Copper Facts

[Guest guest]

What Dr. Linus Pauling  has to say about copper: 

from the " Linus Pauling Institute "

 

Zinc: High supplemental zinc intakes of 50 mg/day or more for extended periods

of time may result in copper deficiency. High dietary zinc increases the

synthesis of an intestinal cell protein called metallothionein, which binds

certain metals and prevents their absorption by trapping them in intestinal

cells. Metallothionein has a stronger affinity for copper than zinc, so high

levels of metallothionein induced by excess zinc cause a decrease in intestinal

copper absorption. High copper intakes have not been found to affect zinc

nutritional status.

 

COPPER

Copper (Cu) is an essential trace element for humans and animals. In the body,

copper shifts between the cuprous (Cu1+) and the cupric (Cu2+) forms, though the

majority of the body's copper is in the Cu2+ form. The ability of copper to

easily accept and donate electrons explains its important role in

oxidation-reduction (redox) reactions and the scavenging of free radicals (1).

Although Hippocrates is said to have prescribed copper compounds to treat

diseases as early as 400 B.C. (2), scientists are still uncovering new

information regarding the functions of copper in the human body. 

 

FUNCTION

Copper is a critical functional component of a number of essential enzymes,

known as cuproenzymes. Some of the physiologic functions known to be

copper-dependent are discussed below. 

Energy production The copper-dependent enzyme, cytochrome c oxidase, plays a

critical role in cellular energy production. By catalyzing the reduction of

molecular oxygen (O2) to water (H2O), cytochrome c oxidase generates an

electrical gradient used by the mitochondria to create the vital energy-storing

molecule, ATP (3).

Connective tissue formation

 

Another cuproenzyme, lysyl oxidase, is required for the cross-linking of

collagen and elastin, which are essential for the formation of strong and

flexible connective tissue. The action of lysyl oxidase helps maintain the

integrity of connective tissue in the heart and blood vessels and plays a role

in bone formation (2).

 

Iron metabolism

Two copper-containing enzymes, ceruloplasmin (ferroxidase I) and ferroxidase II

have the capacity to oxidize ferrous iron (Fe2+) to ferric iron (Fe3+), the form

of iron that can be loaded onto the protein transferrin for transport to the

site of red blood cell formation. Although the ferroxidase activity of these two

cuproenzymes has not yet been proven to be physiologically significant, the fact

that iron mobilization from storage sites is impaired in copper deficiency

supports their role in iron metabolism (2,4).

 

Central nervous system

A number of reactions essential to normal function of the brain and nervous

system are catalyzed by cuproenzymes.

 

Neurotransmitter synthesis: Dopamine-b-monooxygenase catalyzes the conversion of

dopamine to the neurotransmitter norepinephrine (4).

Metabolism of neurotransmitters: Monoamine oxidase (MAO) plays a role in the

metabolism of the neurotransmitters norepinephrine, epinephrine, and dopamine.

MAO also functions in the degradation of the neurotransmitter serotonin, which

is the basis for the use of MAO inhibitors as antidepressants (5).

Formation and maintenance of myelin: The myelin sheath is made of phospholipids

whose synthesis depends on cytochrome c oxidase activity (2).

 

Melanin formation

The cuproenzyme, tyrosinase, is required for the formation of the pigment

melanin. Melanin is formed in cells called melanocytes and plays a role in the

pigmentation of the hair, skin, and eyes (2).

 

Antioxidant functions

Superoxide dismutase: Superoxide dismutase (SOD) functions as an antioxidant  by

catalyzing the conversion of superoxide radicals (free radicals or ROS) to

hydrogen peroxide, which can subsequently be reduced to water by other

antioxidant enzymes (6). Two forms of SOD contain copper: 1) copper/zinc SOD is

found within most cells of the body, including red blood cells, and 2)

extracellular SOD is a copper containing enzyme found in high levels in the

lungs and low levels in blood plasma (2).

