Vitamins

Question 1

Hypervitaminosis A

Answer 1

• acute toxicity raised ICP
• Sx: headache, nausea, projectile vomiting
• Dry & pruritic skin (itchy skin)
• enlarged liver
• pregnancy: spontaneous abortions & congenital malformations in fetus

Question 2

Deficiency of Vit. A

Answer 2

Causes:

• fat free diets (fad diets)
• malabsorption of fats can also lead to deficiency Sx:
• night blindness
• Xerophthalmia:
• dryness of conjunctive & cornea
• Bitot’s spots
• Keratomalacia: corneal erosion
• increased risk of pulm infections: loss of muco-ciliary epithelium
• immune deficiency
• skin metaplasia with hyperkeratinisation
• increased predisposition to formation of renal & urinary stones

Question 3

Clinical uses of Vit. A

Answer 3

• Routine injection of Vit. A given with measles vaccine and also in clinical cases of measles as it helps to reduce the severeity of the disease
• Role on leukemia rx: trans form given along with chemotherapy in Acute Promyelocytic Leukemia
• Rx of acne & psoriasis: topical application

Question 4

Sources & Fx of Vit. A

Answer 4

Sources

• animal derived: liver, kidney, egg yolks, fish, milk, butter
• plant derived: yellow vegetables (carrots, squash) & green leafy veg.
• Kerotene: Pro-vit Fx Vision: component of rhodopsin (visual pigment). Visual cycle requires isomerization b/w cis & trans retinal
• Retinol: transport & storage form
• Retinal: component of visual pigment
• Retinoic Acid: active in epithelial differentiation & growth
• Maintenance of specialized epithelia, especially mucous secreting cells
• Growth
• Repro
• Immunity: stimulation of immune system to generate immunity against infection

Question 5

Absorption & Transport of Vit. A

Answer 5

• Diet contains retinol esters
• Hydrolysis by intestinal mucosa releasing retinol & free fatty acids
• Re-esterification & secretion in chylomicrons which are taken up by the liver where it is stored
• Plasma retinol binding protein in the liver transports to extra hepatic tissues
• Tissues contain cell retinol binding protein that carries retinoic acid to the nucleus

Question 6

Retinoids MOA

Answer 6

• retinol enters the target cell & is oxidised to retinoic acid in the cytosol
• from the cytosol, the retinoic acid moves into the nucleus with the help of cell retinoid binding proteins
• retinoic acid binds to intranuclear receptor forming an activated receptor complex
• retinoic acid-receptor complex binds to chromatin activating gene transcription

Question 7

Biochemical Events in vision

Answer 7

• retinol transported to the retina & enters the retinal pigment cells
• esterified to form a retinyl ester - storage form
• ester can be hydrolysed to form 11-cis retinol - oxidised to 11-cis retinal
• 11-cis retinal enters the rod cell where it combines with opsin to form rhodopsin (visual pigment)
• absorption of a photon of light catalyses the isomerization of 11-cis-retinal to all-trans-retinal triggering a cascade of events, leading to the generation of an electrical signal to the optic nerve which is interpreed as vision

Question 8

Metabolism of Vit. D

Answer 8

• Ergocalciferol (D2): found in plants
• Cholecalciferol (D3): found in animal tissues
• precursor of cholecalciferol synthesis in skin is 7-dehydrocholesterol (intermediate in cholesterol synthesis) in presence of sunlight.
• 1,25 Dihydroxycholecalciferol (calcitriol) is most active form:
• 25-hydroxycholecalciferol 1-hydroxylase aka alpha1-hydroxylase: converts 25-hydroxycholecalciferol -> 1, 25 dihydroxycholecalciferol
• Low plasma Ca2+ & PTH stimulate 25-hydroxycholecalciferol 1-hydroxylase

Question 9

Vit. D. Fx

Answer 9

Actions

• essential fx of Vit. D is maintenance of normal plasma Ca2+ & phosphorous levels. on the intestine: stimulates intestinal absorption of Ca2+ & PO43- by increased synthesis of specific Ca2+ binding proteins. PO4+ absorption is increased through the action of PTH Bone: stimulates the mobilisation of Ca2+ on PO43-from bone in presence of PTH
• Kidneys: Vit. D stimulates parathyroid dependent reabsorption of Ca2+ from the distal renal tubules &inhibits Ca2+ excretion by stimulating parathyroid dependent Ca2+ reabsorption.

