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A new purification procedure for Clostridium difficile enterotoxin
Vol. 124, No. 3, 1984
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS Pages
November 14, 1984
A NEW PURIFICATION Rihn
B.,
PROCEDURE FOR CLOSTRIDIUM DIFFICILE Scheftel
J.M.,
Girardot
R.,
690-695
ENTEROTOXIN
and Monteil
H.
Institut
de Bact&iologie de la Faculte de MBdecine - Universite 3, rue Koeberl6 - 67000 STRASBOURG - FRANCE
Received
September
cytotoxin. filtration, composed
Clostridium difficile produces two toxins, an enterotoxin and a The enterotoxin was purified using fast methods (tangential flow The purified enterotoxin is fast protein liquid chromatography). of two subunits (A1 = 41,500, A2 = 16,000) and its p1 is 3.5. 0 1984
Academic
Press,
17,
Pasteur
1984
Inc.
C.difficile pseudomembranous pathogeny
Louis
is
the This
colitis.
of APC : an enterotoxin The cytotoxin
toxin
has the property
toxin
named enterotoxin
ileal
loop
assay
or toxin of rounding or
toxin
and experimental
we report
a rapid
method
MATERIALS
AND METHODS
for
agent
causative organism
produces
of
antibiotic-associated
two toxins
implicated
in the
and a cytotoxin. B has been purified
by several
different
cells
in culture
A induces
fluid
accumulation
ileocecitis
the purification
in hamster
groups (10,15). in
(5,13).
of C.difficile
toxin
:
this
Another the
In this
rabbit work
A.
Bacterial strain, culture conditions and toxin concentration : C.difficile (strain 79685 was isolated in our laboratory from stool of a patient with pseudomembranous colitis). This strain was grown in an anaerobic Chamber (CO2 containing brain10 %, H 5 %, N 85 %) for 60 hours in three 5 liter-flasks heart br&h (In&itut Pasteur Production) at 37OC under stirring. The culture was then filtered using a sangential flow system in a microporoys filter HVLP (0,5 p; filter area : 5 ft ; recirculation rate : 100 ml/min/ft ; pressure : 10 psi; Millipore). Sixteen liters of filtrate (corresponding to 111 g of proteins) were ultrafiltered with the same system using a PTGC filter with a nominal molecular weight limit of 10,000 (Millipore). During this step the retentate (1,050 ml; 15.5 g of proteins) was equilibrated in 10 mM Tris-HCl buffer pH 7.4. Enterotoxic methods :
and cytotoxic assays : Toxic activities fluid accumulation in the isolated rabbit
were ileal
determined by two loop according to
Abbreviations: APC, antibiotic-associated pseudomembranous colitis; tridium; FPLC fast protein liquid chromatography; IEF, isoelectric MW, molecular weight; PAGE, polyacrylamid gel electrophoresis. 0006-291X/84 Copyright All rights
$1.50
0 I984 by Acudemic Press, Inc. of reproduction in any form reserved.
C, Closfocusing;
BIOCHEMICAL
Vol. 124, No. 3, 1984
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the Pierce and Wallace method (9), cytopathic rounding of Mac Coy Cells (15). The rabbit method for enterotoxin detection.
effect consisting ileal loop assay
of complete a specific
is
Chromatography methods : A fast protein liquid chromatography (Pharmacia) a GP-250 gradient apparatus, was used. It was composed of two P-500 pumps, a FRAC-100 fraction collector and a programmer, two UV-1 and UV-2 monitors, REG482 recorder. Anion exchange chromatography was performed on a Mono Q column (100 x 10 mm, Pharmacia). In each run, 150 mg of protein from the retentate fraction were applied. Fractions containing the enterotoxic activity obtained after Mono Q run, were desalted on Pharmacia PD-10 column and lyophilized. The proteins were equilibrated with the starting buffer (50 NaCl 150 mM) used for chromatofocusing which was achieved mM Tris-HCl pH 8.3, with a Mono P HR column (200 x 5mm, Pharmacia). After chromatofocusing, polybuffer was removed from proteins by gel filtration with the FPLC apparatus using a spherogel TSK SW 3000 column (300 x 7.5 mm, Beckman). The purity was checked by gradient - PAGE (acrylamide 10 to 20 %) in denaturating conditions according to the method of Maize1 (8) and by IEF using a pH gradient ranging from 3 tc 10 (4). The molecular weight of the native protein was determinated by the Andrews's method (1) using the spherogel TSK column SW-3000 with the FPLC apparatus. At each step, protein concentration was measured by the method of Lowry and ~011. (7). RESULTS tangential
The
allowed the
a rapid
separation
filtrate
was
equilibrated
with fractions
cell
and the
rabbit
loop
ileal
loop
NaCl.
