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Proteases from mouse submaxillary gland
Vol. 36, No. 1, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
PROTEASES FROM MOUSE SUBMAXILLARY GLAND Isaac
Schenkein-:?, Mary Boesman, Edward Tokarsky, Louis Fishman and Milton Levy
Dept.
Received
of Biochemistry, College of Dentistry, New York University, New York
May 28, 1969
SUMMARY Two proteases (“A” and I’D”) from mouse submaxi 1lary gland have been isolated in high purity. At pH 8.5 trD” is more negative than “A” and is also smaller. Amino acid composition differs only in 6 constituents. “D” is activated 100-3CX3°/o when acting on tosyl arginine methyl esther by tosyl arginine and all&-amino acids. Both enzymes have a strong preference for arginyl bonds. We recently of Nerve
reported
Growth
and unusual
the
which
are devoid
report
as “A”,
(Fig.
pur i ty.
We have Both
substituted
ones.
of four
isolated
arginyl
to their
it
carboxyl
enzymes in this electro-
and “Dl’ in high
of activity
groups
glands
Irvington Medicine, Medicine,
“A”
appears
is activated
of this
gel columns
toward&N,
A number of protein too
activity
designation
acrylamide
The method of their submaxillary
specific
isolation
estero-proteolytic
two of these,
esters.
the
development
Their
on analytical
and here
address:
high
“C1’, and IrDt7 relates
Enzyme “D”
EXPERIMENTAL
-::- Present
separation
arginine
bonds involving
Two thousand
Further
show a marked degree
have been studied
tible
(1,2).
“B”,
method for
very
of NGF activity.
mobi lities
1).
(NGF) with
stability
method allows
phoretic
Factor
an improved
that
subtrates the peptide
are the most suscep-
by all&-NH2 isolation
from adult
acids.
is as follows: male mice
(over
House Institute and Dept. of New York University School of New York. 156
Vol. 36, No. 1, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Figure I. Analytical acrylamide gel electrophoresis of the fraction from carboxy methyl column chromatography and enzymes !1A11and I’D” after preparative acrylamide gel electrophoresis.
30 gm) obtained
frozen
from Pell-Freez
thawed and homogenized with
one liter
in a Waring
of 0. 1 M phosphate
preparation
was centrifuged
precipitate
discarded.
sulfate
(adjusted
volumes
of extract.
to pH 7.4 After
added to each
15 min at O-4” dis,carded of the
and
the mixture
with
at pH 7.4.
10 min and the
of 0.2 M streptomycin
3-s’,
the
Seven ml of cold 100 ml of the
(-15’) After
precipitate
was
absolute
supernatant.
was centrifuged.
157
The
NaOH) was added to each nine
3 hr at
supernatant.
were
at maximum speed,
lO.OOOxG for
48 ml of ethanol
streptomycin
blendor buffer
One volume
removed by centrifugation. was slowly
at
Biologicals,
ethanol After
The pellet
was
added to each 100 ml 2 hr at
-1’j5”,
centri-
Vol. 36, No. 1, 1969
fugation
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
gave a gummy red precipitates.
500 ml of cold to 35”/0
water
saturation
with
24.5
gm of the solid
3-5O,
the precipitate
supernatant
by adding
original
solution. at
35’ gm of that After
of NGF (3). all
NGF nor
of water.
This
in a small
against
165 cm column of DEAE-Sephadex as in method “B1l given
column was thoroughly
of separation
Further plished
by preparative
“Fractophoratorll obtained
for
with
shown in Fig-II.
purification
the various
was lyophi
A-25
to obtain
Peak II
gel
in Ref.5. steps
of the 158
lized,
at pH 7.5. was applied
(Pharmacia) (4).
