Lecture 14 - micronutrients part 1

Question 1

What is group I?

Answer 1

micronutrients that control type II steroid hormone receptors and have major global health implications
iodine, Vit A, Vit D, calcium, Vit K, phosphorus and fluoride

Question 2

What is Group II?

Answer 2

micronutrients that have a role in oxidant defense
Vit E, Selenium, Vit C, Niacin, Riboflavin, Copper, Zinc, manganese

Question 3

What is Group III?

Answer 3

Micronutrients that act as enzyme cofactors
thiamin, niacin, riboflavin, Vit B6, folate, Vit B12, Biotin, Pantothenic acid

Question 4

What is Group IV?

Answer 4

Iron, Copper, and zinc-related divalent cations

Question 5

What does bioactive mean?

Answer 5

they can interact with eachother and cause an output, a functional form

Question 6

Do all of the group I micronutrients act directly on steroid hormone receptors?

Answer 6

No, only the bioactive forms of vit a, it d and iodine

Question 7

What is iodine used to make?

Answer 7

T3 hormone, which regulates synthesis of proteins that control a persons basal metabolic rate

Question 8

What is Vit A used to make?

Answer 8

Vit A precursors are converted to retinoids, which regulate night vision, epithelial differentiation and gene expression

Question 9

What is Vit D used to make?

Answer 9

Vit D precursors are converted to calcitriol, which regulates calcium levels in the body

Question 10

What is a steroid hormone receptor?

Answer 10

intracellular protein receptors that need to bind a ligand to become a functional (active) transcription factor

Question 11

What are the two types of steroid hormone receptors?

Answer 11

Type 1 and Type 2

Question 12

What is a Type 1 steroid hormone receptor?

Answer 12

• cytosolic
• respond to steroid hormones like estrogen, testosterone, progesterone, glucocorticoids, and mineralcorticoids

Question 13

What is a type 2 steroid hormone receptor?

Answer 13

• nuclear
• respond to steroid and non-steroid ligands, like thyroid hormone, retinoic acid and calcitriol

Question 14

Is iodine high in most foods?

Answer 14

No, iodine content of most foods is low

Question 15

Is iodine organic or inorganic

Answer 15

inorganic

Question 16

Is iodine water soluble?

Answer 16

iodine is highly water soluble

Question 17

Where is iodine found in higher concentrations?

Answer 17

in coastal populations compared to mountainous regions, seafood has high concentrations, especially sea greens

Question 18

What is fortification?

Answer 18

to increase the nutritional value of food by adding vitamins or minerals

Question 19

How is iodine consumed in north america?

Answer 19

through salt fortified with potassium iodine

Question 20

How can iodine be found in the body?

Answer 20

dietary iodine can be bound to AA or found free

Question 21

What is iodine converted to?

Answer 21

in GI tract, iodine (I) is rapidly converted to iodine (I-) and absorbed

Question 22

Where is iodine absorbed?

Answer 22

in the stomach, a bit in the small intestine

Question 23

What does iodide do once it is absorbed in the stomach?

Answer 23

in the blood, free I- circulations and can enter all tissues (most accumulates in the thyroid gland)

Question 24

How much of our bodies iodine is found in the thyroid gland?

Answer 24

70-80%

Question 25

What is uptake of I- in the thyroid gland mediated by?

Answer 25

active transport system known as the Na+/I- symporter

Question 26

NIS

Answer 26

Na+/I- symporter

Question 27

Do tissues rely on iodine itself?

Answer 27

no, tissues actually rely on the thyroid hormones made by iodine, T3 and T4

Question 28

What is the process of making T3 and T4 from iodide?

Answer 28

1. dietary iodide is absorbed from GIT into the blood and is taken to the thyroid
2. iodide enters the thyroid through NIS (active transporter)
3. iodide enters the colloid of a thyroid cell and it is quickly oxidized to form a free radical I’
4. iodide radical attacks the Tyr residues in THG un the colloid, which causes a cross-linking between tyrosine residues
5. thyroid cells proteases hydrolyze THG, releasing fragments that correspond to T3 and T4 hormones
   - note: there is less T3 produced, and more T4 produced
6. The T4 produced travels (in blood through carrier proteins) to the liver for storage, where it can be converted to T3 through 5’ deiodinase (selenoprotein), the T3 made there is then used for function in the body
7. The T3 made in the thyroid is directly used for function in the body
8. the hypothalamus sense low T3 and sends neural signals to the pituitary to cause the release of TSH
9. TSH travels to the thyroid to stimulate the production of more T3

Question 29

What is the function of the T3 hormone?

