persists in denervated kidneys and isolated perfused kidneys …so it is NOT a neuronal or hormonal response but instead, a local effect

Question 16

What are the 2 hypotheses for the autoregulation of renal blood flow?

Answer 16

Myogenic - autoregulation is due to response of renal arterioles to stretch (re: Starling’s Law):

e.g. if BP decreases, renal artery and efferent arterioles automatically constrict to maintain a constant renal blood flow (1,200mL/min) and GFR (~125 mL/min)

Metabolic - renal metabolites modulate afferent and efferent arteriolar contraction and dilation (e.g. adenosine, nitric oxide)

Most likely to be a combination of both

Question 17

_______ and glomerular filtration rate (GFR)

are maintained even when systemic BP changes (______ mmHg)

Answer 17

Renal blood flow (RBF) and glomerular filtration rate (GFR)

are maintained even when systemic BP changes (90-200 mmHg)

Question 18

Complete the diagram on the mechanisms of glomerulus blood vessels

Answer 18

Question 19

How can changes in GFR alter systemic blood pressure?

Answer 19

1. A drop in filtration pressure (e.g. due to declining BP) causes a drop in GFR
   2: Lower GFR means less Na+ enters the proximal tubule
   3: The macula densa senses a change in tubular Na+ levels
   4: This stimulates juxtaglomerular cells to release renin into the blood
   5: Renin release leads to generation of angiotensin II
   6: Ang II is a vasoconstrictor which causes BP to increase
   7: Increased BP causes filtration

pressure to increase and

GFR returns to normal

Question 20

Complete the diagram on the RAS system

Answer 20

Question 21

Answer 21

Question 22

What are the 5 major stages in the process of urine formation?

Answer 22

1: Glomerulus: Filtration of blood
2: Proximal tubule:

• Reabsorption of filtrate
• Secretion into tubule

3: Loop of Henle: Concentration of urine
4: Distal tubule: Modification of urine
5: Collecting duct: Final modification of urine

Question 23

What is reabsorbed from the proximal tubule?

Answer 23

60-70% of filtered water, Na+, HCO3-, Cl-, K+ and urea are reabsorbed from the PT

There is almost complete reabsorption of:

– Glucose

– Amino acids

– Small amount of filtered

proteins

Question 24

What is the driving force for reabsorption from the proximal tubule?

Answer 24

The driving force for this reabsorption is Na+K+ATPase

Question 25

How does Na+-K+-ATPase drive reabsorption?

Answer 25

Na+-K+-ATPase pumps out Na+ from cells into the blood against chemical and electrical gradients

This process requires energy in the form of adenosine triphosphate (ATP)

Accompanied by entry of K+ ions which rapidly diffuses out of cell

The ratio of transport is 3 Na+ leaving cell: 2 K+ entering cell

Question 26

How does sodium reabsorption happen in the proximal tubule?

Answer 26

PT cells have a low intracellular Na+ concentration (less than 30 mM) due to the action of the Na+K+ATPase.

PT cells have an overall negative charge due to the presence of intracellular proteins.

Therefore Na+ enters PT cells.

Cl- follows Na+ by facilitated diffusion. Phosphate (PO42-) and sulphate (SO42-) are also co-transported with Na+

Question 27

How does water reabsorption occur in the proximal tubule?

Answer 27

60-70 % filtered water reabsorbed in the PT - active transport of Na+ out Of PT cells is the driving force

Movement of solutes (Na+, HCO3- and Cl-) reduces osmolality of tubular fluid…and increases osmolality of interstitial fluid

A net flow of water from tubule lumen to lateral spaces occurs by transcellular and paracellular routes

Transcellular routes involve aquaporin (AQP) channels located on apical and basolateral surfaces

Question 28

Is the reabsorption of water in the proximal tubule an active process?

Answer 28

There is no active water reabsorption along nephron - it occurs by osmosis and it follows sodium

Question 29

What routes does water take to be reabsorbed from the proximal tubule?

Answer 29

PT is highly permeable to water. Water flow from tubule lumen to lateral spaces occurs by paracellular and transcellular routes

Question 30

What transcellular routes does water take to be reabsorbed from the proximal tubule?

Answer 30

Transcellular routes involve aquaporins (AQPs) – specific water channels located in the cell membranes. 13 different types identified, 6 in the kidney, these are the 4 major renal AQPs:

Question 31

What are the aquaporin channels in the proximal tubule?

Answer 31

Aquaporin-1 (AQP1): Abundant distribution in proximal tubule. Also other parts of tubule where water is reabsorbed, e.g. descending limb of LOH

Aquaporin-2 (AQP2): Present in collecting duct on apical surface AQP-2 channel expression is controlled by antidiuretic hormone (ADH)

Aquaporins-3 & 4 (AQP3 & AQP4): Present on basolateral surface of tubular cells involved in water reabsorption

Question 32

How is glucose reabsorbed from the proximal tubule?

Answer 32

Glucose is co-transported into the PT cell with sodium

Glucose is co-transported into the PT cell with sodium

very efficiently so very little is excreted…

Question 33

Answer 33

Question 34

Why do diabetics get glucose in their urine?