Question 10

Vit. D sources & deficiency

Answer 10

Sources endogenous production in presence of UV radiation in sunlight - decreased by melanin and high solar protection factor sunblocks fortified cereals & dairy products fish oil egg yolks Causes

• nutritional deficiency: decreased intake/fat malabsorption
• inadequate exposure to sunlight
• Rickets
• Osteomalacia

Question 11

Vit. E structure & Fx

Answer 11

Sructure

• 8 naturally occuring tocopherols
• alpha-tocopherol is most active Fx
• most important role is anti-oxidant
• prevents peroxidation of lipids in conjuction with Selenium
• scavenges free radical generated

Question 12

Vit. E deficiency

Answer 12

Dietary deficiency of Vit. E is very rare since it’s abundant in foods. Occurs in association with:

• malabsorption of fat: cholestasis, pancreatic enzyme deficiency, CF
• relatively more common in premature infants with an immature GI tract
• Abetalipoproteinemia
• rare autosomal recessive syndrome of impaired Vit. E metabolism Sx:
• Hemolytic anemia: oxidative injury by superoxide radicals generated during oxygenation of Hb
• reduced DTR (Areflexia) & gait problems due to axonal degeneration

Question 13

Vit. K metabolism & Fx

Answer 13

• in humans, it is synthesized by the intestinal bacterial flora exists in 2 naturally occuring forms
• Phylloquinone (plants): dietary source
• Menaquinone (bacteria): intestine Vit. K is active in its Reduced form
• Epoxide Reductase (liver): converts inactive Vit. K -> Active epoxide Fx principal role of Vit. K is inpost-translation mod by various clotting factors including:
• Prothrombin
• VII
• IX
• X
• Protein C & S
• Vit. K serves as cofactor for liver microsomal gamma carboxylase
• Vit. K dependent carboxylation of glutamate residues leads of formation of mature clotthing factors (gamma-carboxy-glutamyl (Gla) residues & is capable of subsequent activation
• gamma-carboxylation allows Ca2+ binding b/c of 2 adjacent -ve charged carboxylate groups
• clotting factor Ca2+ complex can then bind to phospholipids on the platelet membrane

Question 14

Vit. K sources & Fx

Answer 14

Sources

• most Vit. K recycled by liver which converts the oxidised form to the reduced form
• endogenous intestinal bacterial flora readily synthesise the vit and so the daily dietary requirement is low
• foods rich in Vit. K include cabbage, cauliflower, spinach, egg yolk & liver Deficiency Neonates:
• newborns have sterile intestines as bacterial flora have not developed & therefore cannot synthesise Vit. K Hemorrhagic disease of the newborn
• bleeding at various sites in the body including skin, umbilicus & viscera
• Intracranial bleeding: most serious complication
• do not confuse w/ Rh incompatibility
• Rx: im injection of Vit. K for all newborns Adults Vit. K deficiency seen in cases of:
• fat malabsorption
• prolonged use of broad spectrum antibiotics
• diffuse liver disease which interferes with storage of Vit. K Vit. K toxicity manifests as:
• hemolytic anemia & jaundice
• hematuria
• melena (blood in stools)
• ecchymoses (brusiing)
• bleeding from gums Warfarin:
• Vit. K receptor antagonist
• MOA: blocks the activity of liver epoxide reductase & prevent regeneration of reduced Vit. K
• Rx for Pt with thrombo-embolic disease.

