Micronutrients (Vitamins & Minerals) PDF 2024

Summary

This document presents lecture notes on micronutrients, specifically vitamins and minerals. It provides an overview of the different types of vitamins and minerals, their roles, functions, and associated deficiencies. The information is intended for an undergraduate audience.

Full Transcript

Micronutrients (Vitamins & Minerals)

Asmare Amuamuta (Ph.D.)

Assoc. Professor of Biochemistry & Bioclinical
Sciences, CMHS

Bahir Dar University

E-mail: [email protected]

) NOV 2024

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 Vitamins
 Vitamins are organic (carbon) compounds
needed for normal function, growth and
maintenance.
 Vitamins act as coenzymes (they don’t do
anything by themselves).
 They are not a source of calories.

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The Nature of Vitamins
Effect of packaging on
 Nutritional Value lost by: nutrient loss in milk.
 Light
 Heat
 Oxidation
 Bacteria
 Enzymes
 Insects

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 Fat Soluble Vitamins

 Stored in the liver and fatty tissues.
 Daily intake not required.
 Deficiency occurs only after prolonged deprivation.
 Can become toxic if excessive amounts are consumed.

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Fat soluble vits
 Vit.A – involved in reproduction, mucosal integrity,
vision and antioxidant roles !

 Vit.D –obtained from diet or synthesized on the skin
(by using sun light) from cholesterol and regulates
Ca:P ratios in the body.
 Vit.E – involved as antioxidant roles.
 Vit.K – contributes to blood clotting.

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Vitamin A

Lots of double bonds (good anti-
oxidant).

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 Vitamin A
 Carrotinoids are major sources
 Stored in liver
 Has antioxidant roles, in cell division,
mucosal integrity and vimp. ision/sight.

 Deficiency states ch’d by:
 Hyperkeratosis of the skin
 Night blindness
 Other conditions

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 Vitamin D
 Also known as ‘calciferol/calcitriol’ due to its role in
calcium absorption/reabsorption.
 Can be stored in the body.
Sources:-
 It is the only fat soluble vitamin that can be synthesized in
the body (with the presence of sunlight from cholesterol)
 Plant & animal (fish oils, salmon, animal livers, eggs, butter,
cereals & fortified milk ) are main sources.
Function: Main role is to maintain Ca+2 and P- levels (normal
calcification of bones & teeth) in the body.

Note: Vitamin D2 (ergocalciferol) is also known as plant vitamin D obtained
through dietary sources & vitamin D3 (cholecalciferol) is produced in skin by
UV…both have same metabolic effect !

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 Fig. Vit.D synthesis
in the body.

Fig. Activation of Vitamin D.
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Vit.D/calcitriol and Ca+2/P metabolism

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 Vit. D deficiency
 Children & elderly (osteomalacia/osteoporesis) are at risk
(lack of enough sunlight).

‘Rickets’ is caused by lack of
sunlight or vit D (but could also
happen due to insufficient calcium
intake) in children.
Note: Vitamin D linked to
extraskeletal roles !!

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Vitamin D: Toxicity

 Long-term ingestion of excessive amounts causes
toxicity
 Hypertension, weakness, fatigue, headache, many
others
 GI tract effects
 CNS effects

Mosby items and derived
items © 2005, 2002 by
Mosby, Inc.
Vitamin E/ ά-tocopherol

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 Vitamin E…
 Fat soluble (d/t tocopherols)
Sources:
 Dietary plant sources
 Fruits, grains, cereals, vegetables, oils, wheat germ
 Animal sources
 Eggs, chicken, meats, fish
Function: Exact biologic function of vitamin E is unknown
but believed to act as an antioxidant.
Mosby items and derived
items © 2005, 2002 by
Mosby, Inc.
Vitamin K

 Fat soluble
 Three types: K1, K2, K3

 Dietary sources of K1/Phylloquinone
 Green leafy vegetables (cabbage, spinach), meats, milk
 Vitamin K2 synthesized by intestinal flora

