Tissue transglutaminase or type II transglutaminase (tTG) is a Ca2+dependent enzyme catalyzing an acyl transfer reaction in which
new g
amide bonds are formed between a g-carboxamide
group of peptide-bound glutamine residues and various primary amines.
Binding of Ca2+
ions to tTG and exposure of the active site cysteine are essential
for enzymatic activity. The active site cysteine reacts with the g-carboxamide
of the glutamine forming a g-glutamyl
thioester and releasing ammonia. The transient acyl-enzyme intermediate
then reacts with any nucleophilic primary amine, yielding either an isopeptide
bond or a (g-glutamyl)
polyamine bond.
Crosslinking either through a polyamine
linker or through the formation of the Ne(glutamyl)-lysine
bridge may be not the only reaction catalyzed by transglutaminases. Their
catalytic mechanism, in fact, is very similar to papain's and can function
also in a hydrolytic mode (1). The hydrolysis of a single Gln to a Glu
residue in a protein, though representing a charge of just a few kilocalories
in the thermodynamic behaviour of the side chain, can have an enormous
effect on the equilibria governing the conformation, the oligomeric association-dissociation
and the interactions of the macromolecule with other proteins.
Reactions catalyzed by transglutaminases
are here reported (2). The backbones or peptide substrates carrying TG-reactive
Gln (i.e. acceptor) and Lys (i.e. donor) side chains, are illustrated by
rectangles and ovals, respectively. Reactions I and V reflect the hydrolytic
nature of this group of enzymes, while transamidating possibilities are
shown in reactions II-IV.
TG has a broad specificity for primary
amine acceptors (peptide bound lysines or polyamines), but in contrast
relatively few proteins contain glutamine residues that form acyl-enzyme
intermediates.
Tissue distribution and regulation
of expression
Tissue transglutaminase is a 75
kDa monomeric globular protein expressed in the majority of cells and tissues.
Its subcellular localization is in the cytosolic fraction and no interactions
with other specific subcellular compartments are described. It is translated
as a fully active enzyme and there is no evidence for a proteolytic activation
(3).
Cells such as endothelial cells,
vascular smooth muscle cells, platelets, and epithelial cells of the lens
express the enzyme constitutively and accumulate high levels of active
enzyme (4). In other cells, such as neurons and skeletal muscle cells,
the tTG constitutive expression is very low and not easily detectable.
The promoter of the tTG gene is constitutively
active, due to the presence of a CAAT box as well as of four SP1 sites.
Two SP1 sites are located directly upstream of the TATA box elements and
two are in the 5’UTR (5). The presence of a constitutively active promoter
suggests that the tTG gene expression is regulated by negative or tissue
specific elements; nevertheless no cis-regulatory regions responsible for
cell and tissue specific expression have been identified so far. Alternatively,
posttranslational modifications of the protein structure could be responsible
for the regulation of the catalytic activity of the enzyme in response
to specific stimuli.
Since tTG is expressed in the vast
majority of cells and tissues, it has been also implicated in a wide variety
of functions resulting in intra and/or extracellular structural alterations.
These include modeling of the extracellular matrix (6), stimulus-secretion
coupling (7), receptor mediated endocytosis (8), cell differentiation (9),
tumor growth (10) and programmed cell death (11).
During apoptosis tTG expression is
increased and its catalytic function is activated (11). The fast increase
in the expression of the enzyme in cells undergoing programmed cell death
may be due to a specific induction of the enzyme or rather to the loss
of factors that normally suppress its expression. Cell death may serve
to unmask the activity of the constitutive core-promoter of the tTG gene
and in turn this may lead to the accumulation of the enzyme that occurs
in many dying cells.
Immunohistological studies together
with the isolation of highly polymerized protein products from apoptotic
cells have established tissue transglutaminase as an useful biochemical
marker of programmed cell death. Its precise role in the death process,
though, is still under discussion (12-14). The enzyme could participate
to the death program as part of the killing mechanism or alternatively
it could modulate the course of apoptosis by temporary stabilization of
the dying cell.
Tissue Transglutaminase detection
The detection of the tTG protein
can be pursued by different strategies: i) evaluation of the catalytic
activity of the enzyme, ii) identification of the protein by immunochemical
methods, and iii) evaluation of the products of the crosslinking reaction.
Transglutaminase Activity Assay
The measurement of tTG activity
is based on the incorporation of a labeled amine into N,N’-dimethylcasein.
