Trace Minerals: Iron, Zinc, Copper, Selenium PDF

Summary

This document is an overview of trace minerals including iron, zinc, copper, and selenium. It covers learning objectives, sources, absorption, function, deficiencies, and toxicity related to each mineral. It provides helpful details on the importance of trace minerals, highlighting the role they play in various bodily functions and the potential consequences of deficiencies or excesses.

Full Transcript

TRACE AND ULTRATRACE MINERALS

13
1

Learning Objectives
13.1 Identify good food sources of the essential minerals
13.2 Explain how the essential minerals are digested, absorbed, transported in the
blood, stored, and excreted
13.3 Describe the functions and mechanisms of action of the essential minerals
13.4 Describe recommended intakes, deficiencies, and toxicities associated with
the essential minerals
13.7 Explain how essential mineral status is assessed

2

IRON
Several oxidation states, Fe6+ to Fe2-, only ferrous (Fe2+) and ferric (Fe3+) are stable
in the body and food
Sources:
Heme: from hemoglobin and myoglobin is 50-60% of the Fe in meats, fish and
poultry
Esp. red meats, oysters & clams
Nonheme: plant foods, dairy (poor source)
Whole grains, nuts, legumes, tofu, spinach
Usually bound to components in foods, needs to be hydrolyzed to be absorbed
Breads, rolls, pasta, cereals, & flour are fortified with Fe
Oral supplements (high doses can cause constipation, stomach pain, and nausea)

3

1
 Iron Content of Selected Foods
Food Iron (mg) Percent DV
Breakfast cereals, 100% of DV for iron, 1 serving 18 100
Oysters, eastern, cooked with moist heat, 3 oz 8 44
White beans, canned, 1 cup 8 44
Chocolate, dark, 45%–69% cacao solids, 3 oz 7 39
Beef liver, pan fried, 3 ounces 5 28
Lentils, boiled and drained, ½ cup 3 17
Spinach, boiled and drained, ½ cup 3 17
Tofu, firm, ½ cup 3 17
Kidney beans, canned, ½ cup 2 11
Chickpeas, boiled and drained, ½ cup 2 11
Tomatoes, canned, stewed, ½ cup 2 11
Beef, braised bottom round, trimmed to 1/8” fat, 3 oz 2 11
Potato, baked, flesh and skin, 1 medium 2 11
Cashew nuts, oil roasted, 1 oz (~18) 2 11
DV= 18 mg

4

Digestion & Absorption
Heme Iron (Fe2+)
Proteases hydrolyze heme from the globin
The globin is digested, the heme is absorbed intact by a carrier
In the enterocyte, heme is hydrolyzed Þ Fe2+ + protoporphyrin

Nonheme Iron (Fe3+)
Must be hydrolyzed from food components and reduced to cross
membrane
Some Fe3+ Þ Fe2+ in the stomach (HCl)
Fe3+ Þ Fe2+ at the brush border (reductases)

5

Enhancers
Sugars
Acids
Acidic pH
Mucin
Animal protein
Low Fe status
Hypoxia Fe2+
Fe3+ Fe3+ Fe 3+
D CYTB
Inhibitors Fe2+
Fe2+ Fe3+
Alkaline pH
Polyphenols Fe2+ Fe2+
Oxalate
Fe2+
Phytate Fe3+
Casein Ferroportin
Egg yolks
Divalent cations
Antacids
High Fe status Fe3+

Increased Fe D M T1: divalent m etal transporter 1
excretion in feces H C P1: hem e carrier protein1
D CYTB: duodenal cytochrom e b reductase
PC PB2: poly (rC )-binding protein

6

2
 Absorption
­ Nonheme Iron Absorption ¯ Iron Absorption
Some acids (ascorbic, citric, lactic acid Polyphenols (tannins in tea or coffee)
Fe 3+ ® Fe 2+) Oxalate (spinach, chocolate, tea)
Sugars (fructose, sorbitol) Phytate (whole grains, legumes, nuts)
Meat, fish or poultry eaten with nonheme Divalent cations (Ca, Zn, Mn)
Mucin Phosvitin – phosphorylated Ser in egg yolk
Low iron status protein
Hypoxia Alkalinization of GI tract: H2 receptor blockers
(Tagamet, Pepcid) and proton pump inhibitors
(Prevacid, Nexium)
High Fe status

