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AIR-Reoxidation of reduced, denatured chymotrypsinogen A covalently attached to a solid matrix
Vol. 48, No. 5, 1972
BIOCHEMICAL
AIR-REOXIDATION
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
OF REDUCED, DENATURED CRYMOTRYPSINOGEN A
COVALENTLY ATTACHED TO A SOLID MATRIX' John C. Brown,
North Received
Harold
E. Swaisgood,
and H. Robert
Departments of Biochemistry Carolina State University,
July
Horton
and Food Science Raleigh, N. C. 27607
14,1972
SUMMARY: Bovine chymotrypsinogen A was covalently attached to porous succinylglass beads via the zymogen's amino groups. The bound zymogen was completely reduced in 8 M urea, then allowed to reoxidize, and activated to chymotrypsin. Comparison of the ko (catalytic coefficient) of this preparation with that of a similar preparation which had never been exposed to reductant showed a 53 % recovery of esterolytic activity towards N-benzoyl-L-tyrosine ethyl ester. Values of Km and k, for non-reduced, matrix-bound zymogen, following its activation to chymotrypsin, were 12.8 x 10-5 M and 11.0 sec'l, respectively. Corresponding values for reduced, air-reoxidized preparations were 6.8 x 10m5 M and 3.1 set-l. Attempts state
to reoxidize
following
the zymogen bility
the
chymotrypsinogen
complete
have met with
of the reduced
esterolytic
activity
was only
1.4 % (2).
as to whether
the
structure
in zymogens
(such
sequence,
it
of the thus
through ovalbumin),
achievement
five
array
bonds
to the
acids
to circumvent
determined
the
tertiary by the
comprising problems
addition
investigate
functional
is
(1,2).
of potential
to further
of biologically
in
insolu-
of pH and the
the maximum recovery In order
present
relative
to air-oxidation
manipulation
of amino
became necessary
functional
disulfide
amenable
as chymotrypsinogen)
linear
biologically
due in part
conditions
(e.g.,
question
thermodynamics
under
was attained
separators
of the
success,
protein
Even when solubility of molecular
reduction little
A to its
inherent
the primary of aggregation
and
insolubility. Recently, muscle
lactate
Cho and Swaisgood dehydrogenase,
exposure
to 7 M guanidinium
nificant
recoveries
(3)
demonstrated
covalently
bound
chloride.
of enzymatic
Epstein
activity
the
reactivation
to porous and Anfinsen
glass (1)
of rabbit beads,
sig-
when carboxymethylcellulose-bound
trypsin was subjected to reduction and air-reoxidation. cu-Chymotrypsin found to be highly active after immobilization by attachment to porous beads
following
observed
was glass
(4).
lThis investigation has been supported in Research Grant GB-78949, and in part by medical Sciences Support Grant RR 07071, Schools of Agriculture and Life Sciences ences. Paper3820 of the Journal Series Agricultural Experiment Station, Raleigh, Copyright 0 1972 by Academic Press, Inc. AN rights of reproduction in any form reserved.
1068
part by National Science Foundation National Institutes of Health Bioand is a contribution from the and Physical and Mathematical Sciof the N. C. State University N. C.
Vol. 48, No. 5, 1972
In view
of these
chymotrypsinogen covalent
BIOCHEMICAL
findings,
which
attachment
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
we sought
had undergone
to porous
reductive
glass
chased
from
Bovine Pentex
ton Biochemical Gdn.HCl
Pierce
Chemical
Porous
alkylaminosilane-glass
obtained
from Corning
Preparation H20,
4.5, for
Coleman
and degassed.
of the
The solution
of the remaining
beads,
corresponding
pH 7.0,
After
for
and then
H20.
Effluent
distilled
522 a pore
from
grade J. T. Baker
diameter)
recycling,
was essentiallv with
were
that
After
of solid
with
disat pH recycling
to 0.2 M in EDC by for
5 hr.
To activate
the
EDC were
were
acid
continuous
washed
A quantity succinyl
made to the
30 min of recycling
the beads
of Cho
1 M NaCl and then
was continued
13.5 mg of CTGn was added
treated
experiments.
with
Company;
from ethanol.
control.
two additions
24 hr at O".