Question 15

Vit. C fx

Answer 15

• required for Iron absorption; reduces Iron to the ferrous state in stomach
• very important anti-oxidant; direct scavenger of free radicals; regenerates anti-oxidant form of Vit. E

Question 16

Scurvy (Vit. C def)

Answer 16

• Fragile blood vessels - perifollicular hemorrhages (base of hair follicles)
• sore, spongy, bleeding gums
• loose teeth
• bleeding into joints
• frequent bruising
• impaired wound healing

Question 17

Vit. B1 (Thiamine) Fx

Answer 17

• active form: TPP (Thiamine pyrophosphate) Fx:
• oxidative decarboxylation of alpha keto acids; helps to maintain neural membranes & nl nerve conduction
• acts as a cofactor for transketolase in HMS

Question 18

Vit. B1 sources & deficiency

Answer 18

Sources

• widely available in diet
• thiamine deficient foods are polished rice, white flour & white sugar Thiamine deficiency Beri-beri:
• polished rice is the major diet component
• Dry: polyneuropathy: disruption of motor, sensory and reflex arcs; could progress to paralysis
• Wet: cardiovascular sx & peripheral neuropathy Wernicke-Korsakoff syndrome:
• associated with chronic alcoholism = poor diet
• ophthalmoplegia & nystagmus; paralysis of extra-ocular muscles
• ataxia
• confusion, disorientation
• memory loss and confabulation
• Dx: increase in erythrocyte Transketolase activity on addiction of TPP

Question 19

Vit. B2 (Riboflavin) Fx

Answer 19

Active forms

• Flavin mononucleotide (FMN)
• Flavin Dinucleotide (FAD)
• participate in oxidation - reduction rxn

Question 20

Vit. B2 sources & deficiency

Answer 20

Sources

• widely distributed in meat, dairy products & veg Riboflavin Deficiency
• primary deficiency still occurs in developing countries
• lack of green veg.
• frequently accompanies other vit deficiencies Sx
• Cheilosis: areas of pallor, cracks & fissures at the angles of the mouth
• Pt describes “eating something salty & corners of mouth burn”
• Glossitis: inflammation & atrophy of the tongue
• facial dermatitis

Question 21

Vit. B3 (niacin)

Answer 21

Active forms:

• NAD+
• NADP+ Fx
• act as co-enzymes in oxidation reduction rxn
• NAD: dehydrogenases
• NADP: dehydrogenation rxn especially in the HMS cycle Uses
• niacin inhibits lipolysis in the adipose tissue & greatly reduces production of free fatty acids; Rx of Type IIb hyperlipoproteinemia

Question 22

Vit. B3 defiency

Answer 22

Pellagra

• seen in alcoholics
• deits rich in maize/corn
• can result from both Niacin or Trp deficiency
• Dermatitis
• Diarrhea
• Dementia

Question 23

Biotin fx & deficiency

Answer 23

• prosthetic group for most carboxylation rxn
• inherited deficiency of incorporation of biotin in these enzymes results in manifestations of biotin deficiency (multiple carboxylase deficiency)
• Biotin supplementation improves sx in many children with multiple carboxylase deficiency enzymes requiring biotin are:
• Pyruvate carboxylase
• Acetyl-CoA carboxylase
• Propionyl-CoA carboxylase
• Avidin inhibits biotin absorption

Question 24

Vit. B6 (pyridoxine)

Answer 24

• collective term for: pyridoxine, pyridoxal, pyridoxamine serve as precursors for PLP which act as co-enzyme for:
• Transamination: aa metabolism
• Decarboxylation: synthesis of NT
• Condensation: heme synthesis, i.e. ALA Synthase
• Conversion of homocysteine to cysteine

Question 25

Vit. B6 (pyridoxine) deficiency

Answer 25

• not very common Isoniazid (anti-TB drug) inactivates pyridoxine
• pyridoxine supplements are given as a part of anti-TB regimes Sx
• microcytic anemia (ALA synthase)
• peripheral neuropathy
• increased risk of cardiovascular disease (high levels of plasma homocysteine)
• seizures may occur

Question 26

Trace elements & enzymes

Answer 26

• Manganese: pyruvate carboxylase, mitochondrial SOD
• Molybdenum: xanthine oxidase
• Selenium: glutathione peroxidase
• Zinc: more than 100 enzymes

