General Introduction
to Amino Acids
Overview
How Do We
Categorize Amino Acids?
The Amino Acid /
Protein Assembly Process
Overview
Amino acids are the chemical units or "building blocks," that make up proteins.
They also are the end products of protein digestion, or hydrolysis. Amino acids contain
about 16 percent nitrogen. Chemically, this is what distinguishes them from the other two
basic nutrients, sugars and fatty acids, which do not contain nitrogen.
To understand how vital amino acids are, you must understand how essential proteins are to
life. It is protein that provides the structure for all living things. Every living
organism, from the largest animal to the tiniest microbe, is composed of protein. And in
its various forms, protein participates in the vital chemical processes that sustain life.
People often do not realize their need for amino acids, because they are not aware of how
busy the human body is.
• Every second the bone marrow makes 2.5 million red cells.
• Every four days most of the lining of the gastrointestinal tract
and the
blood platelets are replaced.
• Most of the white cells are replaced in ten days.
• A person has the equivalent of new skin in twenty-four days and
bone collagen
in thirty years.
All this continuous repair work requires amino acids.
Proteins are a necessary part of every living cell in the body. Next to water, protein
makes up the greatest portion of our body weight.
- In the human body, protein
substances make up the muscles, ligaments, tendons, organs, glands, nails, hair, and many
vital body fluids, and are essential for the growth of bones.
- The enzymes and hormones that
catalyze and regulate all bodily processes are proteins.
- Proteins help to regulate the
body's water balance and maintain the proper internal pH. They assist in the exchange of
nutrients between the intercellular fluids and the tissues, blood, and lymph. A deficiency
of protein can upset the body's fluid balance, causing edema.
- Proteins form the structural
basis of chromosomes, through which genetic information is passed from parents to
offspring. The genetic "code" contained in each cell's DNA is actually
information for how to make that cell's proteins.
After digestion of protein in the stomach,
amino acids are transferred to the blood. Once in the blood, the amino acids are carried
by both the red blood cells and by the liquid part of the blood, called the plasma. The
amino acids are thereby distributed to all the body tissues, where the various body cells
take what they need to repair and reform the protein structures they need.
The blood contains amino acids at all times. Fasting does not clear them, and a high
protein diet does not materially increase them. The body has a constant need for protein
amino acids, and it keeps a fairly uniform balance.
(a) Amino Acids As a Protein Substrate
Proteins are chains of amino acids linked together by what are called peptide bonds. Each
individual type of protein is composed of a specific group of amino acids in a specific
chemical arrangement. It is the particular amino acids and the way in which they are
linked together in sequence that gives the proteins that make up the various tissues their
unique functions and characters. Each protein in the body is tailored for a specific need;
proteins are not interchangeable.
The proteins that make up the human body are not obtained directly from the diet. Rather,
dietary protein is broken down into its constituent amino acids, which the body then uses
to build the specific proteins it needs. Thus, it is the amino acids rather than protein
that are the essential nutrients.
(b) Amino Acids In the Body’ Metabolism
There are other amino acids that are important in metabolic functions.
- Some, such as citruline,
glutathione, ornithine, and taurine, can be similar to (or byproducts of) the
protein-building amino acids.
- Some act as neurotransmitters
or as precursors of neurotransmitters, the chemicals that carry information from one nerve
cell to another. Certain amino acids are thus necessary for the brain to receive and send
messages.
- Amino acids also enable
vitamins and minerals to perform their jobs properly. Even if vitamins and minerals are
absorbed and assimilated by the body, they cannot be effective unless the necessary amino
acids are present. For example, low levels of the amino acid tyrosine may lead to iron
deficiency.
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How Do We
Categorize Amino Acids?
There are approximately twenty-eight commonly known amino acids that are combined in
various ways to create the thousands of different types of proteins present in all living
things. In the human body, the liver produces about 80 percent of the amino acids needed.
The remaining 20 percent must be obtained from the diet. These are called the essential
amino acids. The essential amino acids that must enter the body through diet are:
• histidine
• isoleucine
• leucine
• lysine
• methionine
• phenylalanine
• threonine
• tryptophan
• valine
The nonessential amino acids, which can be
manufactured in the body from other amino acids obtained from dietary sources, include:
alanine |
glutamine |
asparagines |
glycine |
citrulline |
ornithine |
cysteine |
proline |
cystine |
serine |
gamma-aminobutyric acid |
taurine |
glutamic acid |
tyrosine |
The fact that they are termed
"nonessential" does not mean that they are not necessary, only that they need
not necessarily be obtained through the diet because the body can manufacture them as
needed. And nonessential amino acids can become "essential" under certain
conditions. For instance, the nonessential amino acids cysteine and tyrosine are made from
the essential amino acids methionine and phenylalanine. If methionine and phenylalanine
are not available in sufficient quantities, cysteine and tyrosine then become essential in
the diet.
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The Amino Acid / Protein Assembly Process
The processes of assembling amino acids to make proteins, and of breaking down proteins
into individual amino acids for the body's use, are continuous ones. When we need more
enzyme proteins, the body produces more enzyme proteins; when we need more cells, the body
produces more proteins for cells. These different types of proteins are produced as the
need arises. Should the body become depleted of its reserves of any of the essential amino
acids, it would not be able to produce the proteins that require those amino acids. An
inadequate supply of even one essential amino acid can hinder the synthesis, and reduce
body levels, of necessary proteins. Further, all of the essential amino acids must be
present simultaneously in the diet in order for the other amino acids to be utilized.
How could such a situation occur? More easily than you might think. Many factors can
contribute to deficiencies of essential amino acids, even if you eat a well-balanced diet
that contains enough protein. Impaired absorption, infection, trauma, stress, drug use,
age, and imbalances of other nutrients can all affect the availability of essential amino
acids in the body. Insufficient intake of vitamins and minerals, especially vitamin C, can
interfere with the absorpbon of amino acids in the lower part of the small intestines.
Vitamin B6 is needed also, for the transport of amino acids in the body.
If your diet is not properly balanced-that is, if it fails to supply adequate amounts of
the essential amino acids sooner or later, this will become apparent as some type of
physical disorder. This does not mean, however, that eating a diet containing enormous
amounts of protein is the answer. In fact, it is unhealthy. Excess protein puts undue
stress on the kidneys and the liver, which are faced with processing the waste products of
protein metabolism. Nearly half of the amino acids in dietary protein are transformed into
glucose by the liver and utilized to provide needed energy to the cells. This process
results in a waste product, ammonia. Ammonia is toxic to the body, so the body protects
itself by having the liver turn the ammonia into a much less toxic compound, urea, which
is then carried through the bloodstream, filtered out by the kidneys, and excreted.
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