Answer 29

regulates metabolic rate and growth in many tissues through interaction with the thyroid hormone receptor

Question 30

Is T3’s half-life longer than T4?

Answer 30

T3 half-life <T4

Question 31

What does T3 interact with?

Answer 31

Thyroid hormone receptor (THR)

Question 32

THR

Answer 32

thyroid hormone receptor

Question 33

What hormone regulates T3 and T4 production?

Answer 33

TSH

Question 34

How much T3 vs T4 is there in the blood?

Answer 34

50 x more T4 in the blood than T3, but T3 is 100 x more potent

Question 35

THG?

Answer 35

thyroglobulin protein

Question 36

Where is THG produced?

Answer 36

in the thyroid cell (nucleus) and then released in the colloid (lumen), THG is a tyrosine rich protein, it is exocytosed into the colloid

Question 37

What does T4 and T3 stand for?

Answer 37

T4 - thyroxine
T3 - Triiodithyronine

Question 38

What is the function of thyroid hormones?

Answer 38

influence how your body stores and uses energy (effects metabolism)

Question 39

What are the 9 things thyroid hormones control?

Answer 39

1. breathing
2. heart function
3. nervous system function
4. body temp
5. cholesterol level
6. energy balance
7. brain development
8. moisture in the skin
9. menstruation

Question 40

What are some characteristics of the T3 and T4 hormones?

Answer 40

• T3 and T4 are lipophilic (can easily cross plasma membranes)
• T4 is converted into T3 in various tissues (primarily in the liver)

Question 41

What does T3 bind to?

Answer 41

in tissues, T3 binds to THR, which then binds to response elements in the promoter regions of DNA to activates gene expression (mRNA)

Question 42

When T3 indirectly activates gene expression, what do the induced genes effect?

Answer 42

• ATPases (pump Na+ and Ca2+ out of cells) which increases metabolic rate
  (Na+ muscle contraction, neuron firing) (Ca2+ signalling events)
• growth hormone (anabolic effects)

Question 43

What happens when there is an iodine deficiency?

Answer 43

• when T3 levels are low, the pituitary gland releases TSH to turn iodide into T3
• when iodine is deficient, the thyroid is still being stimulated by TSH to make hormones, but it can’t, this causes hyperplasia (increase in cell number), and hypertrophy (increase in cell size)

Question 44

What are the health effects of iodine deficiency?

Answer 44

goitre (in adults) -> thyroid enlargement
- mild goitres can be treated with iodine supplements
- if left untreated, they become thyroid cancer
cretinism -> When iodine levels are low in the mother, the fetus doesn’t develop properly
- growth and development abnormalities
- irreversible

Question 45

What is vitamin A referring to?

Answer 45

a group of compounds known as retinoids

Question 46

What are major forms of vitamin A in the body?

Answer 46

retinol, retinal, retinoic acid and retinyl ester

Question 47

What are carotenes?

Answer 47

precursors for vitamin A, they are a type of carotenoid, which are pigments produced in plants

Question 48

What are animal livers rich in?

Answer 48

retinol and retinyl ester

Question 49

What are orange and dark green vegetables rich in?

Answer 49

beta-carotene

Question 50

What is a retinyl ester composed of?

Answer 50

retinol and FA

Question 51

What do retinyl esterases do?

Answer 51

cleave the FA from the retinol

Question 52

How is vitamin A digested and absorbed steps?

Answer 52

1. a fat droplet from the stomach containing retinyl esters and beta carotene are acted on by pancreatic retinyl esterase and retinol and beta carotene are absorbed as a micelle through passive diffusion into an intestinal mucosal cell
2. beta carotene can either go straight to the chylomicron or can form retinal through 15,15’ DO which then forms retinol
3. this retinol becomes retinyl palmitate through the palmityl CoA enzyme
4. the retinyl palmitate is then packaged in a chylomicron and goes into the lymphatic circulation
5. the chylomicron then gets rid of TAGs to become a chylomicron remnant and the contents of it are absorbed in the liver
6. in the liver, beta carotene can be stored there or can be packaged into a VLDL and sent out into circulation to go to adipose tissue (hypercarotenosis)
7. in the liver, retinyl palmitate can be stored or can become retinol through retinyl esterase when it is needed for vitamin A
8. once it becomes retinol, it combines with RBP to form retinol-RBP and travels through the blood to be recognized by a receptor on the target tissue

Question 53

RBP

Answer 53

retinol binding protein

Question 54

What is taken into circulation when vit A is low?