Mosby items and derived
items © 2005, 2002 by
Mosby, Inc.
Vit K…

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Vitamin K..
Functions:
 Essential for synthesis of blood coagulation factors in
the liver
 Vitamin K–dependent clotting factors:
 II (prothrombin)
 VII
 IX
X
Mosby items and derived
items © 2005, 2002 by
Mosby, Inc.
Vit. K in Blood Clotting:
 The vitamin K–dependent posttranslational carboxylation
of glutamyl residues that forms γ-carboxyglutamate (by γ-
glutamyl carboxylase) on 4 major proteins (factor II or
prothrombin, VII, IX, and X) required for coagulation of blood.

Fig.
Blood
clotting
cascades

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Vitamin K..
Vit K indications:

 Dietary supplementation
 Treatment of deficiency states (rare)
 During antibiotic therapy
 Newborn infants
 Malabsorption conditions
 To reverse the effects of certain anticoagulants
(warfarin, heparin..)
Mosby items and derived
items © 2005, 2002 by
Mosby, Inc.
 Water Soluble Vitamins
 Can dissolve in water
B1 (Thiamin)-TPP
 Excessive amounts excreted in
the urine, not stored in the B2 (Riboflavin)-FAD+, FMN
body B3 (Niacin) –NAD+, NADP+
PantothenicAcid/B5 -CoA
 With the exception of B6 (Pyridoxine)-PLP
vitamin C (ascorbic acid), B7 (Biotin) -Biotin
water-soluble vitamins are B9 (Folic Acid) - THF
members of the B-complex
B12 (Cobalamin)
and most of them act as co-
enzymes!

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21
 Water Soluble Vitamins..
 Vitamin B1 -Thiamine

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 Thiamine..
Function:-
Involved in carbohydrate metabolism in metabolic
pathways including Kreb’s cycle (as TPP).
i.e. Pyruvate conversion to Acetyl-CoA by PDH complex
enzyme !

 As TDP/TPP, thiamin functions in energy transformation as a
coenzyme of the pyruvate dehydrogenase (PDH) complex,
the α-ketoglutarate dehydrogenase complex, and the
branched chain α-keto acid dehydrogenase complex rxns.
 Maintains integrity of peripheral nervous system, CVS
and GI tracts.

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Deficiency of thiamine
 Def. states called Beriberi (white rice d+).

 Ch’d by brain lesions, polyneuropathy of peripheral
nerves, serous effusions, cardiac anatomic changes..

 Wernicke’s encephalopathy
 Cerebral beriberi
Mosby items and derived
items © 2005, 2002 by
Mosby, Inc.
Causes of Thiamine Deficiencies
 Poor diet
 Extended fever, hyperthyroidism, liver disease,
alcoholism
 Malabsorption conditions
 Pregnancy and breast-feeding

Mosby items and derived
items © 2005, 2002 by
Mosby, Inc.
Vit B2- riboflavin
 Water soluble
 Food sources
 Leafy green vegetables, eggs, nuts, meat, etc

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Vit B2- riboflavin..
 Two co-enzyme forms FMN &
FAD.
 Energy metabolism (a variety
of Oxidation-Reduction
Reactions) !

Note: Flavins can
act as oxidizing agents
because of their ability to
accept a pair of H- atoms.

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e.g. Role of flavoproteins (FAD/FMN)in the electron
transport chain (ETC)/tissue respiration

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Functions…
 In the oxidative decarboxylation of pyruvate and α-
ketoglutarate
 Succinate dehydrogenase is a FAD flavoprotein
 In fatty acid oxidation (fatty acyl CoA dehydrogenase)
 Sphinganine oxidase, in sphingosine synthesis, requires FAD
 As a coenzyme for an oxidase such as xanthine oxidase
 In Vit.B6 metabolism; pyridoxine phosphate oxidase—which
converts pyridoxamine phosphate (PMP) and pyridoxine
phosphate (PNP) to pyridoxal phosphate (PLP).
 Synthesis of an active form of folate/5-methyl THF requires
FADH2
 In try convertion to niacin
 In choline catabolism.