7

Iron Must Be Oxidized for Transport
Fe crosses the basolateral membrane through ferroportin
Two Cu-dependent proteins oxidize Fe2+ as it leaves the cell
Intestine: hephaestin
Other cells and plasma: ceruloplasmin
Ferric iron can then bind to transferrin

8

Transport and Cellular Uptake
Free iron can be lethal Tf delivers Fe via transferrin receptors (TfR)
Two negative consequences of free Fe TfR1 - expressed almost everywhere in
­ free radical production the body
Fe2+ + H2 O2 ® Fe3+ + OH- + ·OH Levels respond to iron status
infectious bacteria can use it for growth TfR2 - expressed in hepatocytes and
Transferrin (Tf) transports and delivers Fe erythroblasts; associated with iron
to cells sensing
Glycoprotein with two Fe-binding sites Levels do not change with iron status

20-40% Fe-saturated in adequate Fe Regulates systemic iron homeostasis
status; the remainder is latent capacity via liver Fe and hepcidin synthesis
Tf can bind other minerals: Cr > Cu > Mn >
Cd > Zn > Ni

9

3
10

Fe Storage
Stored in liver (60%), bone marrow, and spleen
Ferritin: Primary storage form of iron (up to 4500 atoms), some is in
the circulation but most intracellularly
Spherical protein made of 24 subunits with a hollow core
Iron is deposited in the center as a variety of ferric compounds
Constantly degraded and resynthesized, making iron readily available
Hemosiderin
Composed of damaged ferritin
Fe released from hemosiderin at a slower rate
Formed in iron excess
Ferritin capacity has been exceeded
Liver is trying to protect the body

11

Systemic Iron Regulation
Liver acts a sensor of Fe status detecting Tf saturation via TfR1 – Tf interaction
Hepcidin (hepatic bactericidal protein, HAMP)
Main regulator of Fe absorption and metabolism in the body
Released from liver when Fe stores are high
Binds ferroportin, disabling Fe transport into blood from enterocytes,
hepatocytes, and reticuloendothelial macrophages
In these cells, ferroportin regulates iron absorption, recycling, and storage,
respectively
Iron accumulates in those cells

12

4
 HFE: Hemochromatosis protein
BMP6: Bone morphogenic protein 6
HJV: Hemojuvelin
IL6: Interleukin 6

13

14

Cellular Iron Regulation
Iron regulatory proteins 1 and 2 (IRP1 and IRP2): Cytoplasmic, bind to iron
response elements (IREs) in specific mRNA segments and regulate synthesis of Fe-
related proteins
In low iron:
↑ DMT1, TfR, DCYTB, ferroportin
↓ Ferritin, δ ALAS
In high iron:
↑ Ferritin, δ ALAS
↓ DMT1, TfR, DCYTB, ferroportin

15

5
16

Roles
Biochemical reactions usually classified as:
oxygen transport and storage
electron transfer
substrate oxidation-reduction

17

Heme group Iron-sulfur clusters Iron metalloenzymes

Active species

5-lipooxygenase

Cytochrome c oxidase
Inactive species

18

6
 Functions and Mechanisms of Action
Heme proteins
Largest group
hemoglobin: transports O 2 to tissue (> 65% of Fe in body)
myoglobin: stores O 2 in tissue, especially muscle (£ 10%)
cytochromes: transport of electrons through respiratory chain
Iron-sulfur proteins
Involved in electron transport, TCA cycle, heme synthesis
Iron metalloenzymes
Monooxygenases, dioxygenases, peroxidases
Insert oxygen into a substrate

19

Functions and Mechanisms of Action
Oxygen transport and storage (Hb, myoglobin) Oxygenases
Electron transport and energy transformation: Amino acid metabolism: phe, tyr, trp, and
Cytochromes and coenzyme Q - arg
cytochrome c reductase (catalyzes the Synthesis of
reduction of cytochrome c by oxidizing CoQ) Niacin
Glycerol phosphate dehydrogenase Carnitine
(glycolysis) and phosphoenolpyruvate Procollagen
carboxykinase (gluconeogenesis) Nitric oxide
Antioxidant and beneficial prooxidant DNA synthesis: Ribonucleotide reductase
functions:
Cytochrome P450 family
Catalase and peroxidase:
Collagen synthesis
Synthesis of thyroid hormone by
thyroperoxidase
Neutrophjils hypochlorite synthesis:
myeloperoxidase