The
buffer.
the pattern
contained
Peak V contained
acrylamide
with
and exhaus-
the Tris
of enzymes “A”
described
recovered
by the manufacturer
on at 250 ml/hr
was kept was retained
mg of protein)
equilibrated
of the enzymes of interest.
rate
HCl buffer
to a 2.5~
was carried
by the method of
of water,
of the dialysate
Elution
(200-500
cm
the estero-proteolytic
eluate
M Tris
of
to a 2.5~60
red pigment
volume
a 0.05
in
unti 1 free
The flow
of the
was centridisolved
prepared
A portion
prepared
it
was applied
ce 1lulose,
ammonium
each 100 ml of
They were quantitatively
disolved
dialyzed
for
and dialyzed
fraction
but neither
2-3 column volumes the residue
1 hr at The
with
the precipitate
water
Virtually
enzymes were he Id.
tively
30 min,
isolation
by the cellulose,
by adding
After
2-4 hr in the cold
This
below 3 ml/min.
salt
in
was brought
to ammonium sulfate
to 85’/ o saturation
distilled
the
The solution
100 ml of solution.
of carboxy-methyl
Cohen for
was disolved
was removed by centrifugation.
ammonium sulfate. column
per
15,OOOxG for
100 ml of cold
stirring. respect
was brought
sulfate
fuges
with
This
a mixture
the NGF activity.
and “D” was accom-
electrophoresis Table
using
the
I shows the yie Ids
isolation.
Vol. 36, No. 1, 1969
BIOCHEMICAL
0
0
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
+ I ’ 100 Fraction
+ ’ No.
I 200
Figure II. DEAE-Sephadex column chromatography text. The arrows are points of addition of 0.1 0.2 M NaCl in the buffer respectively.
described in M NaCl and
TABLE I Frac t i on
Protein
Crude homogenate 24.800 85O/o ammoni urn sulfate 3680 Carboxy methyl fraction 2362 DEAE-Sephadex peak II I’J-JI’ Preparative Electrophoresis “A” (1)
Specific activity
Esterase mg
3.65~10~
'I
2.66~10~
”
725
'
”
2.32~10~
”
1,000
”
7.2
11
1,800
n
~10~
6.9-10.4~10~ 2.6 x105
units
” ”
150 U/mg
The enzyme unit is defined as the amount of protein that hydrolyses 1 p M of TAME/min at pH 8.0 and 37’. The “no enzyme” rate under these conditions is about 0.015 pm/min and is subtracted. The reaction mixture consists of 3 ml of solution which is 0. 1 M in Kcl, 0.0053 M TAME and 0.0026 M glycine. The reason for the presence of glycine is discussed in the text.
(2)
The total esterase units of the crude homogenate reflect the combined action of a variety of enzymes in the mouse submaxi 1 lary g land (e. g. , Kallikrein) that act on the substate (TAME) that served for the definition of the enzyme unit. These various enzymes have different specific activities and this must be taken into account in the evaluation of the table of yields.
(3)
We have observed considerable variability in total protein We ascribe as well as esterase units in these preparations. it to the age of the submaxillary glands used as starting material.
159
Vol. 36, No. 1, 1969
Figure (stained
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I includes
with
described
amido black)
in the
of protein
the analytical
isolation
bands indicating
gels
of the enzymes after At
procedure.
added to the gels,
as single
acrylamide
both
a high
the
leve Is of
enzymes “A” degree
(6) last
step
100-150 pg
and “D”
ran
of purity.
TABLE II
Amino Acid
Composition
of Enzymes “A”
Residues/M ana lyt ica 1 "A 11 ,!D’, Aspartic acid Threonine Serine Glutamic acid Proline Glycine A lani ne Cysteine Va line Isoleucine Leucine Tyrosine Pheny 1 a lanine Methi onine Lys i ne Histidine Arginine Tryptophan (from U.V. absorbance) Residue wts.
