Everything about Enzymes totally explained
Enzymes are
biomolecules that
catalyze (
for example increase the rates of)
chemical reactions. Almost all enzymes are
proteins. In enzymatic reactions, the
molecules at the beginning of the process are called
substrates, and the enzyme converts them into different molecules, the products. Almost all processes in a
biological cell need enzymes in order to occur at significant rates. Since enzymes are extremely selective for their substrates and speed up only a few reactions from among many possibilities, the set of enzymes made in a cell determines which
metabolic pathways occur in that cell.
Like all catalysts, enzymes work by lowering the
activation energy (
Ea or Δ
G‡) for a reaction, thus dramatically increasing the rate of the reaction. Most enzyme reaction rates are millions of times faster than those of comparable uncatalyzed reactions. As with all catalysts, enzymes are not consumed by the reactions they catalyze, nor do they alter the
equilibrium of these reactions. However, enzymes do differ from most other catalysts by being much more specific. Enzymes are known to catalyze about 4,000 biochemical reactions. A few
RNA molecules called
ribozymes catalyze reactions, with an important example being some parts of the
ribosome. Synthetic molecules called
artificial enzymes also display enzyme-like catalysis.
Enzyme activity can be affected by other molecules.
Inhibitors are molecules that decrease enzyme activity;
activators are molecules that increase activity. Many
drugs and
poisons are enzyme inhibitors. Activity is also affected by
temperature, chemical environment (for example
pH), and the
concentration of substrate. Some enzymes are used commercially, for example, in the synthesis of
antibiotics. In addition, some household products use enzymes to speed up biochemical reactions (
for example, enzymes in biological
washing powders break down protein or
fat stains on clothes; enzymes in
meat tenderizers break down proteins, making the meat easier to chew).
Etymology and history
As early as the late 1700s and early 1800s, the digestion of
meat by stomach secretions and the conversion of
starch to
sugars by plant extracts and
saliva were known. However, the mechanism by which this occurred hadn't been identified.
In the 19th century, when studying the
fermentation of sugar to
alcohol by
yeast,
Louis Pasteur came to the conclusion that this fermentation was catalyzed by a vital force contained within the yeast cells called "
ferments", which were thought to function only within living organisms. He wrote that "alcoholic fermentation is an act correlated with the life and organization of the yeast cells, not with the death or putrefaction of the cells."
In 1878 German physiologist
Wilhelm Kühne (1837–1900) first used the term, which comes from
Greek ενζυμον "in leaven", to describe this process. The word
enzyme was used later to refer to nonliving substances such as
pepsin, and the word
ferment used to refer to chemical activity produced by living organisms.
In 1897
Eduard Buchner began to study the ability of yeast extracts that lacked any living yeast cells to ferment sugar. In a series of experiments at the
University of Berlin, he found that the sugar was fermented even when there were no living yeast cells in the mixture. He named the enzyme that brought about the fermentation of sucrose "
zymase". In 1907 he received the
Nobel Prize in Chemistry "for his biochemical research and his discovery of cell-free fermentation". Following Buchner's example; enzymes are usually named according to the reaction they carry out. Typically the suffix
-ase is added to the name of the
substrate (
for example,
lactase is the enzyme that cleaves
lactose) or the type of reaction (
for example,
DNA polymerase forms DNA polymers).
Having shown that enzymes could function outside a living cell, the next step was to determine their biochemical nature. Many early workers noted that enzymatic activity was associated with proteins, but several scientists (such as Nobel laureate
Richard Willstätter) argued that proteins were merely carriers for the true enzymes and that proteins
per se were incapable of catalysis. However, in 1926,
James B. Sumner showed that the enzyme
urease was a pure protein and crystallized it; Sumner did likewise for the enzyme
catalase in 1937. The conclusion that pure proteins can be enzymes was definitively proved by
Northrop and
Stanley, who worked on the digestive enzymes pepsin (1930), trypsin and chymotrypsin. These three scientists were awarded the 1946 Nobel Prize in Chemistry.