Answer 34

Question 35

How do SGLT2 inhibitors work?

Answer 35

New Drugs for Controlling Type II Diabetes?

Idea here is to make diabetic patients excrete more glucose leading to an overall hypoglycaemic effect

Question 36

Where is the action of SGLT2 inhibitors?

Answer 36

Question 37

List some SGLT2 inhibtors

Answer 37

Dapagliflozin

Canagliflozin

Empagliflozin

Ipragliflozin

Topogliflozin

Ertugliflozin

Remogliflozin

Sergliflozin

Question 38

What other molecules are reabsorbed from the PT?

Answer 38

Potassium (K+) - 70 % of filtered K+ is reabsorbed in the PT, mostly passively via tight junctions (i.e. paracellularly)

Urea - 40–50 % filtered urea is reabsorbed passively in the PT down its concentration gradient

Amino Acids - 7 independent transport processes for reabsorbtion of AAs from the PT – depends on type of AA

• High Tm for transport so that as much as possible is reabsorbed from PT

Proteins - Reabsorbed from the PT via receptor-mediated endocytosis…

Question 39

How are proteins reabsorbed from the proximal tubule?

Answer 39

Small amounts of protein pass into filtrate via the glomerulus

These are reabsorbed by pinocytosis…

…vesicles transported into cell, degraded by lysosomes and amino acids returned to blood

Only limited transport capacity (low Tm)…

Question 40

What does proteinuria indicate?

Answer 40

…proteinuria is a sign of glomerular damage and impending renal failure

Question 41

What is the role of secretion into the PT?

Answer 41

Some endogenous substances and drugs cannot be filtered at the glomerulus…

this may be due to their size or protein binding

Specialised pumps in the PT can transport compounds from the plasma into the nephron

Question 42

What 2 pumps are used for secretion into the PT?

Answer 42

For organic acids

(e.g. uric acid, diuretics, antibiotics - penicillin)

For organic bases

(e.g. creatinine, procainamide)

Question 43

Name 3 examples of pumps used to secrete into the proximal tubule

Answer 43

OAT = Organic Anion Transporter

MRP = Multi-drug Resistance Protein

a-KG = a-ketoglutarate

Question 44

How is PAH secreted into the proximal tubule?

Answer 44

Para-amino hippurate (PAH) is secreted into PT from blood

Transported into PT cells from blood with a-ketoglutarate or other di/tri carboxylates

Transported out of PT cells in exchange for another anion present in the PT lumen

Question 45

How can PAH be used?

Answer 45

Not an endogenous compound so PAH can be used as a tool to measure tubular secretion

Question 46

Name some organic acids secreted into the PT

Answer 46

Question 47

Name some organic bases secreted into the PT

Answer 47

Question 48

Answer 48

Question 49

What is the role of the loop of henle?

Answer 49

• Tubular fluid is further modified in this part of the nephron
• The aim here is to recover fluid and solutes from the glomerular filtrate

Question 50

What are the 2 stages of the loop of henle?

Answer 50

(1) Extraction of water in the descending limb (D)
(2) Extraction of Na+ and Cl- in the ascending limb (A)

Question 51

What happens in the thin descending loop of henle?

Answer 51

(1) Extraction of water in the thin descending limb

Question 52

What are the features of the thin descending loop of henle?

Answer 52

Cells are flat, no active transport of salts (e.g. Na+, Cl-)

• But freely permeable to water via Aquaporin-1 channels
• Also some passive movement of water via tight junctions

Question 53

What happens in the thick ascending limb of the loop of henle?

Answer 53

(2) Extraction of Na+ and Cl- in the thick ascending limb

Question 54

What are the features of the thick ascending limb of the loop of henle?

Answer 54

Tubular wall is impermeable to water

• But has specialised Na+/K+/2Cl- (NKCC2) co-transporters
• Transport: Na+, K+, Cl- reabsorbed – but no water

Question 55

How does solute reabsorption occur in the ascending loop of henle?

Answer 55

The Na+/K+/2Cl- (NKCC2) co-transporter (electroneutral) transports all 3 ions into the loop of henle

+ve charge repels Ca2+, Mg2+

Question 56

What happens to the concentration of the filtrate throughout the loop of henle?

Answer 56

Fluid entering LOH from proximal tubule is isotonic (300 mOsm)

Water reabsorbed out of descending LOH

By the tip of the LOH, the filtrate is hypertonic (i.e. very concentrated, 1,200 mOsm)

Solutes (e.g. Na+, Cl-) are then pumped out of the ascending LOH

By the end of the LOH, the filtrate entering the distal tubule is hypotonic (150 mOsm)

Question 57

“But how can the concentration of the filtrate vary from isotonic (300 mOsm) to hypertonic (1,200 mOsm) to hypotonic (100 mOsm) over a short distance in the medulla?”

Answer 57

Countercurrent Multiplication

Creates large osmotic gradient within medulla

Facilitated by Na+/K+/2Cl- transport in ascending limb of LOH

Permits passive reabsorption of water from tubular fluid in descending LOH…

Question 58

What is the role of urea in countercurrent multiplication?