Residues/M inteoers
30.0 30.9 15.4 16.3 18.2 17.8 21.8 21.9 20. 1 16.0 g::
:gi 816 9.1 5.9 25.1
9.4
13.7 11.7 27.5
and “D”
31 15 18 22
31 16 18 22
:‘;
;E 15
1; 12 27
; 6 ‘3 9
: 5 22
: 22 : 7
c 12
30,643
( “A” ) , 28,330
( “D’)
The results given are the averages of 5 analyses of each enzyme using hydrolysis times of 24, 48, and 72 hr. The M ratios were calculated using the parenthetical figures as guides. Table acid
II
hydrolysis.
ti on between
shows the amino acid There lfAf’ and “D”.
content
of
the enzymes after
is a remarkable
similarity
Significant
differences
160
of composiare
found
Vol. 36, No. 1, 1969
only
in 6 amino acids.
gives
a molecular for
28,000
Summation
of the
found
of about
30,000
for
weight
weights
and 2.8
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1rD71in good agreement
molecular
with
residue-weights
enzyme “A”
the estimates
based on the observed
S20 values
and
of their of 3. 1 S
S respectively.
Rabbit Sephadex to
BIOCHEMICAL
antiserum
to the material
column was prepared.
Enzymes “A”
be immuno-electrophoretically
genitally
related
activity
of both
(7).
in peak II
of the DEAE-
and rrD’7 were found
pure and distinct,
The antiserum
enzymes.
It
abolished
does not
affect
but antithe enzymatic
the
action
of
trypsin. TABLE III
Hydrolyzed
Not hydrolyzed
Tosyl arginine methyl ester Benzoyl arginine ethyl ester POlyarginine Cyt.ochrome “Ct’ Lys 0 zyme Arginine and lysine rich histones Protamine sulfate
Table assayed
III
with
set at pH 8.0 of enzymatic hydrolysis methyl
ester
shows the various the enzymes.
ment of alkali
Leucine ethyl ester Lysine methyl ester Po ly lys i ne Arginyl-g lycyl-g lycine Alanyl glycine Glycyl alanine Glycyl pro line Glycyl leucine Valyl glycine p-nitro-phenyl acetate Glycyl-Glycyl a lanine
uptake
Hydrolysis
using
or by form01 activities
Form01 titrations
titration
solution
(Radiometer
by measureCopenhagen)
For rapid
in color
produced
of p-toluene
that 161
have been
(9).
in the presence indicated
that
was followed
a pH stat
the change
of an alkaline (TAME)
substrates
of phenol
scanning by
sulfonyl
arginine
red was used.
polyarginine
(M.W.
about
Vol. 36, No. 1, 1969
150,000)
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
was rapidly
peptides,
with
lysine
hydrolyzed
some release
(M.W.
150-200,000) of protamine
histones
correlated
these
proteins
Addition lysis form01
well
titer
arginine, attacked
with
while
lysine
with rich
or
with
The extent
lysine
rich
content
C-terminal histones
and “D” or a mixture
consistent
poly-
at a 11.
the arginine
peptides
to the
enzymes “A”
and tri-arginine
and of arginine
and yielded
of trypsin with
of free was not
of hydrolysis also
to di-
the additional
of
arginine.
after
hydro-
of both,
gave a
splitting
of the
lys ine bonds. Figure
III
shows the
enzymes “A’, and lIDlIe
reaction
mixture,
significantly
This
the
activation
examination that
all
product
of the effect amino acids of rate
Several
of the curve
of p-tosyl
Simi lar
rate. of the
reaction,
amino acids.
are activators
to varying
of hydrolysis acids
range
tested
were as effective
for
arginine
to
in a
additon
of
has no effect.
of the hydrolysis
of free
D-amino
and phenylalanine)
nature
of TAME by
at the same time
initial
by a product
Enhancements 3oo”/o -
resulting
other
of hydrolysis
upon addition
enhanced
methanol,
course
The sigmoid
enzyme “D1’ is abolished the
time
led to the It
was found
degrees.
between
(alanine,
10Q”/~
and
glutamic
acid,
as the corresponding
L-isomers. Comparison
of sodium acetate,
indicated
that
only
activated
by either
The Km’s for determined 6.6x lo-* the values
for M/l
latter
amino acids the
both at 37’.