1 M NaCl-0.08
eluted
from Worthing-
after
with
each
0.1 M sodium
at 0 O.
with
Analyzer.
urea
was increased
for
to 0.1 M),
final
to all
Amino Acid -Acid
the
washing,
was recycled
grade
reagent.
solution
and recycling
phosphate,
prior
the
removed
After
trypsin
Sigma Chemical
was made 0.5 M in succinic
reagent,
(each
was pur-
EDC and sequanal
mesh,
of solid
was then
addition,
washed
(40-60
solid
solution
buffer
and Bell;
beads
of succinylated
its
Works.
12 hr at room temperature,
groups
bovine
by recrystallization
beads Glass
of
crystallized,
from
and reagent
purified
and 0.1 M in EDC by addition
addition
times
of SG-CTGn Beads. The procedure --(3). A column of beads was washed
and Swaisgood tilled
A, six
Company;
and further
Company,
following
BTEE* was obtained
from Matheson,
from
Chemical
denaturation
twice-crystallized
Corporation.
B-mercaptoethanol
air-reoxidation
AND METHODS
chymotrypsinogen
Corporation;
the
beads.
MATERIALS Materials.
to examine
with
Analysis.
The control CTGn.
SG-CTGn beads, was collected
reaction, buffer,
were
were
performed
followed
in dialysis to a Pyrex
pH 7.8.
tubing,
washed
types
solution in phosphate
of beads
Beads were
on a Beckman Model 0.284
by several
vial,
and the
also
both
1.2 ml representing
10 ml of 6 M Gdn-HCl, H20, transferred
After
M Tris-chloride
Analyses
to the beads,
beads
washings
dialyzed
and taken
g dry weight, with
116 Amino were against
The beads
*The abbreviations used are: BTEE, N-benzoyl-L-tyrosine ethyl ester; DTNB, 5,5'-dithio-bis(2-nitro1-ethyl-3-(dimethylaminopropyl)-carbodiimide; benzoic acid); BME, @-mercaptoethanol; GdneHCl, guanidinium chloride; bovine chymotrypsinogen A; SG-CTGn, succinyl-glass-chymotrypsinogen; succinyl-glass-chymotrypsin; and TNB, thiolnitrobenzoate.
1069
degassed
distilled
exhaustively
to dryness.
were
EDC, CTGn, SG-CHT,
Vol. 48, No. 5, 1972
were
dried
BIOCHEMICAL
and weighed,
in evacuated
vials
and both
placed
content
of each was calculated present
unless
beads
otherwise
to determine
observed
interbead
volume
(V,)
culation
hydrolyzed
for
of average not
occupied
in
24 hr.
of Asp,
to Gdn.HCl
identically
by a column
6 N HCl
The protein
recoveries
exposed
(Vm) of a weighed
of 2.18
pore
g/cc
(6).
(VP).
were
Gly, also
each time,
of wet beads
quantity
was used
Total
of dry beads
volume
(Vt)
Vt - Vm = V, + VP
by transferring
and measuring
the beads
the volume
= V,,
to a syringe thereby
occupied,
=
Vm +
the void
filled
permitting
with the
cal-
of V,.
Activation
of SG-CTGn to SG-CHT. A solution of trypsin in 0.08 M Tris-Cl---pH 7.8, was recycled through the beads for 2 hr at room temperature.
0.1 M CaC12,
Denaturation, denaturation However, dure
+
Vt was determined
H20, degassing,
bath
to pack almost
the volume
volume
space
were
dry weight.
Void Volume. The matrix -was determined using a density volume.
toluene
SG-CTGn beads
were
stated,
their
and beads
on the basis
in CTGn (5).
Since
effluent
in a refluxing
and Ala analyzed.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Reduction,
and Reoxidation. was essentially that
in 8 M urea sulfhydryl
(7),
groups
in that
the
TNB anion
10 % BME in 0.5 M sodium Reoxidation beads
for
Assay.
was pumped through
was monitored
and Anfinsen
(1).
of Ellman's
glass-bound
phosphate
reductive
protein
buffer,
0.05 M Tris-Cl,
procewith
pH 7.5.
pH 8.6,
through
the
Cp is
columns
at 3 ml/min,
activated
activated, and the
of the Michaelis-Menten
=
the
- f)
Km.ln(l
concentration;
to product; E,,
similarly
equation
enzyme was utilized
the product
enzyme;
0.1 ml of SG-CTGn beads,
were
to SG-CHT, used.
absorbance
BTEE
of the
at 256 nm (8). form
of surface-bound
been converted of the
from the
sodium
SG-CTGn beads,
cP where
was eluted by recycling
For assay, the bead
The integrated a column
of Epstein
by a modification
acetate-O.OlM
was effected
ml or reoxidized
effluent
titrated
for
24 hr at room temperature.
