36 - Vitamin D3 Receptors

Question 1

Vitamin D3 (where is It produced and released?)

Answer 1

o Vitamin D3 (cholecalciferol) is produced in the skin by the action of ultraviolet light on 7-dehydrocholesterol
o It is released into the plasma and passes to the liver, where it is converted into 25-hydroxycholecalciferol
o This then passes to the proximal convoluted tubule in the kidney where a further hydroxyl group is added to produce 1,25-dihydroxycholecalciferol (1,25-(OH)2D3; also called calcitriol) by an enzyme found on the mitochondrial inner wall

Question 2

What is the regular cholesterol we get in our diet?

Answer 2

7-dehydrocholeserol is a regular cholesterol that can get in our diet
o UV light acts on this to make the pre-vitamin D3 in the skin
o This opens further to make vitamin D3

Question 3

Where is vitamin D3 converted?

Answer 3

o Vitamin D3 is converted in the liver to 25 hydroxy called calciferol which lasts quite a long time
o In the kidney this is switched on further by adding another hydroxyl to make 1, 25 hydroxyl

Question 4

Control of calcium and phosphate homeostasis

Answer 4

Overview of the hormonal control of calcium and phosphate homeostasis by parathyroid hormone (PTH) and 1,25-dihydroxyvitamin D (1,25-(OH)2D)

Question 5

What is broken down?

Answer 5

he bone material which is made of calcium phosphates broken down by osteoclast cells

Question 6

What does vitamin D potentiate?

Answer 6

Vitamin D potentiates the actions of parathyroid hormone

Question 7

What happens in the kidney?

Answer 7

In the kidney we get reabsorption of calcium and excretion of phosphate, regulated by parathyroid hormone
o This is also facilitated by vitamin D3
o Vitamin D3 causes absorption of calcium from the gut, so we have parathyroid hormone causing calcium absorption from the kidney and also causing absorption from the gut

Question 8

What is the key step for vitamin D3 regulated by?

Answer 8

They key activating step for vitamin D3 is regulated by parathyroid hormone, which regulates the activation of hydroxylase enzyme in the mitochondria of kidney cells
o This causes the switch of 25 hydroxy vitamin D3 to 1,25 dihydroxy vitamin D3 which can now act on the gut and on the bone to increase calcium levels

Question 9

Why do the actions of 1,25-(OH)2D3 occur?

Answer 9

The actions of 1,25-(OH)2D3 occur as a consequence of binding to DNA and increasing transcription of mRNAs

Question 10

Vitamin D3 has the following properties:

Answer 10

1. It is essential for bone development and also for demineralisation and release of Ca2+ and Po4(3-)
2. It stimulates renal tubular reabsorption; a specific 1,25-(OH)2D3 receptor has been identified in the kidney in the distal convoluted tubules of the nephrons
3. It causes reabsorption from the intestine and transports PO4(3-) across the gut epithelium as an active transport mechanism\
   
   • Transport within the intestinal epithelium is achieved by stimulating Ca2+ entry into the epithelial cells

Question 11

What do all transport mechanisms require?

Answer 11

All transport mechanisms require calcium-binding proteins (ca-BPs), the synthesis of which is increased by vitamin D

Question 12

What does the vitamin D3 receptor cause?

Answer 12

o Vitamin D3 receptor causes transcription of a gene coding for calcium binding protein or calcium Bps
o These are synthesised in the gut by vitamin D3 acting on this receptor

Question 13

Number of ways with which calcium can be brought up:

Answer 13

o Calcium can be absorbed in the gut and interact directly with calcium binding protein and then can be further absorbed into the body in exchange for sodium
o Calcium binding protein can allow calcium to be transported between epithelial cells into the body
- This is called transcellular transport
o Calcium binding protein cause vesicular storage of calcium
o Simple calcium channel which allows calcium uptake