obtained
the
hydrolysis
enzymes.
acetamide,
activated. or tosyl
Enzyme “A”
is not
arginine.
of TAME at pH 8.0 were For enzyme “A”
For enzyme “D1’ (activated range
and glycine
from 2.4 162
to 3. 1x10-*
the
value with
M/l
is glycine)
at 37’,
Vol. 36, No. 1, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Figure III. Time course of action of 2.3x 1o-5 M) a. Enzyme “A’* with b. Enzyme lrDtf without activator. tosyl arginine initially present.
because
of some uncertainty
weaver-Burke of these
plots.
trypsin
shows that
appear
less
protamine reaches
active
various
from 500/, activity
100°/,.
versus
times
the extent
activities with
though
of hydrolysis
reached
that
of They
more active.
as substrates
as that
Cue’,
of the Cu”
enzyme activity
esters
protein
Fetf”, to
TAME and similar
with
eventually
by trypsin.
on enzyme “D1’ have been done with
At concentrations
agents.
1x1o-5 M of
specific
with
studies
of Line-
of the
are from 2-15
same point
Inhibition
interpretation
they
or polyarginine the
in the
A comparison
enzymes towards
of enzymes on TAME. (3 ml or without tosyl arginine. c. Enzyme *‘D” with 1.2~10~~
Zn”,
ranging Cd’+ the
EDTA can restore inhibited
enzyme.
EDTA concentration 163
from
1x10-’
M to
enzyme was inhibited up to 85o/o A plot
the
of return
at fixed
of
TAME and
M
Vol. 36, No. 1, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
CU++ concentration
showed a sigmoid
(0.5’ to 3.0’/0)
had no effect
TAME or of protamine solution lyzed
inhibits
the higher
DISCUSSION
There
al.
(10)
the
as a result
of urea,
changes
embryos cultured
was not
More
synthesis
of two estero-proteases
bond specificity
group
different
with
proteins
are
The characteristics tinguish studies
them clearly as well
seems to point than
“A”
acid
residues
it
protein
from
showed scant activity
of androgens
and
on the
bio-
the mouse submaxillary by mercaptoethanol.
have not clear
or kinetic
been reported whether
the
and for
same or
involved. of the from
to a structural
as if
caused
Calissano
substrates
is not
Attardi
Proteolytic
inactivated
enzymes reported
trypsin.
as a comparison
and differs
but
recently,
from
characteristics of enzymes,
gland.
in muscle tissue
the effect
These enzymes were both
either
was
one of which
casein.
reported.
have studied
physico-chemical
hydro-
on the presence
--in vitro,
on denatured
(11)
Since
reports
on two enzymes,
Angeletti
gland.
substrate
have been earlier
activity other
of
M) in the substrate
The amount of
dedifferentiative
proteolytic
of hydrolysis
in the mouse submaxillary
11 day old chick
for
(b-10
acting
have reported
demonstrable
Urea
Mercaptoethanol
the urea concentration.
of estero-proteases et
rate
enzyme.
when enzyme stopped
sma1 ler,
on the
sulfate.
the
curve.
limited
Immune-electrophoretic
of their
amino acid
relatedness.
in composition proteolysis
on here dis-
“D”
by relatively converted
content
is smaller few amino “Al1 to rrD1t.
ACKNOWLEDGMENT The authors are grateful to Dr. R.C. Warner, Department of Biochemistry, N.Y.U. School of Medicine for the determinations of the Svedberg values. This work was supported by USPHS Grants nos. NB 07370 and AM 09873.
164
Vol. 36, No. 1, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
REFERENCES 1. 2.
;: 5. 6. 7.
0. 9. 10.
11.