This discovery that enzymes could be crystallized eventually allowed their structures to be solved by
x-ray crystallography. This was first done for
lysozyme, an enzyme found in tears, saliva and
egg whites that digests the coating of some bacteria; the structure was solved by a group led by
David Chilton Phillips and published in 1965. This high-resolution structure of lysozyme marked the beginning of the field of
structural biology and the effort to understand how enzymes work at an atomic level of detail.
Structures and mechanisms
Enzymes are generally globular proteins and range from just 62 amino acid residues in size, for the
monomer of
4-oxalocrotonate tautomerase, to over 2,500 residues in the animal
fatty acid synthase. A small number of RNA-based biological catalysts exist, with the most common being the
ribosome, these are either referred to as
RNA-enzymes, or
ribozymes. The activities of enzymes are determined by their
three-dimensional structure. Most enzymes are much larger than the substrates they act on, and only a small portion of the enzyme (around 3–4
amino acids) is directly involved in catalysis. The region that contains these catalytic residues, binds the substrate, and then carries out the reaction is known as the
active site. Enzymes can also contain sites that bind
cofactors, which are needed for catalysis. Some enzymes also have binding sites for small molecules, which are often direct or
indirect products or substrates of the reaction catalyzed. This binding can serve to increase or decrease the enzyme's activity, providing a means for
feedback regulation.
Like all proteins, enzymes are made as long, linear chains of amino acids that
fold to produce a
three-dimensional product. Each unique amino acid sequence produces a specific structure, which has unique properties. Individual protein chains may sometimes group together to form a
protein complex. Most enzymes can be
denatured—that is, unfolded and inactivated—by heating, which destroys the
three-dimensional structure of the protein. Depending on the enzyme, denaturation may be reversible or irreversible.
Specificity
Enzymes are usually very specific as to which reactions they catalyze and the
substrates that are involved in these reactions. Complementary shape, charge and
hydrophilic/
hydrophobic characteristics of enzymes and substrates are responsible for this specificity. Enzymes can also show impressive levels of
stereospecificity,
regioselectivity and
chemoselectivity.
Some of the enzymes showing the highest specificity and accuracy are involved in the copying and expression of the
genome. These enzymes have "proof-reading" mechanisms. Here, an enzyme such as
DNA polymerase catalyzes a reaction in a first step and then checks that the product is correct in a second step. This two-step process results in average error rates of less than 1 error in 100 million reactions in high-fidelity
mammalian polymerases. Similar proofreading mechanisms are also found in
RNA polymerase,
aminoacyl tRNA synthetases and
ribosomes.
Some enzymes that produce
secondary metabolites are described as promiscuous, as they can act on a relatively broad range of different substrates. It has been suggested that this broad substrate specificity is important for the evolution of new biosynthetic pathways.
"Lock and key" model
Enzymes are very specific, and it was suggested by
Emil Fischer in 1894 that this was because both the enzyme and the substrate possess specific complementary geometric shapes that fit exactly into one another. This is often referred to as "the lock and key" model. However, while this model explains enzyme specificity, it fails to explain the stabilization of the transition state that enzymes achieve.
The "lock and key" model has proven inaccurate and the induced fit model is the most currently accepted enzyme-substrate-coenzyme figure.
Induced fit model
In 1958
Daniel Koshland suggested a modification to the lock and key model: since enzymes are rather flexible structures, the active site is continually reshaped by interactions with the substrate as the substrate interacts with the enzyme. As a result, the substrate doesn't simply bind to a rigid active site, the amino acid
side chains which make up the active site are moulded into the precise positions that enable the enzyme to perform its catalytic function. In some cases, such as glycosidases, the substrate molecule also changes shape slightly as it enters the active site. The active site continues to change until the substrate is completely bound, at which point the final shape and charge is determined.
Mechanisms
Enzymes can act in several ways, all of which lower ΔG
‡:
- Lowering the activation energy by creating an environment in which the transition state is stabilized (for example straining the shape of a substrate - by binding the transition-state conformation of the substrate/product molecules, the enzyme distorts the bound substrate(s) into their transition state form, thereby reducing the amount of energy required to complete the transition).
- Lowering the energy of the transition state, but without distorting the substrate, by creating an environment with the opposite charge distribution to that of the transition state.
- Providing an alternative pathway. For example, temporarily reacting with the substrate to form an intermediate ES complex, which would be impossible in the absence of the enzyme.