Answer 54

retinol-RBP

Question 55

What is used to check if there is a vitamin A deficiency?

Answer 55

retinol-RBP

Question 56

What do low levels of retinol-RBP stimulate?

Answer 56

hepatic retinyl esterase

Question 57

What is the ability of vitamin A and beta carotene to pass through membranes?

Answer 57

vitamin A and beta carotene are lipophillic, therefore they are handled like other lipids

Question 58

What are the two fates of beta carotene in the liver?

Answer 58

depending on the vit a status of a person, beta carotene will be either
1. incorporated into chylomicrons “as is”
2. or converted into retinyl ester in the intestinal cells and then incorporated into chylomicrons

Question 59

Where are retinyl esters stored?

Answer 59

in hepatic stellate cells until needed

Question 60

What happens when retinyl esters are needed?

Answer 60

liver retinyl esterase removes the FA releasing retinol which binds to retinol-binding protein (RBP) and secreted into blood, liver RBP synthesis depends on persons vit a status

Question 61

RA

Answer 61

retinoic acid

Question 62

What does retinol-RBP do?

Answer 62

brings retinol to cells, and can then be converted into RA

Question 63

What is the function of RA?

Answer 63

goes to nucleus and binds and activates both the RAR and the RXR TF’s
these complexes homo and hetero dimerize with other nuclear hormone receptors (NHR) creating a huge number of possible combination of TF’s which allows the regulation of gene expression

Question 64

RAR

Answer 64

retinoic acid receptor

Question 65

RXR

Answer 65

retinoid X receptor

Question 66

NHR

Answer 66

nuclear hormone receptor

Question 67

Where are stem cells located?

Answer 67

rapidly dividing stem cells are in all epithelial tissues

Question 68

What happens when there is a vitamin A deficiency in epithelial differentiation steps?

Answer 68

When vitamin A is present:
stem cells have normal cell differentiation then columnar epithelium secretes mucus and keratinization, some cells are sloughed off which results in cell death

When vitamin A is deficient:
stem cells continue to rapidly divide and cause poor differentiated function, in the epithelial cells, there is keratinization, but little mucus secretion, there is not enough mucus to form a good protective layer, so viruses and bacteria can penetrate

Question 69

What is an issue with stem cells and vitamin a deficiency?

Answer 69

keratin is a major problem in all epithelial cells whose expression is regulated by retinoic acid

Question 70

What does vit A deficiency in stem cells cause in various parts of the body?

Answer 70

cornea: xeropthalmia
lungs: respiratory infections
GI tract: diarrhea
skin: folliculosis

Question 71

What are the 5 consequences of vitamin A deficiency?

Answer 71

1. night blindness: reversible, one of the first signs of vit a deficiency, associated with bitot spots, a buildup of keratin debris in the conjunctiva of the eye
2. impaired epithelial cell differentiation: can cause permanent blindness and life-threatening infections
3. impaired growth (growth hormone not produced): impacts bone development, tooth decay etc.
4. impaired fertility: decreased sperm formation, fetal resorption (early death of the embryo)
5. fetal development defects: birth defects due to loss of control of differentiation, can occur with too little or too much vit a

Question 72

RAE

Answer 72

retinol activity equivalents

Question 73

What is RAE?

Answer 73

RAE accounts for differences in the biological activity of various carotenoids

Question 74

Why is there no UL for beta carotene?

Answer 74

carotenoids prevent deficiency but don’t cause toxicity, will just be stored if there are enough

Question 75

What occurs during vitamin A dietary toxicity?

Answer 75

most severe consequence is liver cell death
- retinyl ester are stored in the stellate cells of the liver and with excess vit a intake, the cells reach capacity, raw vit a spills out and the local hepatocytes become damaged and die

Question 76

What can excessive intake of beta carotene cause?

Answer 76

hypercarotenosis (skin turns yellow-orange)

Question 77

What does the bioactive form of vit D act as?

Answer 77

a hormone, works with other hormones such as parathyroid and calcitonin

Question 78

Where is the bioactive form of vit D made?