The use of dimethylcasein, where the lysine side chains are blocked by
methylation, instead of casein as the substrate protein prevents the intrachain
reaction between glutamyl and lysine residues and favours the binding with
amino-groups of polyamines.
Three methods, differing in the usage
of the labeled amine substrate and in the requirement for different pieces
of equipment, are here described.
The first is based on the incorporation
of a radioactive polyamine (e.g. [1,4(n)-3H]putrescine
dihydrochloride) into the N,N’-dimethylcasein substrate.
The second is based on the incorporation
of a fluorescent polyamine (e.g. monodansyl-cadaverine) into the N,N’-dimethylcasein
substrate.
The third is based on the incorporation
of a biotin labeled polyamine [e.g. N-(5’-aminopentyl)biotinamide] into
the N,N’-dimethylcasein substrate.
1) Incorporation
of [1,4(n)-3H]putrescine dihydrochloride into N,N’-dimethylcasein.
This assay is based on the incorporation of a radiolabeled polyamine
(either [H3]putrescine
or [C14]putrescine) into N,N'-dimethylcasein. The
proteins are subsequently precipitated by the addition of TCA, washed and
counted in a liquid scintillation spectrometer (15).
Materials
Prepare two reaction mixture 10x, one
(A) with and one (B) without casein
A)
Tris HCl 1 M pH 8.3
CaCl2 50 mM
NaCl 1.5 M
N,N’-dimethylcasein 2 mg/ml
B)
Tris HCl 1 M pH 8.3
CaCl2 50 mM
NaCl 1.5 M
DTT 100 mM
[1,4(n)-3H]putrescine
dihydrochloride 100 mCi/ml
Purified tTG from Guinea pig liver 1-5
mg/sample
(Sigma Chemical Co.)
Crude extracts 50-200 mg/sample
Test samples should be prepared in Tris
HCl 0.1 M pH 8.3, supplemented with EDTA 1 mM and protease inhibitors (e.g.
Leupeptin 0.1 mM, PMSF 1 mM)
Special equipment
Liquid scintillation spectrometer
Methodology
In order to measure the incorporation
of putrescine both in the presence and in the absence of substrate (N,N’-dimethylcasein),
set up two samples adding, respectively, 0.03 ml of sln.A and 0.03 ml of
sln.B in Eppendorf microfuge tubes.
Add 15 ml
of DTT 100 mM
Add crude extracts (50-100 mg)
or purified tTG (0.05-1 mg)
in Tris HCl 0.1 M pH 8.3 supplemented with protease inhibitors.
Add H2O to 0.3
ml final volume
Add [3H]putrescine
0.2-1 mCi/sample
Each sample, therefore, must have
a final volume of 0.3 ml and the following composition:
Tris HCl 0.1 M pH 8.3
CaCl2 5 mM
NaCl 0.15 M
DTT 5 mM Note: DTT must be added
just before the incubation.
N,N’-Dimethylcasein 0.2 mg/ml
[3H]putrescine
0.2-1 mCi/sample
Crude extracts (50-100 mg)
or purified tTG (0.05-1 mg)
Incubate 90 min at 37°C
Stop the reaction by addition of 100
ml of TCA 50% and 10 ml
of BSA 1 mg/ml to each sample.
Let sit overnight at 4°C
Collect precipitates by a 10 min centrifugation
at 10000 rpm in a microfuge (e.g. Haereus Biofuge), wash the pellet once
with 200 ml
of TCA 10%, once with ethyl alcohol, once with a 50% ethyl alcohol 50%
ethyl ether mix and finally with 100% ethyl ether. Air dry the pellet and
dissolve it in 1% SDS vortexing at maximum speed and boiling. Mix the sample
with 5 ml of scintillation fluid (e.g. Insta Gel, Packard Instrument Co.)
and analyse it in a liquid scintillation spectrometer (e.g. Tri Carb, Packard
Instrument Co.).
Commentary
tTG activity can be measured in
cell extracts or alternatively in purified proteins. tTG from guinea pig
liver, commercially available from Sigma, is a very useful positive control
for this test. This enzyme has to be equilibrated in Tris 0.1 M pH 8.3
and kept on ice until the beginninng of the reaction. Good values are obtained
with 0.05-1 mg
of the commercial enzyme.