- Reducing the reaction entropy change by bringing substrates together in the correct orientation to react. Considering ΔH‡ alone overlooks this effect.
Interestingly, this entropic effect involves destabilization of the ground state, and its contribution to catalysis is relatively small.
Transition State Stabilization
The understanding of the origin of the reduction of ΔG
‡ requires one to find out how the enzymes can stabilize its transition state more than the transition state of the uncatalyzed reaction. Apparently, the most effective way for reaching large stabilization is the use of electrostatic effects, in particular, by having a relatively fixed polar environment that's oriented toward the charge distribution of the transition state. Such an environment doesn't exist in the uncatalyzed reaction in water.
Dynamics and function
Recent investigations have provided new insights into the connection between internal dynamics of enzymes and their mechanism of catalysis.
An enzyme's internal dynamics are described as the movement of internal parts (
for example amino acids, a group of amino acids, a loop region, an alpha helix, neighboring beta-sheets or even entire domain) of these biomolecules, which can occur at various time-scales ranging from
femtoseconds to seconds. Networks of protein residues throughout an enzyme's structure can contribute to catalysis through dynamic motions. Protein motions are vital to many enzymes, but whether small and fast vibrations or larger and slower conformational movements are more important depends on the type of reaction involved. These new insights also have implications in understanding allosteric effects and developing new drugs.
It should be clarified, however, that the dynamical time-dependent processes are not likely to help to accelerate enzymatic reactions, since such motions randomize and the rate constant is determined by the probability (P) of reaching the transition state, (P = exp (in
lungs; low CO
2 concentration)
Nevertheless, if the equilibrium is greatly displaced in one direction, that is, in a very
exergonic reaction, the reaction is
effectively irreversible. Under these conditions the enzyme will, in fact, only catalyze the reaction in the thermodynamically allowed direction.
Kinetics
Enzyme kinetics is the investigation of how enzymes bind substrates and turn them into products. The rate data used in kinetic analyses are obtained from
enzyme assays.
In 1902
Victor Henri proposed a quantitative theory of enzyme kinetics, but his experimental data were not useful because the significance of the hydrogen ion concentration wasn't yet appreciated. After
Peter Lauritz Sørensen had defined the logarithmic pH-scale and introduced the concept of buffering in 1909 the German chemist
Leonor Michaelis and his Canadian postdoc
Maud Leonora Menten repeated Henri's experiments and confirmed his equation which is referred to as
Henri-Michaelis-Menten kinetics (sometimes also
Michaelis-Menten kinetics). Their work was further developed by
G. E. Briggs and
J. B. S. Haldane, who derived kinetic equations that are still widely used today.
The major contribution of Henri was to think of enzyme reactions in two stages. In the first, the substrate binds reversibly to the enzyme, forming the enzyme-substrate complex. This is sometimes called the Michaelis complex. The enzyme then catalyzes the chemical step in the reaction and releases the product.
Enzymes can catalyze up to several million reactions per second. For example, the reaction catalyzed by
orotidine 5'-phosphate decarboxylase will consume half of its substrate in 78 million years if no enzyme is present. However, when the decarboxylase is added, the same process takes just 25 milliseconds. Enzyme rates depend on solution conditions and substrate concentration. Conditions that denature the protein abolish enzyme activity, such as high temperatures, extremes of pH or high salt concentrations, while raising substrate concentration tends to increase activity. To find the maximum speed of an enzymatic reaction, the substrate concentration is increased until a constant rate of product formation is seen. This is shown in the saturation curve on the right. Saturation happens because, as substrate concentration increases, more and more of the free enzyme is converted into the substrate-bound ES form. At the maximum velocity (
Vmax) of the enzyme, all the enzyme active sites are bound to substrate, and the amount of ES complex is the same as the total amount of enzyme.
However,
Vmax is only one kinetic constant of enzymes. The amount of substrate needed to achieve a given rate of reaction is also important. This is given by the
Michaelis-Menten constant (
Km), which is the substrate concentration required for an enzyme to reach one-half its maximum velocity. Each enzyme has a characteristic
Km for a given substrate, and this can show how tight the binding of the substrate is to the enzyme. Another useful constant is
kcat, which is the number of substrate molecules handled by one active site per second.