Answer 78

liver only

Question 79

What are the five forms of vitamin D sources

Answer 79

1. natural plant sources (provitamin D2)
2. natural animal sources (provitamin D3)
3. sunlight
4. supplementation
5. fortification

Question 80

What is an example of a natural plant source that provides vitamin D

Answer 80

shitake mushrooms

Question 81

What is an example of a natural animal source that provides vitamin D

Answer 81

fish, fish liver oils

Question 82

Is vitamin D very active in plants?

Answer 82

no, so plant sources are not a very good source of vitamin D

Question 83

Which provitamin D2 is more bioactive?

Answer 83

(D3) cholecalciferol is more bioactive than (D2) ergocalciferol

Question 84

How is vitamin D made in the skin?

Answer 84

vit D3 is made in the skin from 7-D
7-dehydrocholesterol (7-D) is converted to (D3) cholecalciferol by sunlight (UVB and infrared), this occurs in the sebaceous glands of the skin

Question 85

How does vitamin D3 circulate around the body?

Answer 85

D3 binds to the vit D binding protein (DBP) and circulates throughout the body

Question 86

How does melanin slow down vit D3 production?

Answer 86

melanin in the epidermis absorbs UV rays, which slows down vit D3 production, part of the problem for Vit D deficiencies over time (migrating populations)

Question 87

What bioactive form of vitamin D is used in supplements?

Answer 87

Vit D3

Question 88

Where is fortification of vitamin d found?

Answer 88

milk and margarine, insufficient for health if this is a persons only source of vit D3

Question 89

Is there a risk of vitamin D toxicity from the sun?

Answer 89

no

Question 90

What are the steps to vitamin D3 production in the skin?

Answer 90

1. UV rays hit the skin and convert 7-D to vit D3
2. vit D3 has two fates
   - bind to DBP and go into the adipose tissue for storage, eventually goes to liver
   - bind to DBP and go directly into the liver for conversion

Question 91

What are the steps to vitamin D3 production in the diet?

Answer 91

1. vit D3 is absorbed passively in the ileum (not very efficient)
2. vit D3 is incorporated into chylomicrons and eventually ends up in the liver for conversion

Question 92

Is there a difference between sun derived vitamin D3 and diet-derived vitamin D3?

Answer 92

no

Question 93

What is vitamin D3 converted to in the liver?

Answer 93

Vit D3 ->(25-hydroxylase) 25-OH

Question 94

What are the steps to vitamin D3 conversion in the liver?

Answer 94

1. in the liver, the 25th carbon on vitamin D3 is hydroxylated to form 25-OH D3 (inactive molecule) by the25-hydroxylase enzyme
2. once produced, 25-OH D3 is secreted into blood bound to DBP (this corresponds to the largest pool of 25-OH D3 in the body

Question 95

what type of enzyme is 25-hydroxylase?

Answer 95

a cytochrome p450 enzyme

Question 96

What is a sign of vitamin D3 deficiency?

Answer 96

if 25-OH D3 levels in the blood are low

Question 97

What happens with regards to vitamin D when calcium levels are low in the body?

Answer 97

25-OH D3 will be converted to an active molecule

Question 98

Does vitamin D regulate calcium homeostasis?

Answer 98

yes

Question 99

What are the steps to forming the active form of vitamin D3 after D3 is converted to 25-Oh D3 in the liver?

Answer 99

1. 25-OH D3 binds to DBP and circulates around the blood
2. it eventually enters the kidney where 25-OH D3 enters
3. low Ca2+ levels in blood plasma activate the parathyroid to release PTH (parathyroid hormone) promotes uptake of 25-OH D3/DBP complex into the kidney which enters the kidney and turns 25-OH D3 into 1,25-OH2 vit D3 (calcitriol) by the enzyme 1-hydroxylase
4. 1,25-OH2 vit D3 can bind to DBP and go into the bone, to increase breakdown, the gut, to increase calcium absorption, or stay in the kidney to increase calcium resorption

Question 100

What is the active form of vit D?

Answer 100

1,25-OH2 D3 also known as calcitriol

Question 101

How does calcium play a role in the production of calcitriol?

Answer 101

high gradient of blood to intracellular Ca2+ is essential, low blood Ca2+ is sensed by parathyroid gland which releases PTH

Question 102

What does calcitriol activate?

Answer 102

calcitriol is sent out into the body to activate intracellular signalling pathways

Question 103

How does calcitriol activate genomically (steps)?