Although tTG is described as an ubiquitous
enzyme, its activity is detectable in endothelial and smooth muscle cells,
in arteries, in veins and in capillaries but it might be difficult to measure
it in other cell types and tissues. In the latter case, tTG activity may
result undetectable either because the enzyme concentration is below treshold
or because post-translational modifications or intracellular inhibitors
could affect its catalytic activity.
Critical parameters
This method is very efficient when
guinea pig liver tTG is used. On the contrary, very low values can be obtained
with cell extracts. In such a case, it is necessary to set up the assay
in triplicate in order to get reliable results.
The protocol here described includes
several washes with toxic and dangerous reagents, such as TCA and ethyl
ether. This procedure is tedious and time-consuming, but it yields more
precise results than simply washing the precipitates on glass fiber filters.
Troubleshooting
When the tTG activity is determined
in crude extracts, the proteins present in the sample can compete with
[3H]putrescine. A two-threefold increase in the amount
of [3H]putrescine per sample can solve the problem.
2) Incorporation
of monodansyl-cadaverine into N,N’-dimethylcasein.
The fluorescent molecule monodansyl cadaverine, i.e. N-(5’-aminopentyl)-5-dimethylamino-1-naphtalensulfonamide
(Serva Fine Biochemicals) can be used as the amine donor in the tTG activity
detection assay (16).
The protocol is identical to the one described in paragraph 1), except
that the washed pellet is dissolved in urea 4 M, 2-mercaptoethanol 0.5
mM and is subjected to SDS-PAGE. The acrylamide gels are then fixed in
25% ethyl alcohol, 10% acetic acid and photographed on a 300 nm UV screen
using a Polaroid camera. Exposure time is 14 min when positive/negative
665 instant pack films, 80 ASA, are used (17).
Materials
Prepare two reaction mixture 10x, one (A) with and one (B) without casein
A) Tris HCl 1 M pH 8.3
CaCl2
50 mM
NaCl 1.5
M
N,N’-dimethylcasein
2 mg/ml
B) Tris HCl 1 M pH 8.3
CaCl2
50 mM
NaCl 1.5
M
DTT 100 mM
Monodansylcadaverine 39 mM.
From a 50 mM stock solution in methyl alcohol (stored at -20° C) take
7.5 ml
and dilute in 300 ml
Tris HCl 0.1 M pH 8.3
Purified tTG from Guinea pig liver 1-5
mg/sample
(Sigma)
Crude extracts 50-200 mg/sample
Test samples should be prepared in Tris
HCl 0.1 M pH 8.3, supplemented with EDTA 1 mM and protease inhibitors (e.g.
Leupeptin 0.1 mM, PMSF 1 mM)
Special equipment
300 nm UV screen
Polaroid camera with positive/negative
665 instant pack film, 80 ASA
Methodology
In order to measure the incorporation
of dansylcadaverine both in the presence and in the absence of substrate
(N,N’-dimethylcasein), set up two samples adding, respectively, 0.03 ml
of sln.A and 0.03 ml of sln.B in Eppendorf microfuge tubes.
Add 15 ml
of DTT 100 mM
Add crude extracts (50-100 mg)
or purified tTG (0.05-1 mg)
in Tris HCl 0.1 M pH 8.3 supplemented with protease inhibitors.
Add 30 ml
Monodansylcadaverine 39 mM
Add H2O to 0.3
ml final volume
Each sample, therefore, must have
a final volume of 0.3ml and the following composition:
Tris HCl 0.1 M pH 8.3
CaCl2 5 mM
NaCl 0.15 M
DTT 5 mM (Note: DTT must be added
just before the incubation)
N,N’-Dimethylcasein 0.2 mg/ml
Monodansylcadaverine 3.9 mM
Crude extracts (50-100 mg)
or purified tTG (0.05-1 mg)
Incubate 90 min at 37°C
Stop the reaction by addition of 100
ml of TCA 50% and 10 ml
of BSA 1 mg/ml to each sample.
Let sit overnight at 4°C
Collect precipitates by a 10 min centrifugation
at 10000 rpm in a microfuge (e.g. Haereus Biofuge)
Wash the pellet once weled polyamine
(e.g. N-(5’-aminopentyl)biotinamide) into N,N’-dimethylcasein.