The efficiency of an enzyme can be expressed in terms of
kcat/
Km. This is also called the specificity constant and incorporates the
rate constants for all steps in the reaction. Because the specificity constant reflects both affinity and catalytic ability, it's useful for comparing different enzymes against each other, or the same enzyme with different substrates. The theoretical maximum for the specificity constant is called the diffusion limit and is about 10
8 to 10
9 (M
-1 s
-1). At this point every collision of the enzyme with its substrate will result in catalysis, and the rate of product formation isn't limited by the reaction rate but by the diffusion rate. Enzymes with this property are called
catalytically perfect or
kinetically perfect. Example of such enzymes are
triose-phosphate isomerase,
carbonic anhydrase,
acetylcholinesterase,
catalase, fumarase, β-lactamase, and
superoxide dismutase.
Michaelis-Menten kinetics relies on the
law of mass action, which is derived from the assumptions of free
diffusion and thermodynamically-driven random collision. However, many biochemical or cellular processes deviate significantly from these conditions, because of very high concentrations, phase-separation of the enzyme/substrate/product, or one or two-dimensional molecular movement. In these situations, a
fractal Michaelis-Menten kinetics may be applied.
Some enzymes operate with kinetics which are faster than diffusion rates, which would seem to be impossible. Several mechanisms have been invoked to explain this phenomenon. Some proteins are believed to accelerate catalysis by drawing their substrate in and pre-orienting them by using dipolar electric fields. Other models invoke a quantum-mechanical
tunneling explanation, whereby a proton or an electron can tunnel through activation barriers, although for proton tunneling this model remains somewhat controversial. Quantum tunneling for protons has been observed in
tryptamine. This suggests that enzyme catalysis may be more accurately characterized as "through the barrier" rather than the traditional model, which requires substrates to go "over" a lowered energy barrier.
Inhibition
Enzyme reaction rates can be decreased by various types of
enzyme inhibitors.
Competitive inhibition
In competitive inhibition, the inhibitor and substrate compete for the enzyme (for example, they can not bind at the same time). Often competitive inhibitors strongly resemble the real substrate of the enzyme. For example, methotrexate is a competitive inhibitor of the enzyme dihydrofolate reductase, which catalyzes the reduction of dihydrofolate to tetrahydrofolate. The similarity between the structures of folic acid and this drug are shown in the figure to the right bottom. Note that binding of the inhibitor need not be to the substrate binding site (as frequently stated), if binding of the inhibitor changes the conformation of the enzyme to prevent substrate binding and vice versa. In competitive inhibition the maximal velocity of the reaction isn't changed, but higher substrate concentrations are required to reach a given velocity, increasing the apparent Km.
Uncompetitive inhibition
In uncompetitive inhibition the inhibitor can not bind to the free enzyme, but only to the ES-complex. The EIS-complex thus formed is enzymatically inactive. This type of inhibition is rare, but may occur in multimeric enzymes.
Non-competitive inhibition
Non-competitive inhibitors can bind to the enzyme at the same time as the substrate, for example they never bind to the active site. Both the EI and EIS complexes are enzymatically inactive. Because the inhibitor can not be driven from the enzyme by higher substrate concentration (in contrast to competitive inhibition), the apparent Vmax changes. But because the substrate can still bind to the enzyme, the Km stays the same.
Mixed inhibition
This type of inhibition resembles the non-competitive, except that the EIS-complex has residual enzymatic activity.
In many organisms inhibitors may act as part of a feedback mechanism. If an enzyme produces too much of one substance in the organism, that substance may act as an inhibitor for the enzyme at the beginning of the pathway that produces it, causing production of the substance to slow down or stop when there's sufficient amount. This is a form of negative feedback. Enzymes which are subject to this form of regulation are often multimeric and have allosteric binding sites for regulatory substances. Their substrate/velocity plots are not hyperbolar, but sigmoidal (S-shaped).
Irreversible inhibitors react with the enzyme and form a covalent adduct with the protein. The inactivation is irreversible. These compounds include eflornithine a drug used to treat the parasitic disease sleeping sickness. Penicillin and Aspirin also act in this manner. With these drugs, the compound is bound in the active site and the enzyme then converts the inhibitor into an activated form that reacts irreversibly with one or more amino acid residues.