Answer 103

1. calcitriol enters the nucleus and binds to VDR
2. C+VDR binds to the promoter region of mRNA and synthesizes proteins which are pre-calcium binding proteins
3. the pre-calcium binding proteins undergo post translational modification and are activated by vitK dependent PTM (gamma carboxylation) to turn them into calcium binding proteins

Question 104

VDR

Answer 104

vitD receptor

Question 105

What is VDR

Answer 105

type II steroid hormone receptor, it is a TF that promotes calcium-binding protein synthesis

Question 106

How does calcitriol activate non-genomically steps?

Answer 106

1. calcitriol enters the cell via a cell-surface receptor (MARRS) and undergoes protein phosphorylation once inside the cytosol
2. this causes numerous signally events for example the activation of Ca transporters (Ca2+ can enter the cell)

Question 107

MARRS

Answer 107

membrane associated rapid response steroid binding protein
- cell surface receptor

Question 108

What are the three organs relevant for VitD/Ca2+?

Answer 108

small intestine
kidney
bone

Question 109

What is the small intestines role in vitD/Ca2+ story?

Answer 109

Absorption
- minerals need transporters for absorption by intestinal cells and entry into portal circulation
- proper absorption of Ca2+ depends on the expression of Ca2+ binding proteins in enterocytes

Question 110

What is the kidneys role in vitD/Ca2+ story?

Answer 110

Reabsorption
- small molecules like Ca2+ circulate in blood and eventually reach kidney
- pass through filter and can end up in urine unless they are reabsorbed
- reabsorption removes the molecules from the filtrate and gets them back into blood

Question 111

What is bones role in VitD/Ca2+ story?

Answer 111

Resorption
- dissolving bone structure to release Ca2+ into the blood
- balance between break down and synthesis allows for bone maintenance, remodeling and repair

Question 112

Difference between osteoclasts and osteoblasts?

Answer 112

osteoclasts resorb bone
osteoblasts build bone

Question 113

What is more important, maintaining blood Ca2+ or Ca2+ reserves?

Answer 113

maintaining blood Ca2+ is more important than maintaining Ca2+ reserves in bone

Question 114

What is PTH’s role in blood Ca?

Answer 114

serves to increase blood Ca
- promotes the production of calcitriol in kidney by activating 1-hydroxylase enzyme
- stimulates bone resorption by activating osteoclasts
- maximizes tubular reabsorption of calcium into the kidney

Question 115

What is vitamin D (calcitriol) role in blood Ca

Answer 115

serves to increase blood Ca
- stimulates Ca2+ resorption from bone
- helps to increase absorption of Ca2+ from intestine
- maximizes tubular reabsorption of Ca2+ in kidney

Question 116

What is calcitonin’s role in blood Ca?

Answer 116

serves to decrease blood Ca2+
- suppresses tubular reabsorption of Ca2+ in kidney
- inhibits bone resorption and facilitates remineralization

Question 117

Where is calcitonin secreted from?

Answer 117

secreted by parafollicular cells in the thyroid

Question 118

Does vitamin D deficiency vary across lifespan?

Answer 118

yes

Question 119

What is the composition of normal bone?

Answer 119

mixture of solid (outer) and spongy (inner) parts
solid part is 60% mineral (Ca2+ and P) and 40% organic (collagen)

Question 120

What happens with vitamin D deficiency in infants?

Answer 120

Rickets (poor mineralization)

Question 121

What is rickets?

Answer 121

bones don’t mineralize properly and can’t support the body’s weight when they start walking (permanent and reversible only with surgery)

Question 122

What happens with vit D deficiency in adolescents to adult?

Answer 122

osteomalacia

Question 123

What is osteomalacia?

Answer 123

bones become demineralized (can be reversed with supplementation), bone fractures can occur more easily, will get worse with time if not corrected

Question 124

What happens with vit D deficiency in middle-aged to eldery?

Answer 124

osteoporosis

Question 125

What is osteoporosis?

Answer 125

normal part of aging (loss of both mineral and organic parts of bone), diagnosed with bone density scans, difficult to reverse due to erosion of bone (holes in bone form), can take vit D supplements to manage

Question 126

What is osteoporosis worsened by?

Answer 126

chronic low Ca2+ vit D and or vit K intake

Question 127

What is the difference between men and women for osteoporosis?

Answer 127

men have higher peak bone mass between 20-30 years and lower bone loss

Question 128

What is a big change of the RDA’s of vit D?