20

Turnover
Fe homeostasis depends on the recycling of body Fe
The amount absorbed is ~ 0.06% of total body iron
Most of the iron in Tf comes from the destruction of Hb, ferritin, and hemosiderin
Old RBC (~120 days) are taken up by macrophages in spleen, bone marrow or liver
and degraded
Hemoglobin is degraded
Heme ® biliverdin ® bilirubin ® bile ® excretion
Fe (20-25 mg/d) is released and transported by transferrin for reuse in
erythropoiesis, or Fe-dependent enzymes, or is stored in macrophages and
reticuloendothelial cells in bone marrow, liver, and spleen

21

7
 Iron turnover

22

Excretion
Excretion
Most Fe losses (~0.6 mg) through the GI tract, ~0.45 mg through minute (~1 mL) blood
loss, and rest in bile and desquamated mucosal cells
Skin losses of ~0.2–0.3 mg with desquamation
A very small amount, about ~0.05 mg in urine
Losses greater in people with gastrointestinal ulcers or intestinal parasites, or with
hemorrhage
On average:
adult males ~0.9-1.0 mg/day; postmenopausal women ~0.7-0.9 mg/day
menstruating person ~1.3-1.4 mg/day due to menses
Average loss of blood during menses: 35 – 80 mL; 0.5 mg Fe/mL; 17.5-45 mg Fe lost; 27.6
mg calculated into requirements

23

Requirements
RDA
Adult male: 8 mg/d, adolescent male: 11 mg/d
Female
adult: 18 mg, adolescent female: 15 mg
post-menopausal: 8 mg
pregnancy: 27 mg
lactating: 9 mg
The average daily iron intake from foods and supplements is 19.3–20.5 mg/d in
men and 17.0–18.9 mg/ in women
The median dietary iron intake in pregnant women is 14.7 mg/day

UL: 45 mg/d

24

8
 Deficiency
Results from:
Insufficient dietary iron
¯ absorption
Pathological blood loss: nosebleed, occult blood loss, wounds, parasites, blood
donations
Signs & Symptoms
Hypochromic microcytic anemia
Pallor, listlessness, impaired cognitive performance
Fingernails: brittle, flattened or concaved (spoon nails)
Pica: ingestion of non-food substances

25

26

Stages of iron status

Depleted Iron Iron deficiency
Overload Normal
stores deficiency anemia

Serum ferritin ↑ N ↓ ↓ ↓↓

Transferrin saturation ↑↑ N N ↓ ↓

Erythrocyte protoporphyrin N N N ↑ ↑↑

MCV N N N N ↓

Hemoglobin N N N N ↓

27

9
 At-risk populations
Infants and young children: low iron content of milk, low body stores and rapid
growth rate
Adolescents during growth spurt
Premenopausal women: menses, low intake, caloric restriction
Pregnant women: ­ blood volume, use by placenta and fetus, blood loss in
childbirth
People with hemorrhage, protein calorie malnutrition, dialysis patients,
achlorhydria, chronic use of alkaline-based drugs, ¯ transit time, steatorrhea,
parasites

28

Iron Deficiency Worldwide
One of the top 10 most serious health problems in the modern world (WHO)
As many as 4-5 billion people (66-80% of population) may be iron deficient
2 billion people (>30% of population) are anemic
Iron deficiency in young children is the rule rather than the exception (45-70%
prevalence)
Associated with developmental delays of cognitive and motor skills
Iron deficient children tend to be pale, weak, eat less, tire easily, be more irritable,
have shorter attention spans, fall ill more frequently, and fail to grow normally