This method is an ELISA based on
the incorporation of a biotin labeled amine into the N,N'-dimethylcasein
substrate bound to an immunoplate. The tTG activity is then revealed by
addition of streptavidine conjugated with alkaline phosphatase (AP) or
horseradish peroxidase (HRPO) (18).
Materials
N,N’-dimethylcasein 10-20 mg/ml in PBS
or in NaHCO3 50 mM for coating the immunoplates
2% (w/v) powdered skimmed milk in PBS
Reaction mixture 10x
Tris HCl 1 M pH 8.3
CaCl2 50 mM
NaCl 1.5 M
DTT 100 mM
N-(5’-aminopentyl)biotinamide 5 mM (Molecular
Probes Inc.). It can be stored at -70°C for up to 2 weeks.
Purified tTG from Guinea pig liver 1-5
mg/sample
(Sigma)
Crude extracts 50-200 mg/sample.
Total volume maximum 0.2 ml/sample
Test samples should be prepared in Tris
HCl 0.1 M pH8.3, supplemented with EDTA 1 mM and protease inhibitors (e.g.
Leupeptin 0.1 mM, PMSF 1 mM).
Streptavidin AP- or HRPO-conjugated
200 mg/ml
Phosphatase substrate (Sigma 104 Phosphatase
Substrate Tablets, Sigma) or peroxidase substrate (BM Blue POD Substrate,
Boehringer)
TBST solution
TrisHCl 10 mM pH8
NaCl 150 mM
Tween 20 0.001% (v/v)
ELISA reader provided with the appropriate
filters (wavelenght: 405 nm for Substrate 104; 495 nm for POD solution)
Methodology
Coat the immunoplates by adding 200
ml
of N,N’-dimethylcasein (10-20 mg/ml in PBS or NaHCO3
50 mM) to each well
Incubate at 4°C overnight or at
37°C for 1 hour
Wash with PBS and add 200 ml/well
of 2% milk in PBS to block free protein-binding sites. Incubate for 1 hour
at 37°C
Wash three times with PBS. The washed
plates can be stored at -20 for up to 4 months
Set up the samples adding to the crude
extracts (50-100 mg/well)
or to the purified tTG (1-10 mg/well)
the appropriate amount of reaction mixture 10x and of DTT 100 mM for a
final reaction volume of 200 ml
Add N-(5’-aminopentyl)biotinamide, 0.5
mM final concentration
Adjust the final volume (200ml)
with H20
Each sample, therefore, must have
a final volume of 0.2 ml and the following composition:
Tris HCl 0.1 M pH 8.5
CaCl2 5 mM
NaCl 0.15 M
DTT 5 mM (Note: DTT must be added
just before the incubation)
0.5 mM biotin labeled amine.
Crude extracts (50-200 mg)
or purified tTG (1-10 mg)
Prepare negative controls replacing
cell extracts with extraction buffer
Incubate the plate at 37°C for 1
hour
Wash the plate several times with TBST
solution
Dilute streptavidin 1-2 mg/ml
in TBST supplemented with 2% milk. Add 200 ml
per well and incubate for 1 hour at room temperature
Wash the plate several times (at least
five) with TBST solution
Develop the reaction by adding 200 ml
of the appropriate substrate (Substrate 104 for AP-labeled and POD Substrate
for HRPO-labeled streptavidin)
Read the plate at 405 nm wavelenght
when the yellow substrate 104 is used, and at 495 nm when the blue POD
is used
Determine tTG activity by comparison
of the absorbance values per min at the addition of substrate and after
30 min. Subtract the negative controls' values. Since the differences are
in the order of magnitude of 0.1 OD, each measurement must be performed
in triplicate
Detection and localization of
tTG protein
Detection and localization of the
tTG protein can be pursued directly via biochemical and immunochemical
methods (enzymatic assays and western blot analysis) or indirectly using
molecular biology techniques (mRNA detection by in situ hybridization).
Hereinafter are listed few studies
employing antibodies against tTG. Monoclonal antibodies have been used
by P.J. Birckbichler et al. (19, 20), by A. Monsonego et al. (21) and by
A.V. Trejo-Skalli et al. (22). Polyclonal antibodies have been used by
G. Melino et al. (12), by L. Fesus et al. (11) and by Z. Chowdhury et al.
(4). Some of them are suitable for immunohystochemistry and immunocytochemistry,
others for western blot analysis.
These reagents are mainly used to
detect by immunohystochemistry the increased levels of tTG described in
apoptosis.
