Enzymes
An enzyme is any one of many specialised
organic substances, which act as catalysts to regulate the speed of the many
chemical reactions involved in the metabolism of living organisms. Those
enzymes identified now number more than 700. Enzymes are typical catalysts:
they are capable of increasing the rate of reaction without being consumed in
the process.
Enzymes act as catalysts to regulate the rate of chemical reactions involved in
the metabolism of living organisms. Without enzymes most of these reactions
would not take place at a useful rate. This is possible because enzymes reduce
the activation energy needed to start these reactions. With lower activation
energy, minute quantities of an enzyme can accomplish reaction rates at low
temperatures that would otherwise require destructive reagents and high
temperatures. These high temperatures and destructive reagents would destroy
most organic matter in the soil. Additionally, as extraordinarily efficient
catalysts, enzymes are capable of increasing the rate of reaction without being
consumed in the reactions.
Some enzymes control many different reactions, whereas others are extremely
specific and may accelerate only one reaction. Still others release energy to
make the heart beat and the lungs expand and contract. Many facilitate the
conversion of sugar and foods into the various substances the body requires for
tissue-building, the replacement of blood cells, and the release of chemical
energy to move muscles. As a class, enzymes are extraordinarily efficient.
Minute quantities of an enzyme can accomplish at low temperatures what an
ordinary chemical would require violent reagents and high temperatures to
accomplish. About 30g of pure crystalline pepsin, for example, would be capable
of digesting nearly 2 metric tons of egg white in a few hours.
The rates of enzyme reactions differ somewhat from those of simple inorganic
reactions. Each enzyme is selectively specific for the substance in which it
causes a reaction and is most effective at a temperature particular to it.
Although an increase in temperature may accelerate a reaction, enzymes are
unstable when heated. Many enzymes require the presence of another ion or a
molecule, called a cofactor, in order to function.
Enzymes are classified into several broad categories, such as hydrolytic,
oxidizing, and reducing, depending on the type of reaction they control.
Hydrolytic enzymes accelerate reactions in which a substance is broken down
into simpler compounds through reaction with water molecules. Oxidizing
enzymes, known as oxidases, accelerate oxidation reactions; reducing enzymes
speed up reduction reactions, in which oxygen is removed. Many other enzymes
catalyse other types of reactions. Pepsin, trypsin, and some other enzymes possess,
in addition, the peculiar property known as autocatalysis, which permits them
to cause their own formation from an inert precursor called zymogen. As a
consequence, these enzymes may be reproduced in a test tube.
As a rule, enzymes do not attack living cells. As soon as a cell dies,
however, it is rapidly digested by enzymes that break down protein. The
resistance of the living cell is due to the enzyme's inability to pass through
the membrane of the cell as long as the cell lives. When the cell dies, its
membrane becomes permeable, and the enzyme can then enter the cell and destroy
the protein within it. Some cells also contain enzyme inhibitors, known as
antienzymes, which prevent the action of an enzyme upon a substrate.
Alcoholic fermentation and other important industrial processes depend on the
action of enzymes that are synthesised by the yeasts and bacteria used in the
production process. A number of enzymes are used for medical purposes. Some
have been useful in treating areas of local inflammation; trypsin is employed
in removing foreign matter and dead tissue from wounds and burns.
Alcoholic fermentation is undoubtedly the oldest known enzyme reaction. This
and similar phenomena were believed to be spontaneous reactions until 1857,
when the French chemist Louis Pasteur proved that fermentation occurs only in
the presence of living cells. Subsequently, however, the German chemist Eduard
Buchner discovered (1897) that a cell-free extract of yeast can cause alcoholic
fermentation. The ancient puzzle was then solved; the yeast cell produces the
enzyme, and the enzyme brings about the fermentation. As early as 1783 the
Italian biologist Lazzaro Spallanzani had observed that meat could be digested
by gastric juices extracted from hawks. This experiment was probably the first
in which a vital reaction was performed outside the living organism. After
Buchner's discovery scientists assumed that fermentations and vital reactions
in general were caused by enzymes. Nevertheless, all attempts to isolate and
identify their chemical nature were unsuccessful. In 1926, however, the
American biochemist James B. Sumner succeeded in isolating and crystallizing
urease. Four years later pepsin and trypsin were isolated and crystallized by
the American biochemist John H. Northrop. Enzymes were found to be proteins,
and Northrop proved that the protein was actually the enzyme and not simply a
carrier for another compound.
Research in enzyme chemistry in recent years has shed new light on some of the
most basic functions of life. Ribonuclease, a simple three-dimensional enzyme
discovered in 1938 by the American bacteriologist René Dubos and isolated in
1946 by the American chemist Moses Kunitz, was synthesized by American
researchers in 1969. The synthesis involves hooking together 124 molecules in
a very specific sequence to form the macromolecule. Such syntheses led to the
probability of identifying those areas of the molecule that carry out its
chemical functions, and opened up the possibility of creating specialised
enzymes with properties not possessed by the natural substances. This
potential has been greatly expanded in recent years by genetic engineering
techniques that have made it possible to produce some enzymes in great
quantity.
The medical uses of enzymes are illustrated by research into L-asparaginase,
which is thought to be a potent weapon for treatment of leukemia; into
dextrinases, which may prevent tooth decay; and into the malfunctions of
enzymes that may be linked to such diseases as phenylketonuria, diabetes, and
anemia and other blood disorders.