Kinetic and 0.35
were
The procedure
k,, total
f,
the
overall
enzyme
in evaluating
for
the kinetics
of
the data:
+ k,E,V,/Q the
fraction
of substrate
rate
constant
concentration;
V,,
Q, the
(catalytic the void
which
has
COeffiCieIIt)
volume;
and
flow rate. This equation differs slightly in that we have used the void volume rather than
from that of Lilly --et al. the total column volume in
determining
analyzed
least
enzyme concentration.
The data
squares.
1070
were
by the method
of
(9)
Vol. 48, No. 5, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE I Characteristics
of Non-Reduced Activated
and Reduced-Reoxidized to SG-CHT
Total Volume (ml>
Dry Weight 63)
Native
0.10
0.028
0.086
3.26
Reoxidized
0.35
0.093
0.301
1.16
Matrix-bound Enzyme
V~~~~,
SH Content (Reduced) (moles/mole)
K, CM)
x 1O-3
-
12.8 x 1O-5
11.0
x 10-2
11
6.8 x 10-5
3.1
Protein (mg)
(ml)
SG-CTGn
ko (set- 1)
RESULTS Table "native"
I gives
the characteristics
referring
not been
reduced,
8 M urea
and allowed
and "reoxidized"
0.14 mg protein/g mately tion
the
old
its
dry beads.
same value;
Analysis
hence,
there
to that
protein
appeared
beads,
even without
exposure
Accordingly,
these
to GdnsHCl, stored
eluate
the beads as amino
acid
were
approxi50 % adsorp-
stored
in cold
analysis of 0.14
used
for
in
revealed
yielded
were
gave a value
preparations
had
had been reduced
of the beads
to have been at least if
was released,
dry beads.
SG-CHT) which
which
analysis
of the Gdn-HCl
However,
of SG-CTGn columns,
product,
Amino acid
to the beads.
H20, adsorbed
activation
referring
to reoxidize.
of the zymogen
distilled
of the two types
to SG-CTGn (and
of 30-day mg protein/g
enzymatic
studies. Non-reduced 10-4 M and a
of 11.0 . . upon activation,
SG-CTGn, tively
SG-CTGn, k,
(Table
I).
of esterolytic following data
fitted
tude
of errors
changes if
the
to the
integrated
encountered
in flow flow
to enzyme.
rate
rate
rate
substrate
can result
is < 1 ml/min,
inhibition,
same value of Cp as did 0.27 u&i. Control SG-CHT beads exhibited ranging
from
ko/Km
yielded
of 3 mljmin, x lOa
indicates
by air-reoxidation Figure equation,
in sizeable
a l$.,, of whereas
1.28 x
reoxidized
M and 3.1 set-l,
ratios
It
reduced
a typical
and serves
error.
zymogen,
plot
to indicate
was found
experimental
respec-
a 53 % recovery
of the
1 presents
in such measurements.
the data plot in an almost vertical more than 25-30 % of the substrate exhibited
rate
of 6.79
of the
is achieved
activation
to SG-CHT,
at a flow
g ave values
Comparison
activity its
upon activation set"
of the the magni-
that
slight
In our
system,
too much of the substrate is hydrolyzed so that Best results are obtained when not line. has been hydrolyzed. in that
a concentration
no esterolytic
0.5 to 3 ml/min.
1071
The preparations of 0.54 mM produced
activity
at flow
rates
also the
Vol. 48, No. 5, 1972
BIOCHEMICAL
-32 -26-24
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
-20 -16 -12 -6 In(l-f
ln(l - f) vs. and Reoxidized
Fig. 1. A Plot of Cp SG-CHT (open circles),circles).