On the other hand, it has been suggested
that tTG activity could be regulated by post-translational modifications
of the enzyme occuring during the cell death process (11).
The identification of such a modification
could represent a convenient marker of the progress through the different
steps of apoptosis, as much as is the cleavage of PARP (poly(ADP-ribose)polymerase).
The digestion of PARP by caspase 3 (apopain-CPP32) is in fact used as a
marker of the early stages of the apoptotic process (23).
We have recently found that tTG is
cleaved in cells undergoing the late stages of apoptosis (manuscript in
preparation). The availability of a reagent (e.g. scFv (24)) detecting
also the cleaved product allows to monitor the progress of apoptosis by
western blot analysis.
Materials
scFv specific for Guinea pig liver tTG,
selected from a phage display library.
Anti myc mAb (clone 9E10, from ATCC)
specific for the scFv tag sequence.
Anti mouse IgG1 HRPO-labeled (Southern
Biotechnology Associates, Inc.)
Lysing solution for cell extracts
TrisHCl 0.1 M pH 8.3
Triton-X-100 1%
EDTA 1 mM
protease inhibitors (Leupeptin 0.1
mM, PMSF 1 mM).
Micro BCA Protein Assay Reagent (Pierce),
for determination of protein concentration
TBST solution
TrisHCl 10 mM pH 8.0N
NaCl 150 mM
Tween 20 0.001% (v/v)
Methodology
Resuspend a 107 cells
pellet in 100 ml
of lysing solution. Let sit 30 min on ice, then spin at 10000 rpm for 10
min at 4°C in an Eppendorf microfuge
Normalize the extracts for protein concentration
Load a 10% SDS-PAGE gel with 20 mg/lane
of crude extracts and with 1-5 mg/lane
of guinea pig liver tTG as control
Process the gel by standard western
blot technique
Saturate the nitrocellulose filter by
soaking in TrisHCl 0.1 M pH 8.5 supplemented with 4% powdered skimmed milk,
for at least 1hour at room temperature
Rinse the nitrocellulose filter in TBST
Incubate with scFv anti-tTG plus anti-myc
mAb (10mg/ml
final dilution) for 1 hour at room temperature
Wash with TBST. Four washes 10 min each
at room temperature
Incubate with HRPO-conjugated goat anti-mouse
IgG1 antibody, 1 mg/ml
in TBST 2% milk, for 1 hour at room temperature
Wash with TBST as above
Develop the assay by ECL (Enhanced Chemioluminescence)
western blotting detection reagents (Amersham)
Commentary
This method has been developed in
the attempt to identify a molecular marker suitable for the detection of
cells irreversibly committed to apoptosis.
A scFv selected for reactivity with
guinea pig liver tTG and specific for the carboxyl terminal portion of
human tTG, detects in western blot analysis a single 75 kDa band in cytoplasmic
extracts from human thymocytes as well as from a large panel of human cell
lines. In crude extracts from human thymocytes undergoing cell death following
dexamethasone treatment, a new 48 kDa band is detected. A similar band
is also observed in extracts from human tumor cell lines that undergo DNA
fragmentation in the presence of Cycloheximide (CHX) or Actinomycin D (ActD).
These findings suggest a correlation between the apoptotic process and
the appearance of the 48kDa band (manuscript in preparation).
The tTG cleavage yielding the 48
kDa fragment occurs in the late phases of apoptosis, simultaneously to
DNA fragmentation and about 8 hours later than PARP cleavage.
Measurement of
e(g -glutamyl)lysine cross-link
and isopeptide
e(g-glutamyl)lysine
cross-links are the footprints of past tTG activity. The presence of isopeptide
bonds in tissues and in apoptotic bodies can be successfully quantitated.
Since the stability of the side chain isopeptide bridge is not different
from that of the peptide backbone, there are no chemical methods of obtaining
differential hydrolysis. Digestion of the pellet with proteolytic enzymes
is therefore used to brake down the backbone to the level of single aminoacid
without hydrolysis of the e-g
isopeptide. The enzymatic digestion is carried out with the sequential
addition of pronase, carboxypeptidase A, B and Y, and leucine aminopeptidase.
The determination of e(g-glutamyl)lysine
peptide is then carried out by an amino acid analyzer using ninhydrin as
detecting reagent.