Schenkein, I., Levy, M., Bueker, E.D. and Tokarsky, E., Science, I-& 640, 1968. Schenkein, I., Bueker, E.D. and Levy, M., Conference on Hormones in Deve lopment. 1968, Nottingham, England (in press). Cohen, S., Proc. Nat. Acad. Sci. (US), 4, 302, 1960. Pharmacia Fine Chemicals Inc. Sephadex ion exchangers, undated. Schenkein, I., Levy, M., and Weis, P., Analytical Biochem.,
25,
387,
Davz, B. J. PP. 321, Scheidegger,
1,
103,
1968.
and Ornstein,
4049 1964. J. J.,
Inter.
L., Arch.
1955.
Ann.
N.Y.
Allergy
Acad.
Sci.,
121,
Appl.
Immunol.,
Baines, N.,G., Baird, J.B. and Elmore, D.T., Biochemical J., 90, 470, 1964. Levy, M., IN: Methods in Enzymology, (S.P. Volowick and N.O. Kaplan, Eds. ), vol. 2, 454, 1957. A,ttardi, D.G., Schlessinger, M. J. and Schlessinger, S., Science, B, 1253, 1968. Calissano, P. and Angeletti, P.U., Biochem. Biophys. Acta, 156, 51, 1968.
165
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
PROTEASES FROM MOUSE SUBMAXILLARY GLAND Isaac
Schenkein-:?, Mary Boesman, Edward Tokarsky, Louis Fishman and Milton Levy
Dept.
Received
of Biochemistry, College of Dentistry, New York University, New York
May 28, 1969
SUMMARY Two proteases (“A” and I’D”) from mouse submaxi 1lary gland have been isolated in high purity. At pH 8.5 trD” is more negative than “A” and is also smaller. Amino acid composition differs only in 6 constituents. “D” is activated 100-3CX3°/o when acting on tosyl arginine methyl esther by tosyl arginine and all&-amino acids. Both enzymes have a strong preference for arginyl bonds. We recently of Nerve
reported
Growth
and unusual
the
which
are devoid
report
as “A”,
(Fig.
pur i ty.
We have Both
substituted
ones.
of four
isolated
arginyl
to their
it
carboxyl
enzymes in this electro-
and “Dl’ in high
of activity
groups
glands
Irvington Medicine, Medicine,
“A”
appears
is activated
of this
gel columns
toward&N,
A number of protein too
activity
designation
acrylamide
The method of their submaxillary
specific
isolation
estero-proteolytic
two of these,
esters.
the
development
Their
on analytical
and here
address:
high
“C1’, and IrDt7 relates
Enzyme “D”
EXPERIMENTAL
-::- Present
separation
arginine
bonds involving
Two thousand
Further
show a marked degree
have been studied
tible
(1,2).
“B”,
method for
very
of NGF activity.
mobi lities
1).
(NGF) with
stability
method allows
phoretic
Factor
an improved
that
subtrates the peptide
are the most suscep-
by all&-NH2 isolation
from adult
acids.
is as follows: male mice
(over
House Institute and Dept. of New York University School of New York. 156
Vol. 36, No. 1, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Figure I. Analytical acrylamide gel electrophoresis of the fraction from carboxy methyl column chromatography and enzymes !1A11and I’D” after preparative acrylamide gel electrophoresis.
30 gm) obtained
frozen
from Pell-Freez
thawed and homogenized with
one liter
in a Waring
of 0. 1 M phosphate
preparation
was centrifuged
precipitate
discarded.
sulfate
(adjusted
volumes
of extract.
to pH 7.4 After
added to each
15 min at O-4” dis,carded of the
and
the mixture
with
at pH 7.4.
10 min and the
of 0.2 M streptomycin
3-s’,
the
Seven ml of cold 100 ml of the
(-15’) After
precipitate
was
absolute
supernatant.
was centrifuged.
157
The
NaOH) was added to each nine
3 hr at
supernatant.
were
at maximum speed,
lO.OOOxG for
48 ml of ethanol
streptomycin
blendor buffer
One volume
removed by centrifugation. was slowly
at
Biologicals,
ethanol After
The pellet
was
added to each 100 ml 2 hr at
-1’j5”,
centri-
Vol. 36, No. 1, 1969
fugation
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
gave a gummy red precipitates.