29

Anemia
Low hemoglobin

Iron deficiency
anemia
Low hemoglobin due
to low iron

Iron deficiency
Low levels of iron

World
population

30

10
 Toxicity
Acute
Ÿ Usually due to ingestion of iron supplements
Ÿ Occurs mainly in children
Ÿ Average lethal dose for adults: 200 - 500 mg Fe/kg body weight
For a 2-year-old the lethal dose is about 3 grams
Chronic
Ÿ Accumulation of excess iron Þ destruction of cells of organs including the
pancreas (diabetes), liver (liver failure), and heart (heart failure)
1. Excessive supplement intake
2. Iron tonic ingestion
3. Parenteral
4. Iron loading diseases (hemochromatosis)

31

Iron Toxicity – Genetic Defect
Hemochromatosis arises from a hereditary defect
that results in excessive Fe absorption and storage
Affects 5 in 1,000 people of Northern European
origin
Leads to excess Fe in body
Treatment:
reduce dietary iron
avoid high vitamin C intake
blood removal
chelation drugs

32

Assessment of Iron Status
Most common:
Hemoglobin (Hgb): amount of hemoglobin per dL of blood
Hematocrit (Hct): proportion of total blood volume that is RBC [percentage]
RBC details:
MCV: size of the RBC (most popular)
MCH: average Hgb content of each RBC
MCHC: amount of Hgb/dL RBC
TIBC (total iron binding capacity)
Plasma ferritin can be used to assess iron stores (Stage 1)
Serum transferrin receptor levels ­ (Stage 2)

33

11
 ZINC
A metal, mostly found as Zn2+ (divalent)
Sources
Usually associated with amino acids and nucleic acids
40-70% of Zn in US diet is from animal products
Very good sources: red meats (organ meats) and seafood
Good sources: poultry, pork, dairy
Moderate: whole grains, leafy and root vegetables
Plant sources are less bioavailable
Zinc in pancreatic and biliary secretions are also absorbed for reuse
Heating can cause Zn to complex with other compounds in foods Þ ¯
bioavailability
Supplements: pills, lozenges, sprays, nasal gels

34

Selected Food Sources of Zinc
Food Zinc (mg/serving) Percent DV*
Oysters, Eastern, farmed, raw, 3 c 32 291
Beef, bottom sirloin, roasted, 3 oz 3.8 35
Blue crab, cooked, 3 oz 3.2 29
Breakfast cereals, 25% fortified, 1 serving 2.8 25
Oats, unenriched, cooked with water, 1 c 2.3 21
Pumpkin seeds, roasted, 1 ounce 2.2 20
Pork, chops, bone-in, broiled, 3 oz 1.9 17
Turkey breast, meat only, roasted, 3 oz 1.5 14
Cheese, cheddar, 1.5 oz 1.5 14
Shrimp, cooked, 3 oz 1.4 13
Lentils, boiled, ½ c 1.3 12
Sardines, canned in oil, with bone, 3 oz 1.1 10
Greek yogurt, plain, 6 oz 1.0 9
Milk, 1% milkfat, 1 c 1.0 9
DV: 11 mg

35

Zinc Transporters
Two families of zinc transporter proteins:
14 ZIP transporters increase cytoplasmic Zn concentration by facilitating Zn
influx from extracellular space or from cellular compartments
10 ZnT transporters facilitate Zn efflux across the cell membrane or into cellular
vesicles and decrease intracellular Zn concentration
ZnT and ZIP genes exhibit either up- or down-regulation in response to Zn and
contribute to the tight homeostatic control of zinc
Some transporters exhibit multiple ion specificity - could explain some metal-
metal interactions (ZIP8: Zn & Mn, ZIP14: Zn & Fe)

36

12
 ¯ Zn intake, ­ ZIP4
­ Zn intake, ¯ ZIP4

D M T1

37

Factors Influencing Absorption
¯ absorption: ­ absorption:
antacid use Organic acids (citric acid, etc)
¯ HCl in stomach Amino acids (His, Cys)
H2 receptor blockers (Zantac, Glutathione
Tagamet, Pepcid) Acidic environment
proton pump inhibitors (Prilosec)
phytate, oxalate, polyphenols
divalent cations (Ca2+, Fe2+)

38

Transport, Storage, and Excretion
Transport Distribution and storage
Blood - bound loosely to albumin Found in all organs, especially liver,
Also, transferrin, a-2 macroglobulin, kidneys, muscle, skin, bones
histidine-Zn-cysteine (