 

Ceruloplasmin: Ceruloplasmin may function as an antioxidant in two different

ways. Free copper and iron ions are powerful catalysts of free radical damage.

By binding copper, ceruloplasmin prevents free copper ions from catalyzing

oxidative damage. The ferroxidase activity of ceruloplasmin (oxidation of

ferrous iron) facilitates iron loading onto its transport protein, transferrin,

and may prevent free ferrous ions (Fe2+) from participating in harmful free

radical generating reactions (6).

 

Regulation of gene expression

Copper-dependent transcription factors regulate transcription of specific genes.

Thus, cellular copper levels may affect the synthesis of proteins by enhancing

or inhibiting the transcription of specific genes. Genes regulated by

copper-dependent transcription factors include genes for copper/zinc superoxide

dismutase (Cu/Zn SOD), catalase (another antioxidant enzyme), and proteins

related to the cellular storage of copper (3).

 

Nutrient-nutrient interactionsIron: Adequate copper nutritional status appears

to be necessary for normal iron metabolism and red blood cell formation. Anemia

is a clinical sign of copper deficiency, and iron has been found to accumulate

in the livers of copper deficient animals, indicating that copper (probably in

the form of ceruloplasmin) is required for iron transport to the bone marrow for

red blood cell formation (see Iron Metabolism) (2). Infants fed a high iron

formula absorbed less copper than infants fed a low iron formula, suggesting

that high iron intakes may interfere with copper absorption in infants (5).

 

Zinc: High supplemental zinc intakes of 50 mg/day or more for extended periods

of time may result in copper deficiency. High dietary zinc increases the

synthesis of an intestinal cell protein called metallothionein, which binds

certain metals and prevents their absorption by trapping them in intestinal

cells. Metallothionein has a stronger affinity for copper than zinc, so high

levels of metallothionein induced by excess zinc cause a decrease in intestinal

copper absorption. High copper intakes have not been found to affect zinc

nutritional status (2,5).

 

Fructose: High fructose diets have exacerbated copper deficiency in rats, but

not in pigs whose gastrointestinal systems are more like those of humans. Very

high levels of dietary fructose (20% of total calories) did not result in copper

depletion in humans, suggesting that fructose intake does not result in copper

depletion at levels relevant to normal diets (2,5).

 

Vitamin C: Although vitamin C supplements have produced copper deficiency in

laboratory animals, the effect of vitamin C supplements on copper nutritional

status in humans is less clear. Two small studies in healthy young adult men

indicate that the oxidase activity of ceruloplasmin may be impaired by

relatively high doses of supplemental vitamin C. In one study, vitamin C

supplementation of 1,500 mg/day for 2 months resulted in a significant decline

in ceruloplasmin oxidase activity (7). In the other study, supplements of 605 mg

of vitamin C/day for 3 weeks resulted in decreased ceruloplasmin oxidase

activity, although copper absorption did not decline (8). Neither of these

studies found vitamin C supplementation to adversely affect copper nutritional

status.

 

DEFICIENCY

Clinically evident or frank copper deficiency is relatively uncommon. Serum

copper levels and ceruloplasmin levels may fall to 30% of normal in cases of

severe copper deficiency. One of the most common clinical signs of copper

deficiency is an anemia that is unresponsive to iron therapy but corrected by

copper supplementation. The anemia is thought to result from defective iron

mobilization due to decreased ceruloplasmin activity. Copper deficiency may also

result in abnormally low numbers of white blood cells known as neutrophils

(neutropenia), a condition that may be accompanied by increased susceptibility

to infection. Osteoporosis and other abnormalities of bone development related

to copper deficiency are most common in copper-deficient low-birth weight

infants and young children. Less common features of copper deficiency may

include loss of pigmentation, neurological symptoms, and impaired growth (2,3). 

 

Individuals at risk of deficiency

Cow's milk is relatively low in copper, and cases of copper deficiency have been

reported in high-risk infants and children fed only cow's milk formula.