500 ml of cold to 35”/0
water
saturation
with
24.5
gm of the solid
3-5O,
the precipitate
supernatant
by adding
original
solution. at
35’ gm of that After
of NGF (3). all
NGF nor
of water.
This
in a small
against
165 cm column of DEAE-Sephadex as in method “B1l given
column was thoroughly
of separation
Further plished
by preparative
“Fractophoratorll obtained
for
with
shown in Fig-II.
purification
the various
was lyophi
A-25
to obtain
Peak II
gel
in Ref.5. steps
of the 158
lized,
at pH 7.5. was applied
(Pharmacia) (4).
The
buffer.
the pattern
contained
Peak V contained
acrylamide
with
and exhaus-
the Tris
of enzymes “A”
described
recovered
by the manufacturer
on at 250 ml/hr
was kept was retained
mg of protein)
equilibrated
of the enzymes of interest.
rate
HCl buffer
to a 2.5~
was carried
by the method of
of water,
of the dialysate
Elution
(200-500
cm
the estero-proteolytic
eluate
M Tris
of
to a 2.5~60
red pigment
volume
a 0.05
in
unti 1 free
The flow
of the
was centridisolved
prepared
A portion
prepared
it
was applied
ce 1lulose,
ammonium
each 100 ml of
They were quantitatively
disolved
dialyzed
for
and dialyzed
fraction
but neither
2-3 column volumes the residue
1 hr at The
with
the precipitate
water
Virtually
enzymes were he Id.
tively
30 min,
isolation
by the cellulose,
by adding
After
2-4 hr in the cold
This
below 3 ml/min.
salt
in
was brought
to ammonium sulfate
to 85’/ o saturation
distilled
the
The solution
100 ml of solution.
of carboxy-methyl
Cohen for
was disolved
was removed by centrifugation.
ammonium sulfate. column
per
15,OOOxG for
100 ml of cold
stirring. respect
was brought
sulfate
fuges
with
This
a mixture
the NGF activity.
and “D” was accom-
electrophoresis Table
using
the
I shows the yie Ids
isolation.
Vol. 36, No. 1, 1969
BIOCHEMICAL
0
0
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
+ I ’ 100 Fraction
+ ’ No.
I 200
Figure II. DEAE-Sephadex column chromatography text. The arrows are points of addition of 0.1 0.2 M NaCl in the buffer respectively.
described in M NaCl and
TABLE I Frac t i on
Protein
Crude homogenate 24.800 85O/o ammoni urn sulfate 3680 Carboxy methyl fraction 2362 DEAE-Sephadex peak II I’J-JI’ Preparative Electrophoresis “A” (1)
Specific activity
Esterase mg
3.65~10~
'I
2.66~10~
”
725
'
”
2.32~10~
”
1,000
”
7.2
11
1,800
n
~10~
6.9-10.4~10~ 2.6 x105
units
” ”
150 U/mg
The enzyme unit is defined as the amount of protein that hydrolyses 1 p M of TAME/min at pH 8.0 and 37’. The “no enzyme” rate under these conditions is about 0.015 pm/min and is subtracted. The reaction mixture consists of 3 ml of solution which is 0. 1 M in Kcl, 0.0053 M TAME and 0.0026 M glycine. The reason for the presence of glycine is discussed in the text.
(2)
The total esterase units of the crude homogenate reflect the combined action of a variety of enzymes in the mouse submaxi 1 lary g land (e. g. , Kallikrein) that act on the substate (TAME) that served for the definition of the enzyme unit. These various enzymes have different specific activities and this must be taken into account in the evaluation of the table of yields.
(3)
We have observed considerable variability in total protein We ascribe as well as esterase units in these preparations. it to the age of the submaxillary glands used as starting material.