The
cytotoxic
(with
elution
at 0.4
both
(fig.1).
The
The pH variation
After
salt
of
elimination
chromatographied
in
separated
from small
composed
of
two
a
subunits
eluted
and with
whose
SW-3000
MW was 691
step
and
of
the
Mac
Coy
by fast
in
+ 0.2
showed
in the
and 0.32
0.95
then
M
M NaCl.
separation
of
submitted
to
enterotoxic
A was due to the buffer permitted
the elimination
at pH 5.0
enterotoxic
column. (fig.3).
estimated
the
0.13
were
2 M NaCl the
lyophilization,
of contaminants
0.55
an improvement
This
and
response
between
of toxin
Then,
in one hour
a positive
between
the elution
TSK
to
was performed
at pH 5.8
pH 8.3
in 30 min.
according
peak
spherogel
quantity
separation
A
fractions
at and
good
eluted
and polybuffer.
protein
ultrafiltration
enterotoxic
during
by protein
by
showing
eluted
culture
19-fold
allowed
NaCl
bacterial
medium
A) were
were M
The sharp
amount
assay
the
culture
fractions
the toxin
fractions
of
7.4.
The fractions
Discontinuous
of large
pH
enterotoxic
rabbit
composed
buffer
the
chromatography.
system
than
from
anion
activity.
more
Tris-HCl
ileal
chromatofocusing.
from
mM
assay
.system
of bacteria
liquid
toxins
filtration
concentrated 10
cytotcxic test
flow
by
A
(fig.2).
fraction
was
single
peak
was
The purified
toxin
was
to
20 %
PAGE in
10
Vol. 124, No. 3, 1984
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
20 1.2 E
'fi
i
1A
iii
1.2
W %
1.0 om om
a OA 0.2
Figure
I-
FRACTION
1 : Anion-exchange separation : column Mono Q HR 100x10 mm ; buffer A : 10 mM buffer B : buffer A with NaCl 1 M ; discontinuous Tris-HCl pH 7.4 ; gradient from 0 to 1 M N&l ; flow rate : 1.0 ml/min ; sample : 147 mg of retentate fraction protein ; detection at 280 nm (2 absorbance units fractions. fill scale).: enterotoxic fractions I: cytotoxic
FRACTION Figure
No
No
Nacl2Y
2 : Chromatofocusing profile : column Mono P HR 200x5 ; starting buffer : mM Tris-HCl pH 8.3, 150mMNaCl . eluent : polybuffer 74/polybuffer 98/H 0:7/3/140 (v/v/v) pH 5.0, NaCi 150 mM . flow rate : 1.0 ml/min anion-exchange step samp 1 e : 9 mg of enterotoxic fractions from the detection at 280 nm (1 absorbance unit full scale). : enterotoxil fractions
692
50 ;
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 124, No. 3, 1984
0.3
E c 0.2 0
Fd
a
----\
/
, &-+
6
10
14
16
Ve (ml)
Figure 3 : Chromatographic profile of enterotoxin on spherogel TSK SW 3000 column; buffer 150 mM NaCl, 10 mM Tris-HCl, pH 7.4 ; absorbance at 260 nm ; flow rate 1 ml/min ; sample 500 ,ug (500 ~1) of enterotoxin A obtained after chromatofocusing. Only the major peak was collected.
acrylamide
gel
IEP showed
a single
native
protein
containing
0.1
% SDS:
band with
estimated
with
Al
(41,500)
a p1 of 3.5
(fig.5).
the spherogel
TSK
and A2 (16,000) The molecular
SW-3300
(fig.4).
weight
of the
was 52,000.
column
DISCUSSION Bacterial toxin
A
of
technics
buffer
affinity and buffer
the
the
system
been
(13). and toxin
in
the
consisting
in
and anion
exchange
with
classical
scheme
chromatography used gel
step
preparative
693
anion and
procedure was proposed
electrophoresis
chromatography.