Answer 58

Active transport of NaCl contributes 600-1000 mOsm… the remainder is due to urea

Urea freely filtered at glomerulus

Some reabsorption in proximal tubule, but LOH and distal tubule relatively impermeable to urea

Urea can diffuse out of collecting duct into medulla down its concentration gradient

This adds to the osmolality of medullary interstitium

Question 59

What percentage is reabsorbed and where is it reabsorbed?

Answer 59

Question 60

What happens in the distal tubule?

Answer 60

–Active absorption and secretion of solutes takes place here

–Sodium (Na+) and chloride (Cl-) ions are actively reabsorbed from the tubular fluid

–This is in exchange for potassium (K+) or hydrogen (H+) ions which are secreted into the tubular fluid

Question 61

What is the role of sodium in the principle cells?

Answer 61

• Na+ and Cl- exchanged for K+ throughout the DT
• Na+ exchanged for K+ in late DT and early collecting duct
• This involves specialised cells called PRINCIPAL CELLS
• These cells are sensitive to aldosterone

Question 62

Answer 62

Question 63

What is the role of principal cells?

Answer 63

•Exchange Na+ for K+ in the late DT and early collecting duct

This involves specialised cells called PRINCIPAL CELLS which are sensitive to aldosterone

This exchange forms part of the renin-angiotensin-aldosterone system (RAAS):

Question 64

What is the role of sodium in intercalated cells?

Answer 64

•Na+ exchanged for H+ in DT and early collecting duct

• This involves specialised cells called INTERCALATED CELLS
• Subtypes exist called a and b intercalated cells

Question 65

What is the overall renal effect of aldosterone?

Answer 65

More Na+ reabsorbed so more water moves into plasma so BP increases

Question 67

What do a-intercalated cells do?

Answer 67

Secretes acid (H+) via H+/Na+ or H+/K+ exchange, involving ATPase or H+ATPase

Reabsorbs bicarbonate (HCO3-)

Question 68

What do b-intercalated cells do?

Answer 68

Secrete bicarbonate (HCO3-) via Pendrin

Reabsorbs acid (H+)

Question 69

What is ADH?

Answer 69

• Anti-diuretic hormone
• The most important hormone that regulates water balance - it is a nonapeptide with Mw of just over 1000
• Also known as ‘vasopressin’ or 8-arginine-vasopressin (to distinguish it from ADH of some other species, e.g. ADH is 8-lysine-vasopressin in pigs)

Question 70

When is the collecting duct permeable?

Answer 70

The Collecting Duct is relatively impermeable to movement of water and solutes

However, the permeability of the collecting duct can be considerably increased the action of antidiuretic hormone (ADH)

Question 71

How does ADH work?

Answer 71

• Released from the posterior pituitary subsequent to hypothalamic inputs
• ADH acts on vasopressin V2 receptors on basal membrane of principal cells in DT and collecting duct cells leading to activation of intracellular (aquaporin-2 or AQP2) water channels…

Question 72

What is the half life of ADH?

Answer 72

• Plasma half life is 10-15 min (liver and renal metabolism)

Question 73

Complete the diagram

Answer 73

Question 74

How does the concentration of the solutes change in collecting duct?

Answer 74

No net movement of solutes (water only)

Question 75

What is the effect of maximal circulating ADH?

Answer 75

•Collecting duct becomes permeable to water due to maximal AQP2 insertion so water reabsorption occurs

–Reabsorbs up to 66 % of the water entering the collecting duct

–Delivery of fluid to the collecting duct is low (~ 8 L/day)

–Urine volume can be reduced to 300 mL/day

Question 76

What is the effect of no circulating ADH?

Answer 76

• Reabsorption of water occurs at various sites in the nephron as described previously
• However, the collecting duct wall becomes impermeable to water due to no AQP2 so a large volume of water is excreted (up to 30 L/day !!!)

Question 77

What is diabetes insipidus?

Answer 77

•Lack of ADH: Diabetes insipidus – treated using synthetic ADH

Question 78

What are the 2 major types of diabetes insipidus and how are they treated?

Answer 78

Question 79

What are the other types of diabetes insipidus?

Answer 79

Other types: Dipsogenic, Gestational

Question 80

What is SIADH and how is it treated?

Answer 80

Syndrome of Inappropriate ADH

Excessive release of ADH, e.g. due to head injury, unwanted effects of drugs, (e.g. ecstasy)

SIADH can cause hyponatraemia and possibly fluid overload

Treatment: V2 receptor blockers (ADH inhibitors), e.g. demeclocycline, Tolvaptan

Question 81

Where does ADH come from?

Answer 81

•ADH synthesised in hypothalamus, then stored and released from posterior pituitary

Question 82

Name agents which increase ADH release?

Answer 82

–Nicotine

–Ether

–Morphine

–Barbiturates

Question 83

Name an agent which inhibits ADH release?

Answer 83

–Alcohol

Question 84

Complete the percentages

Answer 84

Question 85

Q: What happens to all that water and solutes reabsorbed from the tubule?

Answer 85

It is all taken back into the peritubular vessels and vasa recta surrounding the tubule