'Trypsin' () is a
serine protease found in the
digestive system, where it breaks down
proteins. It is used for numerous
biotechnological processes.
Chemistry and function
Trypsin is secreted into the
intestine, where it acts to
hydrolyse proteins into smaller
peptides or amino acids. This is necessary for the uptake of protein in the food. Trypsin
catalyses the hydrolysis of peptide bonds. The enzymatic mechanism is like all other serine proteases: A
catalytic triad serves to make the
active site serine nucleophilic. This is achieved by modifying the electrostatic environment of the serine. The enzymatic reaction that trypsins catalyze is
thermodynamically favorable but requires significant
activation energy (it is "
kinetically unfavorable"). Trypsins have an optimal operating
pH of about 8 and optimal operating temperature of about 37°C.
The
aspartate residue (Asp 189) located in the catalytic pocket (S1) of trypsins is responsible for attracting and stabilizing positively-charged
lysine and/or
arginine, and is thus responsible for the specificity of the enzyme. This means that trypsin predominantly cleaves
proteins at the
carboxyl side (or "
C-terminal side") of the
amino acids
lysine and
arginine, except when either is followed by
proline. Trypsins are considered
endopeptidases, i.e., the cleavage occurs within the
polypeptide chain rather than at the terminal amino acids located at the ends of
polypeptides.
Trypsin is produced in the
pancreas in the form of inactive
zymogen,
trypsinogen. It is then secreted into the
small intestine, where the enzyme
enterokinase activates it into trypsin by proteolytic cleavage. The resulting trypsins themselves activate more trypsinogens (
autocatalysis), so only a small amount of enterokinase is necessary to start the reaction. This activation mechanism is common for most serine proteases, and serves to prevent autodigestion of the pancreas.
The activity of trypsins is not affected by the
inhibitor tosyl phenylalanyl chloromethyl ketone
TPCK, which deactivates
chymotrypsin. This is important because, in some applications, like
mass spectrometry, the specificity of cleavage is important.
Involvement in disease
One consequence of inheriting the autosomal recessive disease
cystic fibrosis is a deficiency of trypsin and other digestive enzymes from the
pancreas. This leads to the disorder termed
meconium ileus. This disorder involves intestinal obstruction (
ileus) due to overly thick
meconium, the dark sticky stuff that is present in the
intestine at birth and which is normally broken down by trypsins and other proteases, then defecated.
Storage
Trypsins should be stored at very cold temperatures (between −20°C and −80°C) to prevent autolysis (self-cleavage). Autolysis may also be prevented by storage of trypsins at pH 3 or by using trypsin modified by e.g. reductive methylation. When the pH is adjusted back to pH 8 activity returns.
Applications
Trypsin is available in high quantities in pancreases, and can be purified rather easily. Hence it has been used widely in various biotechnological processes.
In a
tissue culture lab, trypsins are used to re-suspend cells adherent to the cell culture dish wall during the process of harvesting cells.
Trypsin can also be used to dissociate dissected cells. For example, prior to cell fixing and sorting.
Trypsins can be used to breakdown casein in breast milk. If trypsin is added to a solution of milk powder, the breakdown of casein will cause the milk to become
translucent. The rate of reaction can be measured by using the amount of time it takes for the milk to turn translucent.
Trypsin is commonly used in biological research during
proteomics experiments to digest proteins into peptides for mass spectrometry analysis. Trypsin is particularly suited for this, since it has a very well defined specificity.
Trypsin can also be used to dissolve blood clots in its microbial form and treat inflammation in its pancreatic form.
Trypsin is used in baby food to pre-digest it. It can break down the protein molecules which helps the baby to digest it as its stomach is not strong enough to digest bigger protein molecules.
See also
★
Trypsin inhibitor
References
# Promega
PDF - 58kB
External links
★
Trypsin In-Gel Digestion Protocol for Mass Spectrometry
★
Trypsin Inhibitors and
Trypsin Assay Method at
Sigma-Aldrich
★
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