High-risk individuals include: premature infants, especially those with

low-birth weight, infants with prolonged diarrhea, infants and children

recovering from malnutrition, individuals with malabsorption syndromes,

including celiac disease, sprue, and short bowel syndrome due to surgical

removal of a large portion of the intestine.  Individuals receiving intravenous

total parenteral nutrition or other restricted diets may also require

supplementation with copper and other trace elements (2,3). Recent research

indicates that cystic fibrosis patients may also be at increased risk of copper

insufficiency (9). 

 

The Recommended Dietary Allowance (RDA)

A variety of indicators were used to establish the recommended dietary allowance

(RDA) for copper, including plasma copper concentration, serum ceruloplasmin

activity, superoxide dismutase activity in red blood cells, and platelet copper

concentration (5). The RDA for copper reflects the results of

depletion-repletion studies and is based on the prevention of deficiency.

 

Recommended Dietary Allowance (RDA) for Copper

 

Life Stage 

Age 

Males (mcg/day) 

Females (mcg/day) 

 

Infants 

0-6 months

200 (AI) 

200 (AI) 

 

Infants 

7-12 months 

220 (AI) 

220 (AI) 

 

Children 

1-3 years 

340 

340 

 

Children

 4-8 years 

440 

440 

 

Children 

9-13 years 

700 

700 

 

Adolescents 

14-18 years 

890 

890 

 

Adults 

19 years and older

900

900 

 

Pregnancy 

all ages 

 -

1,000 

 

Breastfeeding 

all ages 

 - 

1,300

 

DISEASE PREVENTION

Cardiovascular diseases

While it is clear that severe copper deficiency results in heart abnormalities

and damage (cardiomyopathy) in some animal species, the pathology differs from

atherosclerotic cardiovascular diseases prevalent in humans (5). Studies in

humans have produced inconsistent results, and their interpretation is hindered

by the lack of a reliable marker of copper nutritional status. Outside the body,

free copper is known to be a pro-oxidant and is frequently used to produce

oxidation of low density lipoprotein (LDL) in the test tube. Recently, the

copper-containing protein ceruloplasmin has been found to stimulate LDL

oxidation in the test tube (10), leading some scientists to propose that

increased copper levels could increase the risk of atherosclerosis by promoting

the oxidation of LDL. However, there is little evidence that copper or

ceruloplasmin promotes LDL oxidation in the human body. Additionally, the

cuproenzymes, superoxide dismutase and ceruloplasmin, are known to have

antioxidant properties, leading some experts to propose that copper deficiency

rather than excess copper increases the risk of cardiovascular diseases (11).

 

Epidemiological studies: Several epidemiological studies have found increased

serum copper levels to be associated with increased risk of cardiovascular

disease. A recent prospective study in the U.S. examined serum copper levels in

more than 4,400 men and women 30 years of age and older (12). During the

following 16 years, 151 participants died from coronary heart disease (CHD).

After adjusting for other risk factors of heart disease, those with serum copper

levels in the two highest quartiles had a significantly greater risk of dying

from CHD. Three other case-control studies conducted in Europe had similar

findings. Serum copper largely reflects serum ceruloplasmin, and is not a

sensitive indicator of copper nutritional status. Serum ceruloplasmin levels are

known to increase by 50% or more under certain conditions of physical stress,

such as trauma, inflammation, or disease. Because over 90% of serum copper is

carried in ceruloplasmin, elevated serum copper may simply be a marker of the

inflammation that accompanies atherosclerosis. In contrast to the serum copper

findings, two autopsy studies found copper levels in heart muscle to be lower in

patients who died of CHD than those who died of other causes (13). Additionally,

the copper content of white blood cells has been positively correlated with the

degree of patency of coronary arteries in CHD patients (14, 15), and patients

with a history of myocardial infarction (MI) had lower concentrations of

extracellular superoxide dismutase (SOD) than those without a history of MI

(16).