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 B2 Deficiency Causes
 Alcoholism is a major cause
 Deficiency also caused by:
 Intestinal malabsorption
 Long-term infections and liver disease
 Malignancy and probenecid therapy

Mosby items and derived
items © 2005, 2002 by
Mosby, Inc.
Vit B2 Indications
 Dietary supplement
 Treatment of B2 deficiency
 Microcytic anemia
 Acne and migraine headaches
 Many other uses

Mosby items and derived
items © 2005, 2002 by
Mosby, Inc.
 Niacin (B3)
 Food sources
 Meats, beans, liver, yeast,
wheat
 The body can make niacin from
the amino acid tryptophan.
 Role: Energy metabolism
(glycogenolysis, lipid/protein
metab, tissue respiration) and Fig. Niacin
purine metabolism
 Supports nervous and digestive
system and promotes healthy
skin. 32
Two coenzyme forms NAD & NADP (take part in energy
metabolism)

NAD+ NADP+

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Functions :-

 Approximately 200 enzymes, primarily
dehydrogenases, require the coenzymes NAD+ and
NADP+, which act as a hydrogen donor or electron
acceptor.

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Functions..
Some of the oxidative reactions in which NAD+ participates and
is reduced to NADH include:
-Glycolysis
-Oxidative decarboxylation of pyruvate
-Oxidation of acetyl CoA in the TCA cycle
-β-oxidation of fatty acids
-Oxidation of ethanol
The NADP+/NADPH used in a variety of reductive biosyntheses;
-Fatty acid synthesis
-Cholesterol and steroid hormone synthesis
-Oxidation of glutamate & folate metabolism
-Synthesis of deoxyribonucleotides (precursors of DNA)
-Regeneration of glutathione, vitamin C, and thioredoxin

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Vitamin B3 (Niacin)Deficiency
 Niacin deficiency is ch’d by:
 Mental: various psychotic symptoms
 Neurologic: neurasthenic syndrome
 Cutaneous: crusting, erythema
 Mucous membrane: oral, vaginal, and urethral lesions
 GI: diarrhea or bloody diarrhea

Mosby items and derived
items © 2005, 2002 by
Mosby, Inc.
 Niacin Def..
 Like thiamine, which was discovered
through its deficiency disorder
‘beriberi’, niacin was discovered
through the condition ‘pellagra’ (ch’ed
by the three Ds—dermatitis,
dementia, diarrhea) in humans and a
similar condition, called ‘black tongue’,
in dogs !
And death (as 4th D).

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Panthothenic acid- VitB5(Part of CoA)

 Pantothenic acid consists
of β-alanine and pantoic
acid joined by a peptide
bond/amide linkage.

Fig. Pantothenic acid and
CoA (coenzyme form)

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Fig. CoA

Fig. The structure of CoA
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CoA forms thio esters with carboxylic acids and
can transfer the acetyl or acyl groups, typically 2 to
13 carbons, for various cellular reactions:

- Carbohydrate metabolism
-FA synthesis (formation of condensation of acetyl-CoA with
activated CO2 to form malonyl CoA)
-Cholesterol and ketone bodies synthesis (acetyl CoA and
acetoacetyl CoA reaction to form HMG CoA)
-Phospholipid and sphingomyelin production

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 Vit B6 (Pyridoxine)
 Sources
 Whole grains, wheat germ, nuts, yeast
 Fish and organ meats

Vit B6 – Pyridoxine (PLP as the coenzyme form)
Functions:
 Involved as a neurotransmitter, and immune system
 Co-enzyme in > 100 reaction (important in the
metabolism of amino acids/transamination reactions mainly
and also fatty acids metabolism)

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Pyridoxine PLP

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 Vit B6 Functions

 Necessary for many metabolic functions
 Protein, lipid, and carbohydrate utilization
 Conversion of tryptophan to niacin

Necessary for integrity of peripheral nerves, skin,
mucous membranes, hematopoietic system

Mosby items and derived
items © 2005, 2002 by
Mosby, Inc.
Biotin – VitB7

 Functions in energy metabolism as a coenzyme that carries
CO2 (carboxylation rxns)
 Can be synthesized by bacteria in the GI tract..