Reading out the results requires
the comparison between the profile of the test sample and the profiles
of a negative and a positive control. The positive control is represented
by a known amount of e(g-glutamyl)lysine
peptide. The negative control is represented by an aliquot of the test
sample where g-glutamyl
cyclo-transferase has been added. This enzyme degrades the isodipeptide
by cleaving the e(g-glutamyl)lysine
bond and catalysing its conversion to free L-lysine and 5-oxo-1-proline.
Materials
Synthetic e(g-glutamyl)lysine
isopeptide (SERVA)
g-glutamyl
cyclo-transferase
0.1 M Ammonium bicarbonate
Pronase, carboxypeptidase A, B and Y,
and leucine aminopeptidase
Special equipment
Lyophilizer or SpeedVac (Savant)
Amino acid analyzer
Methodology
Solubilize cells in TrisHCl 50 mM pH
7.0, SDS 2%, 2-mercaptoethanol 0.1 M with a 2 hours incubation at room
temperature
Heat the sample at 100°C for 10
min, pass it through a 0.1 mm mesh and centrifuge at 1500xg
Collect supernate (0.2-0.5 mg protein/sample
maximum) and mix it with trichloroacetic acid, final concentration 30%
(w/v). Let sit overnight at 4°C
Collect the precipitated proteins by
centrifugation and wash the pellet in succession with 1 ml of 5% trichloroacetic
acid (3 times), 1 ml of 50% ethyl alcohol/50% aceton mix (3 times) and
with 1 ml of aceton (twice)
Air dry the pellet, then resuspend it
in 0.5 ml of 0.1 M ammonium bicarbonate pH 8.0
Carry out the enzymatic digestion in
NH4HCO3 0.1 M by sequential addition
of the proteolytic enzymes directly to the reaction mixture at 37°C
in the presence of 0.02% sodium azide (25): pronase 5 mg/ml for 18 hours;
a second pronase addition (5 mg/ml) for 18 more hours; leucine aminopeptidase
1 mg/ml for 65 hours; carboxypeptidase A 0.4 mg/ml, carboxypeptidase B
0.4 mg/ml and carboxypeptidase Y 0.4 mg/ml for 24 hours. Before each new
enzyme addition the sample is boiled for 5 min to inactivate the previously
added protease.
Add a volume of trichloroacetic acid
equal to that of the final and remove the precipitate by centrifugation.
Extract the supernatant three times
with 1.5 ml of ethyl ether and concentrate the acqueous layer to a volume
suitable for the analysis.
Split the protein free fraction of the
digest in three aliquots.
Add 10 pmol of e(g-glutamyl)lysine
to the first aliquot, 0.1 U/ml g-glutamyl
cyclo-transferase to the second aliquot and nothing to the third aliquot.
The first two aliquots represent the positive and the negative control,
respectively, the third aliquot represents the test sample. Incubate for
90 min at 37°C
Analyse each aliquot by ion-exchange
chromatography on a amino acid analyzer with litium citrate buffer and
ninhydrin as detecting reagent (26).
Elute (0.2 ml/min) according to the
following program: buffer A (pH 2.90) is pumped for 30 min at 40°C,
buffer B (pH 3.04) for 22 min at 40°C, buffer C (pH 2.95) for 43 min
at 40°C, buffer D (pH 3.34) for 25 min at 40°C, buffer D (pH 3.34)
for 5 min during which column temperature is raised to 65°C and buffer
E (pH 4.24) for 60 min at 65°C. Ninhydrin flow rate is 0.1 ml/min with
the reaction chamber at 115°C.
At the completion of runs, wash the
column for 30 min with 0.3 M lithium hydroxide containing EDTA 5 mM at
a temperature of 65°C.
Reequilibrated then the column in buffer
A with the column temperature returning to 40°C.
The amount of e(g-glutamyl)lysine
isopeptide in a sample is calculated by the comparison of the profiles
obtained from each of the three aliquots. A control containing enzymes
but not cellular extracts should be treated in parallel for each determination.
Commentary
A different chromatographic technique
can also be used to identify e(g-glutamyl)lysine
isopeptide. In this case the protein-free sample derived from enzymatic
digestion is derivatized with o-phtalaldehyde and then loaded on
a HPLC C18 reverse-phase column (26). Also with this technique the quantification
of the e(g-glutamyl)lysine
isopeptide results from the comparison between the profile of the test
sample and the profiles of a negative and a positive control, prepared
as described above.
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