Question 27

Copper Fx & metabolism

Answer 27

important co-factor in redox rxn Cytochrome C

• part of complex IV
• inhibited by CN
• SOD Lysyl oxidase
• synthesis of collagen Tyrosinase
• melanin synthesis Dopamine beta-hydroxylase
• NT synthesis
• Copper forms ceruloplasmin aka Ferroxidase in the liver, which apart from being a copper transport protein, helps in Iron metabolism Metabolism
• 50% of ingested copper is absorbed in stomach & upper small intestine and the rest is excreted in feces
• ingested copper is absorbed in the stomach & instestine; transported to the liver bound to albumin
• in hepatocytes, it is used to form Ceruloplasmin which is secreted into plasma
• aged Ceruloplasmin is taken up by the liver from the plasma, endocytosed & degraded and copper is secreted into bile

Question 28

Copper deficiency

Answer 28

Sx:

• microcytic anemia (smaller RBC)
• degradation of vascular tissue
• defects in hair
• includes Menke’s syndrome & Wilson’s disease

Question 29

Menke’s syndrome

Answer 29

• X-linked disease (only boys) resulting in a defect in copper mobilisation from intestine causing copper deficiency
• kinky hair syndrome
• mental retardation
• fatal in infancy

Question 30

Wilson’s disease

Answer 30

• AR disorder of copper metabolism
• defect in copper transporting ATPase which is needed to attach copper to Ceruloplasmin & help in its biliary excretion -> accumulates in liver, brain, & eye
• gene for Wilson disease located on chromosome 13; over 30 mutations have been id Sx:
• commonest presentation is acute or chronic liver disease
• presents around >6 y
• neuropsych manifestations & frank psychosis Dx:
• decreased serum Ceruloplasmin
• increased Urinary excretion of copper; specific for Wilson’s disease
• increased hepatic copper content; also seen in Menke’s Rx:
• chelation
• Zn blocks uptake of copper from intestine and is used in conjunction with chelators
• ammonium tetrahiomolybdate: investigation drug which acts both as chelating agen and to block absorption of copper from gut
• avoidance of food with high copper contents link chocolate, nuts, liver

Question 31

Iron Fx & metabolism

Answer 31

Fx

• required for redox rxn & heme synthesis Metabolism
• absorption from diet; regulated by body iron stores & sensed by HFE
• iron can be absorbed only in the ferrous form
• any iron in the ferric form is changed to ferrous form by action of pH and Vit C in stomach -> no milk before iron tablets because it neutralizes some the stomach acid
• Ceruloplasmin (ferroxidase) participates in the release of ferrous iron from the intestinal cells and helps to convert it to ferric iron
• transferrin is the transport protein for iron
• ferritin & hemosiderin are the storage forms of iron in the liver

Question 32

Iron deficiencies

Answer 32

Causes

• dietary lack
• impaired absorption: tannates decrease absorption.
• increased requirement: pregnancy
• chronic blood loss Iron deficiency anemia: induces a hypochromic microcytic anemia. Sx include
• brittle nails
• alopecia
• pica: appetite for soil
• weakness & pallor
• fatigue

Question 33

Heriditary Hemochromatosis & Iron toxicitiy

Answer 33

• AR disorder causing excessive absorption of Iron
• defect in HFE gene leading loss of sensing mechanisms on basolateral surface of intestinal crypot cell iron sensor
• excessive accumulation of iron in the parenchymal organs, most importantly liver & pancreas excessive iron appears to be directly toxic to tissues by:
• lipid peroxidation via iron catalyzed free radical rxn
• DNA damage Clinical Sx
• cirrhosis
• diabetes
• cardiac dysfunction
• acute synovitis (inflammation of joint synovial linings)
• brownish skin pigmentation
• very high levels of serum iron & ferritin
• iron content of unfixed liver tissue dramatically increased
• Pt treated by regular phlebotomy have a nl life expectancy

Question 34

Nutritional anemias

Answer 34

Microcytic (

• Iron, copper or pyridoxine deficiency Normocytic (MCV 80-100)
• protein-calorie malnutrition Macrocytic (MCV>100)
• aka megaloblastic
• Vit. B12 or Folate deficiency