 

Experimental studies: While studies in very small numbers of adults fed

experimental diets low in copper have demonstrated adverse changes in blood

cholesterol levels, including increased total and LDL-cholesterol levels and

decreased HDL-cholesterol levels (17), other studies have not confirmed those

results (18). Copper supplementation of 2-3 mg/day for 4 to 6 weeks did not

result in clinically significant changes in cholesterol levels (11, 19). Recent

research has also failed to find evidence that increased copper intake increases

oxidative stress. In a multi-center placebo-controlled study, copper

supplementation of 3 and 6 mg/day for 6 weeks did not result in increased

susceptibility of LDL to oxidation induced outside the body (ex vivo) by copper

or peroxynitrite (a reactive nitrogen species) (20). Moreover, supplementation

with 3 and 6 mg/day of copper decreased the in vitro oxidizability of red blood

cells (21), indicating that relatively high intakes of copper do not increase

the susceptibility of LDL or red blood cells to oxidation.

Summary: Although free copper and ceruloplasmin can promote LDL oxidation in the

test tube, there is little evidence that increased dietary copper increases

oxidative stress in humans. Increased serum copper levels have been associated

with increased cardiovascular disease risk, but the significance of these

findings is unclear due to the association between serum ceruloplasmin levels

and inflammatory conditions. Clarification of the relationships between copper

nutritional status, ceruloplasmin levels, and cardiovascular disease risk

requires further research.

 

Immune system function

Copper is known to play an important role in the development and maintenance of

immune system function, but the exact mechanism of its action is not yet known.

Neutropenia (abnormally low numbers of white blood cells called neutrophils) is

a clinical sign of copper deficiency in humans. Adverse effects of insufficient

copper on immune function appear most pronounced in infants. Infants with Menkes

disease, a genetic disorder that results in severe copper deficiency, suffer

from frequent and severe infections (22, 23). In a study of 11 malnourished

infants with evidence of copper deficiency, the ability of certain white blood

cells to engulf pathogens increased significantly after one month of copper

supplementation (24). More recently, 11 men on a low-copper diet (0.66 mg

copper/day for 24 days and 0.38 mg/day for another 40 days) showed a decreased

proliferation response when white blood cells called mononuclear cells isolated

from their blood were presented with an immune challenge in cell culture (25).

While severe copper deficiency has adverse effects on immune function, the

effects of marginal copper insufficiency in humans are not yet clear.

 

Osteoporosis

The copper-dependent enzyme, lysyl oxidase, is required for the maturation

(cross-linking) of collagen, a key element in the organic matrix of bone.

Osteoporosis has been observed in infants and adults with severe copper

deficiency, but it is not clear whether marginal copper deficiency contributes

to osteoporosis. Research regarding the role of copper nutritional status in

age-related osteoporosis is limited. Serum copper levels of 46 elderly patients

with hip fractures were reported to be significantly lower than matched controls

(26). A small study in perimenopausal women, who consumed an average of 1 mg of

dietary copper daily, reported decreased loss of bone mineral density (BMD) from

the lumbar spine after copper supplementation of 3 mg/day for 2 years (27).

Marginal copper intake of 0.7 mg/day for 6 weeks significantly increased a

measurement of bone resorption (breakdown) in healthy adult males (28). However,

copper supplementation of 3 to 6 mg/day for 6 weeks had no effect on

biochemical markers of bone resorption or bone formation in a study of healthy

adult men and women (29). Although severe copper deficiency is known to

adversely affect bone health, the effects of marginal copper deficiency and

copper supplementation on bone metabolism and age-related osteoporosis require

further research before conclusions can be drawn.

 

The RDA for copper (900 mcg/day for adults) is sufficient to prevent deficiency,

but the lack of clear indicators of copper nutritional status in humans makes it

difficult to determine the level of copper intake most likely to promote optimum

health or prevent chronic disease. A varied diet should provide enough copper

for most people. For those who are concerned that their diet may not provide

adequate copper, a multivitamin/multimineral supplement will generally provide

at least the RDA for copper.