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 Biotin Plays a role in gluconeogensis, metabolism of
fatty acids and the breakdown of amino acids.

Table: 4 Carboxylases that use biotin in cells

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Fig. The role of Biotin for PC
enzyme
Fig. The oxidation of
propionyl CoA by PCC & the
role of Biotin

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Folate – Folic acid –Vit B9
 Folate is made up of three distinct
parts (as shown below), all of which
must be present
for vitamin activity.
 Coenzyme form is THF
 Important in metabolism and important
in DNA synthesis

 Folate’s and vitamin B12’s discovery
resulted from the search to cure
the disorder megablastic anemia, a
problem in the late 1870s and early
1880s.

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Functions and MoA:-

 THF functions in the body as a coenzyme in both the
mitochondria and cytoplasm to accept one-carbon groups
in amino acid synthesis (metabolism) and DNA synthesis
(purine and pyrimidine synthesis).
 The THF derivatives, which participate in a variety of
reactions…

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DNA (Purine and Pyrimidine) Synthesis

 Synthesis of new cells with short life spans, such as
enterocytes, is particularly dependent on adequate levels of
folate.
 In purine synthesis; Folate as 10-formyl THF is needed for
purine (adenine and guanine) ring formation.
 In pyrimidine synthesis; thymidylate synthetase uses 5,10-
methylene THF to convert dUMP to dTMP (used for DNA
synthesis) and DHF.
 To regenerate 5,10-methylene THF, DHF is converted by dihydrofolate
reductase (DHFR) to THF in a reaction requiring NADPH.
 Both thymidylate synthetase and DHFR are active enzymes in cells
undergoing cell division.

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Fig. The role of Folate in pyrimidine synthesis used for DNA synthesis
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Deficiency disorders:

Megaloblastic/Macrocytic Anemia:

 Megaloblastic Anemia (MA) is deficiency of folate that may
also occur with the def. of vitamin B12 and interferes with
normal cell division. Note: synergistic relationship exists
between folate and vitamin B12/cobalamin !
 MA characterized by increased mean cell volume (MCV), and
hypersegmentation (increased lobes) of white blood cells
(neutrophils) occurs, along with decreased blood cell counts.

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 Folate/B12
deficiency !

Fig. Genesis of normal RBCs and megaloblastic anemia in
Folate/Vit.B12 deficincy
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Methionine regeneration from homocysteine involves folate as 5-methyl THF and Vit B12
synergistic action.

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Other D+es associated to Folate def…
Occlusive vascular diseases including cerebral or
peripheral and coronary artery disease (associated
to hyperhomocysteinemia).

Increased DNA strand breaks and intiations of
some cancers (e.g colon cancers)
CNS/neural devt defects (e.g. ‘Spina bifida’) due to
defective choline synthesis (a major component of
cell membranes).

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Folate def & neural tube defect..

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Vit B12 - Cyanocobalamine
 Vit. B12/Cobalamin contains the corrin nucleus (a
macrocyclic ring made of 4 reduced pyrrole rings
linked together) and in the center of the corrin is
an atom of cobalt (Co) to which is attached, at
almost right angles, is the nucleotide 5,6-
dimethylbenzimidazole.

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Cobalamine..

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Functions and MoA:-

 The reaction requiring methylcobalamin as a coenzyme:
-Methylcobalamin is needed in methionine synthesis or
regeneration. i.e. cobalamin bound to the methionine synthase
(also called homocysteine methyltransferase) picks up the methyl
group from 5-methyl tetrahydrofolate (THF), forming
methylcobalamin bound to methionine synthase and THF.