-4
)x 102
for Non-Reduced SG-CTGn Activated to SG-CTGn Activated to SG-CRT (filled
DISCUSSION To the authors' zymogen with exist tion
that,
could
of chymotrypsin
not
with
Adsorption
be anticipated
faces
can be a problem, storage
released
and Swaisgood all
that
(unpublished
The regeneration following
reductive
significant structure reduced
breakthrough chymotrypsinogen potential
from
which have
during
acid
functional
that
A in solution
action
to form SG-CTGn to glass
solutions.
surHowever,
zymogen was effectively
analysis
of a 30-day-old with
Gdn*HCl
Gdn.HCl.
Cho
effectively
beads. three-dimensional
structure
chymotrypsinogen
represents
in our understanding of the The air-reoxidation
proteins. enzymatic
reaction
had been washed
of matrix-bound
of the matrixof CTGn prior
and binding
demonstrated
activa-
of rr-chymotrypsin.
H20, adsorbed
succinyl-glass
of biologically
in multi-chain
1.4 % of the
in cold
most
innxobilization
of a did
zymogen,
the autocatalytic
protein,
of the amino
denaturation
that
in the case of dilute
data)
protein
indicate
beads
immobilization The possibility bound
a good source
CTGn is a basic
particularly
of an aliquot
adsorbed
covalently
in solution,
to the glass
of the SG-CTGn beads with
reported form.
By minimizing
may provide
as shown by comparison
preparation removes
since
first
The results
generated trypsin
the of the
to trypsin.
of zymogen
could upon
occur.
molecules
activation
is
to the enzyme
arrangement
CTGn was accessible
to its
this
activation
due to spatial
by trypsin
bound
knowledge,
subsequent
achievement of tertiary of denatured, fully
had resulted in a maximum recovery of In the present study, 53 % of activity (2).
1072
a
Vol. 48, No. 5, 1972
the
zymogen's
potential
immobilization function reduced
BIOCHEMICAL
esterolytic
of the
appears
activity
polypeptide
of intermolecular
which
bonds.
suggesting
ment of functional tions
of residues
an even wider eration the
apparent
proteins
the the
of proteins
primary
sequences
previously
in artificially
applicability
of the recent A (11)
zymogens
exemplified
of enzymatic among the
of growing bonds
shown.
formation in the polypep-
earlier
and the achieveinterac-
may now be extended Moreover,
immobilized somewhat
Thus,
thermodynamic
(10)
successful
to the
and the
complexes. upon the
of
in recovery
may be achieved
of disulfide depend
such as ribonuclease
of proteolytic
effect
conditions
of interactions
to aggregation
polysomal
location
than
conformations
under
of the attachment
structures
comprising
array
of active
that
tertiary
lead
A similar
of proteins by virtue --in vivo synthesis tide chains to ribosomes in the active observations
The increase
due to the avoidance
molecules
disulfide
was recovered
chains.
to be primarily
chymotrypsinogen
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
solid-phase
to
such regen-
proteins
extends
synthesis
more complicated
of
class
by chymotrypsinogen. REFERENCES
1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11.
Epstein, C. J., and Anfinsen, C. B ., 2. Biol. Chem. 237, 2175 (1962). Brown, J. C., and Horton, H. R., --Proc. Sot. &. Med. 141, in press --Biol. (1972). Biophys. Acta 258, 675 (1972). Cho, I. C., and Swaisgood, H. E., Biochim. Robinson, P. J., Dunnill, P., and Lilly, M. D., Biochim. Biophys. Acta 242, 659 (1971). Blow, D. M., Birktoft, J. J., and Hartley, B. S., Nature 221, 337 (1969). "Properties of Selected Commercial Glasses," Form B-83, Corning Glass Works, Corning, New York. Copyright 1949. Ellman, G. L., a. Biochem. Biophys. 82, 70 (1959). Hummel, B. C. W., Canad. 2. Biochem. Physiol. 37, 1393 (1959). Lilly, M. D., Horn=. E., and Crook, E. M., Biochem. 1. 100, 718 (1966). Epstein, C. J., Goldberger, R. F., and Anfinsen, C. B., Cold Spring Harbor m. Quant. Biol. _28, 439 (1963). Gutte, B., and- Merrifield, R. B., 2. --Amer. Chem. Sot. 9l, 501 (1969).