159
Vol. 36, No. 1, 1969
Figure (stained
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I includes
with
described
amido black)
in the
of protein
the analytical
isolation
bands indicating
gels
of the enzymes after At
procedure.
added to the gels,
as single
acrylamide
both
a high
the
leve Is of
enzymes “A” degree
(6) last
step
100-150 pg
and “D”
ran
of purity.
TABLE II
Amino Acid
Composition
of Enzymes “A”
Residues/M ana lyt ica 1 "A 11 ,!D’, Aspartic acid Threonine Serine Glutamic acid Proline Glycine A lani ne Cysteine Va line Isoleucine Leucine Tyrosine Pheny 1 a lanine Methi onine Lys i ne Histidine Arginine Tryptophan (from U.V. absorbance) Residue wts.
Residues/M inteoers
30.0 30.9 15.4 16.3 18.2 17.8 21.8 21.9 20. 1 16.0 g::
:gi 816 9.1 5.9 25.1
9.4
13.7 11.7 27.5
and “D”
31 15 18 22
31 16 18 22
:‘;
;E 15
1; 12 27
; 6 ‘3 9
: 5 22
: 22 : 7
c 12
30,643
( “A” ) , 28,330
( “D’)
The results given are the averages of 5 analyses of each enzyme using hydrolysis times of 24, 48, and 72 hr. The M ratios were calculated using the parenthetical figures as guides. Table acid
II
hydrolysis.
ti on between
shows the amino acid There lfAf’ and “D”.
content
of
the enzymes after
is a remarkable
similarity
Significant
differences
160
of composiare
found
Vol. 36, No. 1, 1969
only
in 6 amino acids.
gives
a molecular for
28,000
Summation
of the
found
of about
30,000
for
weight
weights
and 2.8
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1rD71in good agreement
molecular
with
residue-weights
enzyme “A”
the estimates
based on the observed
S20 values
and
of their of 3. 1 S
S respectively.
Rabbit Sephadex to
BIOCHEMICAL
antiserum
to the material
column was prepared.
Enzymes “A”
be immuno-electrophoretically
genitally
related
activity
of both
(7).
in peak II
of the DEAE-
and rrD’7 were found
pure and distinct,
The antiserum
enzymes.
It
abolished
does not
affect
but antithe enzymatic
the
action
of
trypsin. TABLE III
Hydrolyzed
Not hydrolyzed
Tosyl arginine methyl ester Benzoyl arginine ethyl ester POlyarginine Cyt.ochrome “Ct’ Lys 0 zyme Arginine and lysine rich histones Protamine sulfate
Table assayed
III
with
set at pH 8.0 of enzymatic hydrolysis methyl
ester
shows the various the enzymes.
ment of alkali
Leucine ethyl ester Lysine methyl ester Po ly lys i ne Arginyl-g lycyl-g lycine Alanyl glycine Glycyl alanine Glycyl pro line Glycyl leucine Valyl glycine p-nitro-phenyl acetate Glycyl-Glycyl a lanine
uptake
Hydrolysis
using
or by form01 activities
Form01 titrations
titration
solution
(Radiometer
by measureCopenhagen)
For rapid
in color
produced
of p-toluene
that 161
have been
(9).
in the presence indicated
that
was followed
a pH stat
the change
of an alkaline (TAME)
substrates
of phenol
scanning by
sulfonyl
arginine
red was used.
polyarginine
(M.W.
about
Vol. 36, No. 1, 1969
150,000)
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
was rapidly
peptides,
with
lysine
hydrolyzed
some release
(M.W.