With
The
were sulfate
or precipitation
Lijnnroth
method
toxin
ammonium
filtration,
fractionation
purification
the
in
(2,3)
(11).
chromatography of
consisted
electrophoresis.
a four Another
a FPLC system
characteristics
and co11.(14)
preparative
using
purified
exchange
Taylor
A in
purified
purification
anion
chromatography. coll.(lZ)
seldom
discrepancies
double
chromatography purified
some
has
Generally,
precipitation, acetate
were
C.difficile
but
reported.
toxins
in the
in exchange
Lange
(6)
including
an
by Stephen discontinuous
FPLC system,
the
BIOCHEMICAL
Vol. 124, No. 3, 1984
AND BIOPHYSICAL RESEARCH COMMUNICATIONS A
A
B
6
C 3.5, 4.4, 4.7,
+ ._Q
2:;:
-
20.1+ cl6
0 4
05
14.4+
10.e
Ib
Figure 4 : SDS-electrophoresis in gradient ranging from 10 to 20 % of acrylamide gels according to a modified Maizel's method (8) ; A : low molecular weight B (94,000), bovine serum albumin (67,000), marker proteins : phosphorylase ovalbumin (43,01X)), carbonic anhydrase (3O,OCO), soybean trypsin inhibitor alpha-lactalbumin (14,400) ; 8 : pool of enterotoxic fractions (20,100), after ion-exchange chromatography ; C : pool of enterotoxic fractions after gel filtration. Figure 5 : Isoelectric focusing ; A : marker proteins kit : amyloglycosidase (p1 ferritin (p1 4.4), albumin bovine (p1 4.7), 13 lactoglobulin (p1 3.5), 5.3), conalbumin (p1 5.9), myoglobin horse (p1 7.3), myoglobin whale (p1 enterotcxic fraction (the cytochrome c (p1 10.6). B : purified 8.3), arrow indicates the migration of enterotoxin). Running conditions : 1,000 volthours, Pharmalyte 3 - 10 according to the instruction manual of Pharmacia Fine Chemicals (4).
anion
exchange
faster
than
chromatography classical
chromatofocusing
anion
and gel
a good recovery
of toxic
never
the
used
achieved
for with
conditions,
filtration
fixation
was unsuccessful.
was necessary
to perform for
molecular
weight
different
authors
have
of
(2,12,13).
But
toxin
in these
with
charge
the
In
of the
the
toxin. (8) Only
two, protein
bands weight
way,
and led
to was
chromatofocusing However,
These
toxins.
694
same
chromatofocusing
occured
method
molecular
was lo-fold
FPLC apparatus
NaCl-free.
toxin.
Maizel's
on C.difficile
cases,
and
but
its
of 150 mM NaCl to the
of the
either
hour
respects,
A on the column Addition
showing
one
Usually,
buffer
A with
working
been performed,
elution
ionic
toxin
faster
In other
the elution
a adequate
in
purification.
and of the
out
chromatography.
were
activities.
a pH gradient
be required
exchange
enterotoxin
starting
carried
was
in elution
buffer seemed to
Determination was
not
such with
elution
conditions
is
of the
used
by the
non-denaturating
gels
(14)
band
or a single
of these
bands
was not
BIOCHEMICAL
Vol. 124, No. 3, 1984 reported,pI
of toxin
molecular the
weight
Andrews's
conditions,
of
A was not toxin
method
(1).
corresponding
chromatography) The most
were
interesting
reliability
determined
or not
A was estimated Toxin
techniques easy-to-use characteristics
to
A showed
to a dimeric
Purification
AND BIOPHYSICAL RESEARCH COMMUNICATIONS published
550,000 52,000
configuration
reported methods of
here for these
and
the
- 600,000 molecular (Al)1
methods
according weight
to
in
our
(A2)l.