1073
BIOCHEMICAL
AIR-REOXIDATION
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
OF REDUCED, DENATURED CRYMOTRYPSINOGEN A
COVALENTLY ATTACHED TO A SOLID MATRIX' John C. Brown,
North Received
Harold
E. Swaisgood,
and H. Robert
Departments of Biochemistry Carolina State University,
July
Horton
and Food Science Raleigh, N. C. 27607
14,1972
SUMMARY: Bovine chymotrypsinogen A was covalently attached to porous succinylglass beads via the zymogen's amino groups. The bound zymogen was completely reduced in 8 M urea, then allowed to reoxidize, and activated to chymotrypsin. Comparison of the ko (catalytic coefficient) of this preparation with that of a similar preparation which had never been exposed to reductant showed a 53 % recovery of esterolytic activity towards N-benzoyl-L-tyrosine ethyl ester. Values of Km and k, for non-reduced, matrix-bound zymogen, following its activation to chymotrypsin, were 12.8 x 10-5 M and 11.0 sec'l, respectively. Corresponding values for reduced, air-reoxidized preparations were 6.8 x 10m5 M and 3.1 set-l. Attempts state
to reoxidize
following
the zymogen bility
the
chymotrypsinogen
complete
have met with
of the reduced
esterolytic
activity
was only
1.4 % (2).
as to whether
the
structure
in zymogens
(such
sequence,
it
of the thus
through ovalbumin),
achievement
five
array
bonds
to the
acids
to circumvent
determined
the
tertiary by the
comprising problems
addition
investigate
functional
is
(1,2).
of potential
to further
of biologically
in
insolu-
of pH and the
the maximum recovery In order
present
relative
to air-oxidation
manipulation
of amino
became necessary
functional
disulfide
amenable
as chymotrypsinogen)
linear
biologically
due in part
conditions
(e.g.,
question
thermodynamics
under
was attained
separators
of the
success,
protein
Even when solubility of molecular
reduction little
A to its
inherent
the primary of aggregation
and
insolubility. Recently, muscle
lactate
Cho and Swaisgood dehydrogenase,
exposure
to 7 M guanidinium
nificant
recoveries
(3)
demonstrated
covalently
bound
chloride.
of enzymatic
Epstein
activity
the
reactivation
to porous and Anfinsen
glass (1)
of rabbit beads,
sig-
when carboxymethylcellulose-bound
trypsin was subjected to reduction and air-reoxidation. cu-Chymotrypsin found to be highly active after immobilization by attachment to porous beads
following
observed
was glass
(4).
lThis investigation has been supported in Research Grant GB-78949, and in part by medical Sciences Support Grant RR 07071, Schools of Agriculture and Life Sciences ences. Paper3820 of the Journal Series Agricultural Experiment Station, Raleigh, Copyright 0 1972 by Academic Press, Inc. AN rights of reproduction in any form reserved.
1068
part by National Science Foundation National Institutes of Health Bioand is a contribution from the and Physical and Mathematical Sciof the N. C. State University N. C.
Vol. 48, No. 5, 1972
In view
of these
chymotrypsinogen covalent
BIOCHEMICAL
findings,
which
attachment
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
we sought
had undergone
to porous
reductive
glass
chased
from
Bovine Pentex
ton Biochemical Gdn.HCl
Pierce
Chemical
Porous
alkylaminosilane-glass
obtained
from Corning
Preparation H20,
4.5, for
Coleman
and degassed.
of the
The solution
of the remaining
beads,
corresponding
pH 7.0,
After
for
and then
H20.
Effluent
distilled
522 a pore
from
grade J. T. Baker
diameter)
recycling,
was essentiallv with
were
that
After
of solid
with
disat pH recycling
to 0.2 M in EDC by for
5 hr.
To activate
the
EDC were
were
acid
continuous
washed
A quantity succinyl
made to the
30 min of recycling
the beads
of Cho
1 M NaCl and then
was continued
13.5 mg of CTGn was added
treated
experiments.
with
Company;
from ethanol.
control.
two additions
24 hr at O".