Answer 128

in recent years, Health Canada tripled the RDA for Vit D

Question 129

How are there not toxicity concerns for vitamin D production from sun exposure?

Answer 129

production of Vit D3 is limited by finite amounts of 7-D present in the skin, also produces the inactive lumisterol and tachysterol metabolites with prolonged sun exposure, which have no bioactivity

Question 130

What happens with very high dietary intake of vit D causing high levels of circulating calcitriol?

Answer 130

hypercalcemia, leading to a possible calcification of soft tissues, and acute kidney injury

Question 131

Is vitD toxicity rare?

Answer 131

yes however it could happen if a person consumes lots of fortified foods, takes dietary supplements and spend lots of time in the sun

Question 132

What is vit K important for?

Answer 132

bone formation and blood coagulation

Question 133

How is vit K obtained?

Answer 133

through consumption of green leafy plants (as phylloquinone)
made by gut bacteria (as menaquinone)

Question 134

What is a special feature of phylloquinone?

Answer 134

sensitive to light and heat

Question 135

Why do infants have poor vit K status?

Answer 135

• little vit K in mothers milk and babies aren’t getting leafy plants yet
• babies also haven’t developed their colonic gut bacteria so no menaquinone
• babies given vit K heel prick at birth

Question 136

Is vit K deficiency rare in adults?

Answer 136

yes, due to bacterial production

Question 137

Does phylloquinone require digestion?

Answer 137

no

Question 138

How is phylloquinone absorbed?

Answer 138

incorporated into micelles and absorbed in the small intestine
absorbed via NPC1L1 transporter

Question 139

How are menaquinones absorbed?

Answer 139

passive absorption, don’t require a transporter, go into lymphatic system

Question 140

How do phylloquinone and menaquinone transported to various tissues across the body?

Answer 140

both are incorporated into chylomicrons

Question 141

Where can vit K be stored?

Answer 141

lungs, kidneys, adrenal glands, bone

Question 142

What is the difference between phylloquinone and menaquinone in structure?

Answer 142

phylloquinone has a long s.c. and menaquinone doesn’t

Question 143

What are the short forms for phylloquinone and menaquinone

Answer 143

phylloquinone - K1
menaquinone - K2

Question 144

What are the steps to the vitamin K cycle?

Answer 144

1. vit K (quinone) comes in from dietary intake or from bacteria
2. vit K (quinone) ——> vitamin K hydroquinone (active form)
   enzyme: quinone reductase
   NADPH -> NADP+
3. vitamin K hydroquinone (active) —> vitamin K epoxide (inactive)
   enzyme: gamma-glutamyl carboxylase
   glutamic acid in
   gamma carboxyglutamic acid out
   CO2 in
4. vitamin K epoxide (inactive) —> vitamin K quinone
   enzyme: epoxide reductase
   warfarin inhibits epoxide reductase

Question 145

What does warfarin do?

Answer 145

inhibits epoxide reductase
- rat poison
- anticoagulant

Question 146

What is the reduced form of vit K

Answer 146

vit K hydroquinone

Question 147

What is the oxidized form of vit K

Answer 147

vit K epoxide

Question 148

how do protein precursors become calcium-binding proteins through the help of vit K steps?

Answer 148

1. protein precursor with a glutamate s.c. becomes a posttranslationally modified protein with a gamma carboxyglutamate s.c. through the gamma-glutamyl carboxylase
2. posttranslationally modified protein becomes a calcium-binding protein
   - Gla residues on blood clotting proteins bind Ca2+

Question 149

What do Gla residues on blood clotting proteins do?

Answer 149

Bind Ca2+. Ca2+ allows gla containing proteins to bind to phospholipids on membrane of blood platelets and endothelial cells

Question 150

What are the susceptible populations for a vit K deficiency?

Answer 150

newborn infants
people who take antibiotics regularly
- antibiotics destroy the gut bacterial community
people with malabsorptive illnesses

Question 151

What are deficiency symptoms related to role in gamma-carboxylation in vit K deficiency?

Answer 151

impaired blood clotting: possible hemorrhagic syndrome (mostly seen in newborns)
impaired activation of calcium-binding proteins: accelerate development of osteoporosis (mostly seen in elderly adults)

Question 152

What part of the body has the most calcium?

Answer 152

bones and teeth

Question 153

Where is calcium primarily obtained?