(tangential isolation
apparent
filtration, of C.difficile were
their
FPLC toxin. rapidity,
and accuracy.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
Andrews P. (1965) Biochem. J. 96, 595-606. Kobayashi T., Banno Y., Kono H., Watanabe K., Ueno K., and Nozawa Y. (1984) Rev. Infect. Dis. 6, Sll-S20. Banno Y., Kobayashi T., Watanabe K., Ueno K., and Nozawa Y. (1981) Biochemistry International 2, 629-635. Isoelectric focusing : principles and methods (1982) published by Pharmacia Fine Chemical AB, UPPSALA, Sweden. Libby J.M., Jortner B.S., and Wilkins T.D. (1982) Infect. Imun. 36, 822-829. Lijnnroth I., and Lange S. (1983) Acta Pathol. Microbial. Stand. Sect. B Microbial. Immunol. 91, 395-400. Lowry O.H., Rosebrough N.J., Farr A.L., and Randall R.J. (1951) J. Biol. Chem. 193, 265-275. Maize1 Jr. J.V. (1970) Nature 227, 680-686. Pierce N.F., and Wallace C.K. (1972) Gastroenterology 63, 439-448. Rolfe R.D., and Finegold S.M. (1979) Infect. Inmun. 25, 191-201. Rijnnberg B., Wadstrijm T. (in press) Prep. Biochem. Stephen J., Redmond S.C., Mitchell T.J., Ketley J., Candy D.C.A., Burdon D.W., and Daniel R. (1984) Biochem. Sot. Trans. 12, 194-195. Sullivan N.M., Pellett S., and Wilkins T.D. (1982) Infect. Imnun. 35, 1032-1046. Taylor N.S., Thorne G.M., and Bartlett J.G. (1981) Infect. Imnun. 34, 1036-1043. Tytgat F. (1980) Ann. Microbial. (Paris) 131 B, 11-20.
695
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS Pages
November 14, 1984
A NEW PURIFICATION Rihn
B.,
PROCEDURE FOR CLOSTRIDIUM DIFFICILE Scheftel
J.M.,
Girardot
R.,
690-695
ENTEROTOXIN
and Monteil
H.
Institut
de Bact&iologie de la Faculte de MBdecine - Universite 3, rue Koeberl6 - 67000 STRASBOURG - FRANCE
Received
September
cytotoxin. filtration, composed
Clostridium difficile produces two toxins, an enterotoxin and a The enterotoxin was purified using fast methods (tangential flow The purified enterotoxin is fast protein liquid chromatography). of two subunits (A1 = 41,500, A2 = 16,000) and its p1 is 3.5. 0 1984
Academic
Press,
17,
Pasteur
1984
Inc.
C.difficile pseudomembranous pathogeny
Louis
is
the This
colitis.
of APC : an enterotoxin The cytotoxin
toxin
has the property
toxin
named enterotoxin
ileal
loop
assay
or toxin of rounding or
toxin
and experimental
we report
a rapid
method
MATERIALS
AND METHODS
for
agent
causative organism
produces
of
antibiotic-associated
two toxins
implicated
in the
and a cytotoxin. B has been purified
by several
different
cells
in culture
A induces
fluid
accumulation
ileocecitis
the purification
in hamster
groups (10,15). in
(5,13).
of C.difficile
toxin
:
this
Another the
In this
rabbit work
A.