Uses of inactivators
Inhibitors are often used as drugs, but they can also act as poisons. However, the difference between a drug and a poison is usually only a matter of amount, since most drugs are toxic at some level, as
Paracelsus wrote, "
In all things there's a poison, and there's nothing without a poison." Equally,
antibiotics and other anti-infective drugs are just specific poisons that kill a pathogen but not its
host.
An example of an inactivator being used as a drug is
aspirin, which inhibits the
COX-1 and
COX-2 enzymes that produce the
inflammation messenger
prostaglandin, thus suppressing pain and inflammation. The poison
cyanide is an irreversible enzyme inactivator that combines with the copper and iron in the active site of the enzyme
cytochrome c oxidase and blocks
cellular respiration.
Biological function
Enzymes serve a wide variety of
functions inside living organisms. They are indispensable for
signal transduction and cell regulation, often via
kinases and
phosphatases. They also generate movement, with
myosin hydrolysing ATP to generate
muscle contraction and also moving cargo around the cell as part of the
cytoskeleton. Other ATPases in the cell membrane are
ion pumps involved in
active transport. Enzymes are also involved in more exotic functions, such as
luciferase generating light in
fireflies.
Viruses can also contain enzymes for infecting cells, such as the
HIV integrase and
reverse transcriptase, or for viral release from cells, like the
influenza virus
neuraminidase.
An important function of enzymes is in the
digestive systems of animals. Enzymes such as
amylases and
proteases break down large molecules (
starch or
proteins, respectively) into smaller ones, so they can be absorbed by the intestines. Starch molecules, for example, are too large to be absorbed from the intestine, but enzymes hydrolyse the starch chains into smaller molecules such as
maltose and eventually
glucose, which can then be absorbed. Different enzymes digest different food substances. In
ruminants which have a
herbivorous diets, microorganisms in the gut produce another enzyme,
cellulase to break down the cellulose cell walls of plant fiber.
Several enzymes can work together in a specific order, creating
metabolic pathways. In a metabolic pathway, one enzyme takes the product of another enzyme as a substrate. After the catalytic reaction, the product is then passed on to another enzyme. Sometimes more than one enzyme can catalyze the same reaction in parallel, this can allow more complex regulation: with for example a low constant activity being provided by one enzyme but an inducible high activity from a second enzyme.
Enzymes determine what steps occur in these pathways. Without enzymes, metabolism would neither progress through the same steps, nor be fast enough to serve the needs of the cell. Indeed, a metabolic pathway such as
glycolysis couldn't exist independently of enzymes. Glucose, for example, can react directly with ATP to become
phosphorylated at one or more of its carbons. In the absence of enzymes, this occurs so slowly as to be insignificant. However, if
hexokinase is added, these slow reactions continue to take place except that phosphorylation at carbon 6 occurs so rapidly that if the mixture is tested a short time later,
glucose-6-phosphate is found to be the only significant product. Consequently, the network of metabolic pathways within each cell depends on the set of functional enzymes that are present.
Control of activity
There are five main ways that enzyme activity is controlled in the cell.
Enzyme production (transcription and translation of enzyme genes) can be enhanced or diminished by a cell in response to changes in the cell's environment. This form of gene regulation is called enzyme induction and inhibition. For example, bacteria may become resistant to antibiotics such as penicillin because enzymes called beta-lactamases are induced that hydrolyse the crucial beta-lactam ring within the penicillin molecule. Another example are enzymes in the liver called cytochrome P450 oxidases, which are important in drug metabolism. Induction or inhibition of these enzymes can cause drug interactions.
Enzymes can be compartmentalized, with different metabolic pathways occurring in different cellular compartments. For example, fatty acids are synthesized by one set of enzymes in the cytosol, endoplasmic reticulum and the Golgi apparatus and used by a different set of enzymes as a source of energy in the mitochondrion, through β-oxidation.