Answer 153

dairy products, but also high in sardines, salmon and some green leafy vegetables, present in these foods as an insoluble salt, stomach acid creates soluble Ca2+

Question 154

Where is calcium absorbed?

Answer 154

small intestine, about 25-30% of dietary calcium is absorbed

Question 155

How is calcium absorbed?

Answer 155

• saturable, carrier-mediated, active transport
• absorption is regulated by calcitriol, most calcium is absorbed this way
• diffusion via paracellular route is a secondary pathway for Ca2+ uptake

Question 156

What are the ways calcium is transported across the body?

Answer 156

40% bound to albumin
10% found complexed with sulfate, phosphate etc.
50% found in free (ionized) form

Question 157

What is the function of calcium?

Answer 157

Bone: makes up hydroxyapatite which is what gives strength and rigidity to the bone
Intra- and extracellular calcium (ionized calcium):
- blood clotting (formation of gla residues on coagulation proteins)
- skeletal muscle contraction (release of calcium stores)
- nerve potential (acting through ion channels)
- intracellular signalling pathways

Question 158

What happens to calcium is intra- and extracellular levels drop?

Answer 158

bone will be sacrificed

Question 159

How is calcium absorbed from the small intestine to the blood steps?

Answer 159

1. free Ca2+ enters two ways
   - TRPV5/6 transporter (transcellular)
   - through space between cells (paracellular)
2. transcellular
   - high Ca2+ on lumen side and low Ca2+ on inside of cell
   - the transporter under the influence of proteins made by calcitriol brings Ca2+ into the cell
   - calbindin-D binds to Ca2+ and throws it into the blood through various Ca channels
   
   • one requires ATP, the other uses
     Na+ gradient
3. paracellular
   - minor route
   - just a leaking between cells

Question 160

apical vs basolateral

Answer 160

the apical surface of the cell faces towards the external environment whereas the basolateral surface sits adjacent to an internal-facing basement membrane.

Question 161

How has the UL of Ca2+ changed?

Answer 161

increased UL in children
decreased UL in adults
decreased UL in >70yrs to prevent kidney stones

Question 162

What are factors that affect calcium absorption?

Answer 162

• caffeine decreases absorption
• some fibres decrease absorption
• magnesium and zinc decrease absorption
• PTH (Vit D) increase absorption
• pregnancy and lactation increase absorption

Question 163

What does Ca2+ deficiency affect?

Answer 163

Bone:
- inadequate mineralization in bone
- rickets in children
- osteomalacia

Muscle:
- tetany: a condition characterized by involuntary muscle contractions

• evidence for association with hypertension
• evidence for association with colon cancer

Question 164

What happens when there is a Ca2+ toxicity?

Answer 164

• constipation, bloating and/or gas
• hypercalcemia (kidney stones)

Question 165

In which food is phosphorus found?

Answer 165

widely distributed in food
- found in animal products as phosphorus
- grains as phytic acid

Question 166

Is phosphorus deficiency and toxicity common?

Answer 166

widely distributed in food, so deficiency and toxicity are rare

Question 167

Where is phosphorus absorbed?

Answer 167

most is absorbed in the small intestine in its ionic form PO43-

Question 168

How is phosphorus absorbed?

Answer 168

through passive diffusion (primaru
saturable, carrier-mediated, active transport (NaPi cotransporter) - bind phosphate

Question 169

How is phosphorus transported to various tissue?

Answer 169

primarily transported in the blood as organic phosphate (incorporated into phospholipids)

Question 170

Where is phosphorus primarily found in the body?

Answer 170

bone but also in molecules key for metabolism (ATP, DNA, RNA, cAMP - through phosphorylation)

Question 171

What does phosphorus play a key role in?

Answer 171

phosphorylation

Question 172

Is fluoride found in abundance in the body?

Answer 172

no, it is found in trace amounts, not essential

Question 173

How is fluoride absorbed?

Answer 173

through passive diffusion (nearly 100% efficiency)

Question 174

How is fluoride transported through the body?

Answer 174

as ionic fluoride or bound to plasma proteins

Question 175

What is the major function of fluoride?

Answer 175

effects on mineralization of teeth and bones, increases resistance of enamel to acid demineralization by forming fluorapatite (protective layer)

Question 176

What happens during a fluoride deficiency?

Answer 176

increased incidence of tooth decay

Question 177

What happens during a fluoride toxicity?

Answer 177

• fluorosis (mottling of the teeth) - cosmetic