1 M NaCl-0.08
eluted
from Worthing-
after
with
each
0.1 M sodium
at 0 O.
with
Analyzer.
urea
was increased
for
to 0.1 M),
final
to all
Amino Acid -Acid
the
washing,
was recycled
grade
reagent.
solution
and recycling
phosphate,
prior
the
removed
After
trypsin
Sigma Chemical
was made 0.5 M in succinic
reagent,
(each
was pur-
EDC and sequanal
mesh,
of solid
was then
addition,
washed
(40-60
solid
solution
buffer
and Bell;
beads
of succinylated
its
Works.
12 hr at room temperature,
groups
bovine
by recrystallization
beads Glass
of
crystallized,
from
and reagent
purified
and 0.1 M in EDC by addition
addition
times
of SG-CTGn Beads. The procedure --(3). A column of beads was washed
and Swaisgood tilled
A, six
Company;
and further
Company,
following
BTEE* was obtained
from Matheson,
from
Chemical
denaturation
twice-crystallized
Corporation.
B-mercaptoethanol
air-reoxidation
AND METHODS
chymotrypsinogen
Corporation;
the
beads.
MATERIALS Materials.
to examine
with
Analysis.
The control CTGn.
SG-CTGn beads, was collected
reaction, buffer,
were
were
performed
followed
in dialysis to a Pyrex
pH 7.8.
tubing,
washed
types
solution in phosphate
of beads
Beads were
on a Beckman Model 0.284
by several
vial,
and the
also
both
1.2 ml representing
10 ml of 6 M Gdn-HCl, H20, transferred
After
M Tris-chloride
Analyses
to the beads,
beads
washings
dialyzed
and taken
g dry weight, with
116 Amino were against
The beads
*The abbreviations used are: BTEE, N-benzoyl-L-tyrosine ethyl ester; DTNB, 5,5'-dithio-bis(2-nitro1-ethyl-3-(dimethylaminopropyl)-carbodiimide; benzoic acid); BME, @-mercaptoethanol; GdneHCl, guanidinium chloride; bovine chymotrypsinogen A; SG-CTGn, succinyl-glass-chymotrypsinogen; succinyl-glass-chymotrypsin; and TNB, thiolnitrobenzoate.
1069
degassed
distilled
exhaustively
to dryness.
were
EDC, CTGn, SG-CHT,
Vol. 48, No. 5, 1972
were
dried
BIOCHEMICAL
and weighed,
in evacuated
vials
and both
placed
content
of each was calculated present
unless
beads
otherwise
to determine
observed
interbead
volume
(V,)
culation
hydrolyzed
for
of average not
occupied
in
24 hr.
of Asp,
to Gdn.HCl
identically
by a column
6 N HCl
The protein
recoveries
exposed
(Vm) of a weighed
of 2.18
pore
g/cc
(6).
(VP).
were
Gly, also
each time,
of wet beads
quantity
was used
Total
of dry beads
volume
(Vt)
Vt - Vm = V, + VP
by transferring
and measuring
the beads
the volume
= V,,
to a syringe thereby
occupied,
=
Vm +
the void
filled
permitting
with the
cal-
of V,.
Activation
of SG-CTGn to SG-CHT. A solution of trypsin in 0.08 M Tris-Cl---pH 7.8, was recycled through the beads for 2 hr at room temperature.
0.1 M CaC12,
Denaturation, denaturation However, dure
+
Vt was determined
H20, degassing,
bath
to pack almost
the volume
volume
space
were
dry weight.
Void Volume. The matrix -was determined using a density volume.
toluene
SG-CTGn beads
were
stated,
their
and beads
on the basis
in CTGn (5).
Since
effluent
in a refluxing
and Ala analyzed.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Reduction,
and Reoxidation. was essentially that
in 8 M urea sulfhydryl
(7),
groups
in that
the
TNB anion
10 % BME in 0.5 M sodium Reoxidation beads
for
Assay.
was pumped through
was monitored
and Anfinsen
(1).
of Ellman's
glass-bound
phosphate
reductive
protein
buffer,
0.05 M Tris-Cl,
procewith
pH 7.5.
pH 8.6,
through
the
Cp is
columns
at 3 ml/min,
activated
activated, and the
of the Michaelis-Menten
=
the
- f)
Km.ln(l
concentration;
to product; E,,
similarly
equation
enzyme was utilized
the product
enzyme;
0.1 ml of SG-CTGn beads,
were
to SG-CHT, used.
absorbance
BTEE
of the
at 256 nm (8). form
of surface-bound
been converted of the
from the
sodium
SG-CTGn beads,
cP where
was eluted by recycling
For assay, the bead
The integrated a column
of Epstein
by a modification
acetate-O.OlM
was effected
ml or reoxidized
effluent
titrated
for
24 hr at room temperature.