Bacterial strain, culture conditions and toxin concentration : C.difficile (strain 79685 was isolated in our laboratory from stool of a patient with pseudomembranous colitis). This strain was grown in an anaerobic Chamber (CO2 containing brain10 %, H 5 %, N 85 %) for 60 hours in three 5 liter-flasks heart br&h (In&itut Pasteur Production) at 37OC under stirring. The culture was then filtered using a sangential flow system in a microporoys filter HVLP (0,5 p; filter area : 5 ft ; recirculation rate : 100 ml/min/ft ; pressure : 10 psi; Millipore). Sixteen liters of filtrate (corresponding to 111 g of proteins) were ultrafiltered with the same system using a PTGC filter with a nominal molecular weight limit of 10,000 (Millipore). During this step the retentate (1,050 ml; 15.5 g of proteins) was equilibrated in 10 mM Tris-HCl buffer pH 7.4. Enterotoxic methods :
and cytotoxic assays : Toxic activities fluid accumulation in the isolated rabbit
were ileal
determined by two loop according to
Abbreviations: APC, antibiotic-associated pseudomembranous colitis; tridium; FPLC fast protein liquid chromatography; IEF, isoelectric MW, molecular weight; PAGE, polyacrylamid gel electrophoresis. 0006-291X/84 Copyright All rights
$1.50
0 I984 by Acudemic Press, Inc. of reproduction in any form reserved.
C, Closfocusing;
BIOCHEMICAL
Vol. 124, No. 3, 1984
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the Pierce and Wallace method (9), cytopathic rounding of Mac Coy Cells (15). The rabbit method for enterotoxin detection.
effect consisting ileal loop assay
of complete a specific
is
Chromatography methods : A fast protein liquid chromatography (Pharmacia) a GP-250 gradient apparatus, was used. It was composed of two P-500 pumps, a FRAC-100 fraction collector and a programmer, two UV-1 and UV-2 monitors, REG482 recorder. Anion exchange chromatography was performed on a Mono Q column (100 x 10 mm, Pharmacia). In each run, 150 mg of protein from the retentate fraction were applied. Fractions containing the enterotoxic activity obtained after Mono Q run, were desalted on Pharmacia PD-10 column and lyophilized. The proteins were equilibrated with the starting buffer (50 NaCl 150 mM) used for chromatofocusing which was achieved mM Tris-HCl pH 8.3, with a Mono P HR column (200 x 5mm, Pharmacia). After chromatofocusing, polybuffer was removed from proteins by gel filtration with the FPLC apparatus using a spherogel TSK SW 3000 column (300 x 7.5 mm, Beckman). The purity was checked by gradient - PAGE (acrylamide 10 to 20 %) in denaturating conditions according to the method of Maize1 (8) and by IEF using a pH gradient ranging from 3 tc 10 (4). The molecular weight of the native protein was determinated by the Andrews's method (1) using the spherogel TSK column SW-3000 with the FPLC apparatus. At each step, protein concentration was measured by the method of Lowry and ~011. (7). RESULTS tangential
The
allowed the
a rapid
separation
filtrate
was
equilibrated
with fractions
cell
and the
rabbit
loop
ileal
loop
NaCl.
The
cytotoxic
(with
elution
at 0.4
both
(fig.1).
The
The pH variation
After
salt
of
elimination
chromatographied
in
separated
from small
composed
of
two
a
subunits
eluted
and with
whose
SW-3000
MW was 691
step
and
of
the
Mac
Coy
by fast
in
+ 0.2
showed
in the
and 0.32
0.95
then
M
M NaCl.
separation
of
submitted
to
enterotoxic
A was due to the buffer permitted
the elimination
at pH 5.0
enterotoxic
column. (fig.3).
estimated
the
0.13
were
2 M NaCl the
lyophilization,
of contaminants
0.55
an improvement
This
and
response
between
of toxin
Then,
in one hour
a positive
between
the elution
TSK
to
was performed
at pH 5.8
pH 8.3
in 30 min.
according
peak
spherogel
quantity
separation
A
fractions
at and
good
eluted
and polybuffer.
protein
ultrafiltration
enterotoxic
during
by protein
by
showing
eluted
culture
19-fold
allowed
NaCl
bacterial
medium
A) were
were M
The sharp
amount
assay
the
culture
fractions
the toxin
fractions
of
7.4.