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MoA…
 Because the formation of 5-methyl THF is
irreversible, a vitamin B12 deficiency traps body
folate in the 5-methyl form, in what is known as the
methyl-folate trap hypothesis.

This hypothesis helps explain in part the synergism
between folate and vitamin B12 !!
 DNA and RNA synthesis (RBC devt, maintains and protects nerve
fibers and promotes their normal growth )!

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60
Vit. B12..

-The 2nd of the
vitamin B12–dependent
reactions requires
adenosylcobalamin
(oxidation of L-Methyl
malony CoA) catalyzed by a
mutase enzyme called
methylmalonyl CoA mutase !
[Imp. for metabolic pathways
including fat and CH2Os
metabolism] !

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Deficiency disorders:-
 Megaloblastic Anemia
 Most deficiency signs and symptoms are of neurologic and hematologic
origin; some signs and symptoms include skin pallor, fatigue, shortness
of breath, palpitations, insomnia, tingling and numbness (paresthesia)
in extremities, abnormal gait, loss of concentration, memory loss,
disorientation, swelling of myelinated fibers, and possibly dementia.
Vit B12 deficiency secondary to malabsorption could be caused by:
- Pernicious anemia (autoimmune condition in which the body
produces Abs that attack gastric parietal cells and decrease IF).
- Atrophic gastritis and gasterectomy
- Achlorhydria (reduced HCl production)
- Increased use of medications for GERD
- Ileitis (inflammation of the Ileum) and in elderly people
 Methylmalonic Aciduria

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Vitamin C (Ascorbic Acid)

 The human being is one of the few mammals
unable to synthesize vitamin C, also known as
ascorbic acid or ascorbate.
 Other animals unable to synthesize vitamin C
include primates, guinea pigs, and some birds.
 The inability to synthesize vitamin C results from
the lack of gulonolactone oxidase (the final
enzymatic reaction in Vit. C synthesis.

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Fig. The interconversion of ascorbate and dehydroascorbate

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Functions and MoA:-

 Acts in oxidation-reduction reactions
(‘anti-oxidant activity’)
 Required for several metabolic activities
-Collagen synthesis; hence maintenance of bone, teeth,
capillaries & connective tissue/tissue repair like skin.
-Carnitine and tyrosine synthesis
-Folic acid metabolism and erythropoiesis
-Enhances absorption of iron (Fe+2)
-Required for the synthesis of lipids, proteins and steroids.
*Aids in resistance to infections e.g. Colds

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Collagen synthesis:-

 Ascorbate functions in a number of hydroxylation reactions
(3 hydroxylation reactions; prolyl 4-hydroxylase, prolyl 3-
hydroxylase and lysyl hydroxylase rxns ) requiring vitamin
C are necessary for collagen synthesis or triple helix
configuration.

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Antioxidant activity:-
 Vitamin C functions in a general capacity as a reducing agent
or electron donor and thereby has antioxidant activity.
 Ascorbic acid acts as a reducing agent in aqueous solutions
such as the blood and within cells.

Examples of reactive oxygen/N species that vitamin C may
reduce include:
-Hydroxyl radical ( OH)
-Hydroperoxyl radical (HO2 )
-Superoxide radical (O 2 )
-Alkoxyl radical (RO )
-Peroxyl radical (RO2 )

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 Once formed, free radicals and reactive species attack
nucleic acids in DNA, PUFAs in phospholipids, and proteins
in cells.
 Ascorbic acid has been shown to interact with oxidants in
the aqueous phase before they initiate damage, especially to
cell lipids.

 Furthermore, ascorbic acid appears to be superior to other
water-soluble antioxidants such as bilirubin, uric acid, and
protein thiols.

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Deficiency:-
Deficient vitamin C intakes result in the deficiency condition
known as scurvy (when plasma vitamin C concentrations
drop to