Kinetic and 0.35
were
The procedure
k,, total
f,
the
overall
enzyme
in evaluating
for
the kinetics
of
the data:
+ k,E,V,/Q the
fraction
of substrate
rate
constant
concentration;
V,,
Q, the
(catalytic the void
which
has
COeffiCieIIt)
volume;
and
flow rate. This equation differs slightly in that we have used the void volume rather than
from that of Lilly --et al. the total column volume in
determining
analyzed
least
enzyme concentration.
The data
squares.
1070
were
by the method
of
(9)
Vol. 48, No. 5, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE I Characteristics
of Non-Reduced Activated
and Reduced-Reoxidized to SG-CHT
Total Volume (ml>
Dry Weight 63)
Native
0.10
0.028
0.086
3.26
Reoxidized
0.35
0.093
0.301
1.16
Matrix-bound Enzyme
V~~~~,
SH Content (Reduced) (moles/mole)
K, CM)
x 1O-3
-
12.8 x 1O-5
11.0
x 10-2
11
6.8 x 10-5
3.1
Protein (mg)
(ml)
SG-CTGn
ko (set- 1)
RESULTS Table "native"
I gives
the characteristics
referring
not been
reduced,
8 M urea
and allowed
and "reoxidized"
0.14 mg protein/g mately tion
the
old
its
dry beads.
same value;
Analysis
hence,
there
to that
protein
appeared
beads,
even without
exposure
Accordingly,
these
to GdnsHCl, stored
eluate
the beads as amino
acid
were
approxi50 % adsorp-
stored
in cold
analysis of 0.14
used
for
in
revealed
yielded
were
gave a value
preparations
had
had been reduced
of the beads
to have been at least if
was released,
dry beads.
SG-CHT) which
which
analysis
of the Gdn-HCl
However,
of SG-CTGn columns,
product,
Amino acid
to the beads.
H20, adsorbed
activation
referring
to reoxidize.
of the zymogen
distilled
of the two types
to SG-CTGn (and
of 30-day mg protein/g
enzymatic
studies. Non-reduced 10-4 M and a
of 11.0 . . upon activation,
SG-CTGn, tively
SG-CTGn, k,
(Table
I).
of esterolytic following data
fitted
tude
of errors
changes if
the
to the
integrated
encountered
in flow flow
to enzyme.
rate
rate
rate
substrate
can result
is < 1 ml/min,
inhibition,
same value of Cp as did 0.27 u&i. Control SG-CHT beads exhibited ranging
from
ko/Km
yielded
of 3 mljmin, x lOa
indicates
by air-reoxidation Figure equation,
in sizeable
a l$.,, of whereas
1.28 x
reoxidized
M and 3.1 set-l,
ratios
It
reduced
a typical
and serves
error.
zymogen,
plot
to indicate
was found
experimental
respec-
a 53 % recovery
of the
1 presents
in such measurements.
the data plot in an almost vertical more than 25-30 % of the substrate exhibited
rate
of 6.79
of the
is achieved
activation
to SG-CHT,
at a flow
g ave values
Comparison
activity its
upon activation set"
of the the magni-
that
slight
In our
system,
too much of the substrate is hydrolyzed so that Best results are obtained when not line. has been hydrolyzed. in that
a concentration
no esterolytic
0.5 to 3 ml/min.
1071
The preparations of 0.54 mM produced
activity
at flow
rates
also the
Vol. 48, No. 5, 1972
BIOCHEMICAL
-32 -26-24
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
-20 -16 -12 -6 In(l-f
ln(l - f) vs. and Reoxidized
Fig. 1. A Plot of Cp SG-CHT (open circles),circles).