The fractions
Discontinuous
of large
pH
enterotoxic
rabbit
composed
buffer
the
chromatography.
system
than
from
anion
activity.
more
Tris-HCl
ileal
chromatofocusing.
from
mM
assay
.system
of bacteria
liquid
toxins
filtration
concentrated 10
cytotcxic test
flow
by
A
(fig.2).
fraction
was
single
peak
was
The purified
toxin
was
to
20 %
PAGE in
10
Vol. 124, No. 3, 1984
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
20 1.2 E
'fi
i
1A
iii
1.2
W %
1.0 om om
a OA 0.2
Figure
I-
FRACTION
1 : Anion-exchange separation : column Mono Q HR 100x10 mm ; buffer A : 10 mM buffer B : buffer A with NaCl 1 M ; discontinuous Tris-HCl pH 7.4 ; gradient from 0 to 1 M N&l ; flow rate : 1.0 ml/min ; sample : 147 mg of retentate fraction protein ; detection at 280 nm (2 absorbance units fractions. fill scale).: enterotoxic fractions I: cytotoxic
FRACTION Figure
No
No
Nacl2Y
2 : Chromatofocusing profile : column Mono P HR 200x5 ; starting buffer : mM Tris-HCl pH 8.3, 150mMNaCl . eluent : polybuffer 74/polybuffer 98/H 0:7/3/140 (v/v/v) pH 5.0, NaCi 150 mM . flow rate : 1.0 ml/min anion-exchange step samp 1 e : 9 mg of enterotoxic fractions from the detection at 280 nm (1 absorbance unit full scale). : enterotoxil fractions
692
50 ;
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 124, No. 3, 1984
0.3
E c 0.2 0
Fd
a
----\
/
, &-+
6
10
14
16
Ve (ml)
Figure 3 : Chromatographic profile of enterotoxin on spherogel TSK SW 3000 column; buffer 150 mM NaCl, 10 mM Tris-HCl, pH 7.4 ; absorbance at 260 nm ; flow rate 1 ml/min ; sample 500 ,ug (500 ~1) of enterotoxin A obtained after chromatofocusing. Only the major peak was collected.
acrylamide
gel
IEP showed
a single
native
protein
containing
0.1
% SDS:
band with
estimated
with
Al
(41,500)
a p1 of 3.5
(fig.5).
the spherogel
TSK
and A2 (16,000) The molecular
SW-3300
(fig.4).
weight
of the
was 52,000.
column
DISCUSSION Bacterial toxin
A
of
technics
buffer
affinity and buffer
the
the
system
been
(13). and toxin
in
the
consisting
in
and anion
exchange
with
classical
scheme
chromatography used gel
step
preparative
693
anion and
procedure was proposed
electrophoresis
chromatography.
With
The
were sulfate
or precipitation
Lijnnroth
method
toxin
ammonium
filtration,
fractionation
purification
the
in
(2,3)
(11).
chromatography of
consisted
electrophoresis.
a four Another
a FPLC system
characteristics
and co11.(14)
preparative
using
purified
exchange
Taylor
A in
purified
purification
anion
chromatography. coll.(lZ)
seldom
discrepancies
double
chromatography purified
some
has
Generally,
precipitation, acetate
were
C.difficile
but
reported.
toxins
in the
in exchange
Lange
(6)
including
an
by Stephen discontinuous
FPLC system,
the
BIOCHEMICAL
Vol. 124, No. 3, 1984
AND BIOPHYSICAL RESEARCH COMMUNICATIONS A
A
B
6
C 3.5, 4.4, 4.7,
+ ._Q
2:;:
-
20.1+ cl6
0 4
05
14.4+
10.e
Ib
Figure 4 : SDS-electrophoresis in gradient ranging from 10 to 20 % of acrylamide gels according to a modified Maizel's method (8) ; A : low molecular weight B (94,000), bovine serum albumin (67,000), marker proteins : phosphorylase ovalbumin (43,01X)), carbonic anhydrase (3O,OCO), soybean trypsin inhibitor alpha-lactalbumin (14,400) ; 8 : pool of enterotoxic fractions (20,100), after ion-exchange chromatography ; C : pool of enterotoxic fractions after gel filtration. Figure 5 : Isoelectric focusing ; A : marker proteins kit : amyloglycosidase (p1 ferritin (p1 4.4), albumin bovine (p1 4.7), 13 lactoglobulin (p1 3.5), 5.3), conalbumin (p1 5.9), myoglobin horse (p1 7.3), myoglobin whale (p1 enterotcxic fraction (the cytochrome c (p1 10.6). B : purified 8.3), arrow indicates the migration of enterotoxin). Running conditions : 1,000 volthours, Pharmalyte 3 - 10 according to the instruction manual of Pharmacia Fine Chemicals (4).