Enzymes can be regulated by inhibitors and activators. For example, the end product(s) of a metabolic pathway are often inhibitors for one of the first enzymes of the pathway (usually the first irreversible step, called committed step), thus regulating the amount of end product made by the pathways. Such a regulatory mechanism is called a negative feedback mechanism, because the amount of the end product produced is regulated by its own concentration. Negative feedback mechanism can effectively adjust the rate of synthesis of intermediate metabolites according to the demands of the cells. This helps allocate materials and energy economically, and prevents the manufacture of excess end products. Like other homeostatic devices, the control of enzymatic action helps to maintain a stable internal environment in living organisms.
Enzymes can be regulated through post-translational modification. This can include phosphorylation, myristoylation and glycosylation. For example, in the response to insulin, the phosphorylation of multiple enzymes, including glycogen synthase, helps control the synthesis or degradation of glycogen and allows the cell to respond to changes in blood sugar. Another example of post-translational modification is the cleavage of the polypeptide chain. Chymotrypsin, a digestive protease, is produced in inactive form as chymotrypsinogen in the pancreas and transported in this form to the stomach where it's activated. This stops the enzyme from digesting the pancreas or other tissues before it enters the gut. This type of inactive precursor to an enzyme is known as a zymogen.
Some enzymes may become activated when localized to a different environment (eg. from a reducing (cytoplasm) to an oxidising (periplasm) environment, high pH to low pH etc). For example, hemagglutinin in the influenza virus is activated by a conformational change caused by the acidic conditions, these occur when it's taken up inside its host cell and enters the lysosome.
Involvement in disease
Since the tight control of enzyme activity is essential for homeostasis, any malfunction (mutation, overproduction, underproduction or deletion) of a single critical enzyme can lead to a genetic disease. The importance of enzymes is shown by the fact that a lethal illness can be caused by the malfunction of just one type of enzyme out of the thousands of types present in our bodies.
One example is the most common type of phenylketonuria. A mutation of a single amino acid in the enzyme phenylalanine hydroxylase, which catalyzes the first step in the degradation of phenylalanine, results in build-up of phenylalanine and related products. This can lead to mental retardation if the disease is untreated.
Another example is when germline mutations in genes coding for DNA repair enzymes cause hereditary cancer syndromes such as xeroderma pigmentosum. Defects in these enzymes cause cancer since the body is less able to repair mutations in the genome. This causes a slow accumulation of mutations and results in the development of many types of cancer in the sufferer.
Naming conventions
An enzyme's name is often derived from its substrate or the chemical reaction it catalyzes, with the word ending in -ase. Examples are lactase, alcohol dehydrogenase and DNA polymerase. This may result in different enzymes, called isoenzymes, with the same function having the same basic name. Isoenzymes have a different amino acid sequence and might be distinguished by their optimal pH, kinetic properties or immunologically. Furthermore, the normal physiological reaction an enzyme catalyzes may not be the same as under artificial conditions. This can result in the same enzyme being identified with two different names. E.g. Glucose isomerase, used industrially to convert glucose into the sweetener fructose, is a xylose isomerase in vivo.
The International Union of Biochemistry and Molecular Biology have developed a for enzymes, the EC numbers; each enzyme is described by a sequence of four numbers preceded by "EC".
The first number broadly classifies the enzyme based on its mechanism:
The top-level classification is
EC 1 Oxidoreductases: catalyze oxidation/reduction reactions
EC 2 Transferases: transfer a functional group (for example a methyl or phosphate group)
EC 3 Hydrolases: catalyze the hydrolysis of various bonds
EC 4 Lyases: cleave various bonds by means other than hydrolysis and oxidation
EC 5 Isomerases: catalyze isomerization changes within a single molecule
EC 6 Ligases: join two molecules with covalent bonds
The complete nomenclature can be browsed at http://www.chem.qmul.ac.uk/iubmb/enzyme/.