-4
)x 102
for Non-Reduced SG-CTGn Activated to SG-CTGn Activated to SG-CRT (filled
DISCUSSION To the authors' zymogen with exist tion
that,
could
of chymotrypsin
not
with
Adsorption
be anticipated
faces
can be a problem, storage
released
and Swaisgood all
that
(unpublished
The regeneration following
reductive
significant structure reduced
breakthrough chymotrypsinogen potential
from
which have
during
acid
functional
that
A in solution
action
to form SG-CTGn to glass
solutions.
surHowever,
zymogen was effectively
analysis
of a 30-day-old with
Gdn*HCl
Gdn.HCl.
Cho
effectively
beads. three-dimensional
structure
chymotrypsinogen
represents
in our understanding of the The air-reoxidation
proteins. enzymatic
reaction
had been washed
of matrix-bound
of the matrixof CTGn prior
and binding
demonstrated
activa-
of rr-chymotrypsin.
H20, adsorbed
succinyl-glass
of biologically
in multi-chain
1.4 % of the
in cold
most
innxobilization
of a did
zymogen,
the autocatalytic
protein,
of the amino
denaturation
that
in the case of dilute
data)
protein
indicate
beads
immobilization The possibility bound
a good source
CTGn is a basic
particularly
of an aliquot
adsorbed
covalently
in solution,
to the glass
of the SG-CTGn beads with
reported form.
By minimizing
may provide
as shown by comparison
preparation removes
since
first
The results
generated trypsin
the of the
to trypsin.
of zymogen
could upon
occur.
molecules
activation
is
to the enzyme
arrangement
CTGn was accessible
to its
this
activation
due to spatial
by trypsin
bound
knowledge,
subsequent
achievement of tertiary of denatured, fully
had resulted in a maximum recovery of In the present study, 53 % of activity (2).
1072
a
Vol. 48, No. 5, 1972
the
zymogen's
potential
immobilization function reduced
BIOCHEMICAL
esterolytic
of the
appears
activity
polypeptide
of intermolecular
which
bonds.
suggesting
ment of functional tions
of residues
an even wider eration the
apparent
proteins
the the
of proteins
primary
sequences
previously
in artificially
applicability
of the recent A (11)
zymogens
exemplified
of enzymatic among the
of growing bonds
shown.
formation in the polypep-
earlier
and the achieveinterac-
may now be extended Moreover,
immobilized somewhat
Thus,
thermodynamic
(10)
successful
to the
and the
complexes. upon the
of
in recovery
may be achieved
of disulfide depend
such as ribonuclease
of proteolytic
effect
conditions
of interactions
to aggregation
polysomal
location
than
conformations
under
of the attachment
structures
comprising
array
of active
that
tertiary
lead
A similar
of proteins by virtue --in vivo synthesis tide chains to ribosomes in the active observations
The increase
due to the avoidance
molecules
disulfide
was recovered
chains.
to be primarily
chymotrypsinogen
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
solid-phase
to
such regen-
proteins
extends
synthesis
more complicated
of
class
by chymotrypsinogen. REFERENCES
1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11.
Epstein, C. J., and Anfinsen, C. B ., 2. Biol. Chem. 237, 2175 (1962). Brown, J. C., and Horton, H. R., --Proc. Sot. &. Med. 141, in press --Biol. (1972). Biophys. Acta 258, 675 (1972). Cho, I. C., and Swaisgood, H. E., Biochim. Robinson, P. J., Dunnill, P., and Lilly, M. D., Biochim. Biophys. Acta 242, 659 (1971). Blow, D. M., Birktoft, J. J., and Hartley, B. S., Nature 221, 337 (1969). "Properties of Selected Commercial Glasses," Form B-83, Corning Glass Works, Corning, New York. Copyright 1949. Ellman, G. L., a. Biochem. Biophys. 82, 70 (1959). Hummel, B. C. W., Canad. 2. Biochem. Physiol. 37, 1393 (1959). Lilly, M. D., Horn=. E., and Crook, E. M., Biochem. 1. 100, 718 (1966). Epstein, C. J., Goldberger, R. F., and Anfinsen, C. B., Cold Spring Harbor m. Quant. Biol. _28, 439 (1963). Gutte, B., and- Merrifield, R. B., 2. --Amer. Chem. Sot. 9l, 501 (1969).
1073