anion
exchange
faster
than
chromatography classical
chromatofocusing
anion
and gel
a good recovery
of toxic
never
the
used
achieved
for with
conditions,
filtration
fixation
was unsuccessful.
was necessary
to perform for
molecular
weight
different
authors
have
of
(2,12,13).
But
toxin
in these
with
charge
the
In
of the
the
toxin. (8) Only
two, protein
bands weight
way,
and led
to was
chromatofocusing However,
These
toxins.
694
same
chromatofocusing
occured
method
molecular
was lo-fold
FPLC apparatus
NaCl-free.
toxin.
Maizel's
on C.difficile
cases,
and
but
its
of 150 mM NaCl to the
of the
either
hour
respects,
A on the column Addition
showing
one
Usually,
buffer
A with
working
been performed,
elution
ionic
toxin
faster
In other
the elution
a adequate
in
purification.
and of the
out
chromatography.
were
activities.
a pH gradient
be required
exchange
enterotoxin
starting
carried
was
in elution
buffer seemed to
Determination was
not
such with
elution
conditions
is
of the
used
by the
non-denaturating
gels
(14)
band
or a single
of these
bands
was not
BIOCHEMICAL
Vol. 124, No. 3, 1984 reported,pI
of toxin
molecular the
weight
Andrews's
conditions,
of
A was not toxin
method
(1).
corresponding
chromatography) The most
were
interesting
reliability
determined
or not
A was estimated Toxin
techniques easy-to-use characteristics
to
A showed
to a dimeric
Purification
AND BIOPHYSICAL RESEARCH COMMUNICATIONS published
550,000 52,000
configuration
reported methods of
here for these
and
the
- 600,000 molecular (Al)1
methods
according weight
to
in
our
(A2)l.
(tangential isolation
apparent
filtration, of C.difficile were
their
FPLC toxin. rapidity,
and accuracy.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
Andrews P. (1965) Biochem. J. 96, 595-606. Kobayashi T., Banno Y., Kono H., Watanabe K., Ueno K., and Nozawa Y. (1984) Rev. Infect. Dis. 6, Sll-S20. Banno Y., Kobayashi T., Watanabe K., Ueno K., and Nozawa Y. (1981) Biochemistry International 2, 629-635. Isoelectric focusing : principles and methods (1982) published by Pharmacia Fine Chemical AB, UPPSALA, Sweden. Libby J.M., Jortner B.S., and Wilkins T.D. (1982) Infect. Imun. 36, 822-829. Lijnnroth I., and Lange S. (1983) Acta Pathol. Microbial. Stand. Sect. B Microbial. Immunol. 91, 395-400. Lowry O.H., Rosebrough N.J., Farr A.L., and Randall R.J. (1951) J. Biol. Chem. 193, 265-275. Maize1 Jr. J.V. (1970) Nature 227, 680-686. Pierce N.F., and Wallace C.K. (1972) Gastroenterology 63, 439-448. Rolfe R.D., and Finegold S.M. (1979) Infect. Inmun. 25, 191-201. Rijnnberg B., Wadstrijm T. (in press) Prep. Biochem. Stephen J., Redmond S.C., Mitchell T.J., Ketley J., Candy D.C.A., Burdon D.W., and Daniel R. (1984) Biochem. Sot. Trans. 12, 194-195. Sullivan N.M., Pellett S., and Wilkins T.D. (1982) Infect. Imnun. 35, 1032-1046. Taylor N.S., Thorne G.M., and Bartlett J.G. (1981) Infect. Imnun. 34, 1036-1043. Tytgat F. (1980) Ann. Microbial. (Paris) 131 B, 11-20.
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