Industrial applications
Enzymes are used in the chemical industry and other industrial applications when extremely specific catalysts are required. However, enzymes in general are limited in the number of reactions they've evolved to catalyze and also by their lack of stability in organic solvents and at high temperatures. Consequently, protein engineering is an active area of research and involves attempts to create new enzymes with novel properties, either through rational design or in vitro evolution.
| Application |
Enzymes used |
Uses |
| Baking industry |
Fungal alpha-amylase enzymes are normally inactivated at about 50 degrees Celsius, but are destroyed during the baking process. |
Catalyze breakdown of starch in the flour to sugar. Yeast action on sugar produces carbon dioxide. Used in production of white bread, buns, and rolls. |
| Proteases |
Biscuit manufacturers use them to lower the protein level of flour. |
| Baby foods |
Trypsin |
To predigest baby foods. |
| Brewing industry |
Enzymes from barley are released during the mashing stage of beer production. |
They degrade starch and proteins to produce simple sugar, amino acids and peptides that are used by yeast for fermentation. |
| Industrially produced barley enzymes |
Widely used in the brewing process to substitute for the natural enzymes found in barley. |
| Amylase, glucanases, proteases |
Split polysaccharides and proteins in the malt. |
| Betaglucanases and arabinoxylanases |
Improve the wort and beer filtration characteristics. |
| Amyloglucosidase and pullulanases |
Low-calorie beer and adjustment of fermentability. |
| Proteases |
Remove cloudiness produced during storage of beers. |
|
Acetolactatedecarboxylase (ALDC) |
Avoid the formation of diacetyl |
| Fruit juices |
Cellulases, pectinases |
Clarify fruit juices |
| Dairy industry |
Rennin, derived from the stomachs of young ruminant animals (like calves and lambs). |
Manufacture of cheese, used to hydrolyze protein. |
| Microbially produced enzyme |
Now finding increasing use in the dairy industry. |
| Lipases |
Is implemented during the production of Roquefort cheese to enhance the ripening of the blue-mould cheese. |
| Lactases |
Break down lactose to glucose and galactose. |
| Meat tenderizers |
Papain |
To soften meat for cooking. |
| Starch industry |
Amylases, amyloglucosideases and glucoamylases |
Converts starch into glucose and various syrups. |
| Glucose isomerase |
Converts glucose into fructose in production of high fructose syrups from starchy materials. These syrups have enhanced sweetening properties and lower calorific values than sucrose for the same level of sweetness. |
| Paper industry |
Amylases, Xylanases, Cellulases and ligninases |
Degrade starch to lower viscosity, aiding sizing and coating paper. Xylanases reduce bleach required for decolorising; cellulases smooth fibers, enhance water drainage, and promote ink removal; lipases reduce pitch and lignin-degrading enzymes remove lignin to soften paper. |
| Biofuel industry |
Cellulases |
Used to break down cellulose into sugars that can be fermented (see cellulosic ethanol). |
| Ligninases |
Use of lignin waste |
| Biological detergent |
Primarily proteases, produced in an extracellular form from bacteria |
Used for presoak conditions and direct liquid applications helping with removal of protein stains from clothes. |
| Amylases |
Detergents for machine dish washing to remove resistant starch residues. |
| Lipases |
Used to assist in the removal of fatty and oily stains. |
| Cellulases |
Used in biological fabric conditioners. |
| Contact lens cleaners |
Proteases |
To remove proteins on contact lens to prevent infections. |
| Rubber industry |
Catalase |
To generate oxygen from peroxide to convert latex into foam rubber. |
| Photographic industry |
Protease (ficin) |
Dissolve gelatin off scrap film, allowing recovery of its silver content. |
| Molecular biology |
Restriction enzymes, DNA ligase and polymerases |
Used to manipulate DNA in genetic engineering, important in pharmacology, agriculture and medicine. Essential for restriction digestion and the polymerase chain reaction. Molecular biology is also important in forensic science. |
Further Information
Get more info on 'Enzymes'.
|
External Link Exchanges
Do you know how hard it is to get a link from a large encyclopaedia? Well we're different and will prove it. To get a link from us just add the following HTML to your site on a relevant page:
<a href="http://enzyme.totallyexplained.com">Enzyme Totally Explained</a>
Then simply click through this link from your web page. Our crawlers will verify your link, extract the title of your web page and instantly add a link back to it. If you like you can remove the words Totally Explained and embed the link in article text.
As long as your link remains in place, we'll keep our link to you right here. Please play fair - our crawlers are watching. Your site must be closely related to this one's topic. Any kind of spamming, dubious practises or removing the link will result in your link from us being dropped and, potentially, your whole site being banned. |