150-200,000) of protamine
histones
correlated
these
proteins
Addition lysis form01
well
titer
arginine, attacked
with
while
lysine
with rich
or
with
The extent
lysine
rich
content
C-terminal histones
and “D” or a mixture
consistent
poly-
at a 11.
the arginine
peptides
to the
enzymes “A”
and tri-arginine
and of arginine
and yielded
of trypsin with
of free was not
of hydrolysis also
to di-
the additional
of
arginine.
after
hydro-
of both,
gave a
splitting
of the
lys ine bonds. Figure
III
shows the
enzymes “A’, and lIDlIe
reaction
mixture,
significantly
This
the
activation
examination that
all
product
of the effect amino acids of rate
Several
of the curve
of p-tosyl
Simi lar
rate. of the
reaction,
amino acids.
are activators
to varying
of hydrolysis acids
range
tested
were as effective
for
arginine
to
in a
additon
of
has no effect.
of the hydrolysis
of free
D-amino
and phenylalanine)
nature
of TAME by
at the same time
initial
by a product
Enhancements 3oo”/o -
resulting
other
of hydrolysis
upon addition
enhanced
methanol,
course
The sigmoid
enzyme “D1’ is abolished the
time
led to the It
was found
degrees.
between
(alanine,
10Q”/~
and
glutamic
acid,
as the corresponding
L-isomers. Comparison
of sodium acetate,
indicated
that
only
activated
by either
The Km’s for determined 6.6x lo-* the values
for M/l
latter
amino acids the
both at 37’.
obtained
the
hydrolysis
enzymes.
acetamide,
activated. or tosyl
Enzyme “A”
is not
arginine.
of TAME at pH 8.0 were For enzyme “A”
For enzyme “D1’ (activated range
and glycine
from 2.4 162
to 3. 1x10-*
the
value with
M/l
is glycine)
at 37’,
Vol. 36, No. 1, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Figure III. Time course of action of 2.3x 1o-5 M) a. Enzyme “A’* with b. Enzyme lrDtf without activator. tosyl arginine initially present.
because
of some uncertainty
weaver-Burke of these
plots.
trypsin
shows that
appear
less
protamine reaches
active
various
from 500/, activity
100°/,.
versus
times
the extent
activities with
though
of hydrolysis
reached
that
of They
more active.
as substrates
as that
Cue’,
of the Cu”
enzyme activity
esters
protein
Fetf”, to
TAME and similar
with
eventually
by trypsin.
on enzyme “D1’ have been done with
At concentrations
agents.
1x1o-5 M of
specific
with
studies
of Line-
of the
are from 2-15
same point
Inhibition
interpretation
they
or polyarginine the
in the
A comparison
enzymes towards
of enzymes on TAME. (3 ml or without tosyl arginine. c. Enzyme *‘D” with 1.2~10~~
Zn”,
ranging Cd’+ the
EDTA can restore inhibited
enzyme.
EDTA concentration 163
from
1x10-’
M to
enzyme was inhibited up to 85o/o A plot
the
of return
at fixed
of
TAME and
M
Vol. 36, No. 1, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
CU++ concentration
showed a sigmoid
(0.5’ to 3.0’/0)
had no effect
TAME or of protamine solution lyzed
inhibits
the higher
DISCUSSION
There
al.
(10)
the
as a result
of urea,
changes
embryos cultured
was not
More
synthesis
of two estero-proteases
bond specificity
group
different
with
proteins
are
The characteristics tinguish studies
them clearly as well
seems to point than
“A”
acid
residues
it
protein
from
showed scant activity
of androgens
and
on the
bio-
the mouse submaxillary by mercaptoethanol.
have not clear
or kinetic
been reported whether
the
and for
same or
involved. of the from
to a structural
as if
caused
Calissano
substrates
is not
Attardi
Proteolytic
inactivated
enzymes reported
trypsin.
as a comparison
and differs
but
recently,
from
characteristics of enzymes,
gland.
in muscle tissue
the effect
These enzymes were both
either
was
one of which
casein.
reported.
have studied
physico-chemical
hydro-
on the presence
--in vitro,
on denatured
(11)
Since
reports
on two enzymes,
Angeletti
gland.
substrate
have been earlier
activity other
of
M) in the substrate
The amount of
dedifferentiative
proteolytic
of hydrolysis
in the mouse submaxillary
11 day old chick
for
(b-10
acting
have reported
demonstrable
Urea
Mercaptoethanol
the urea concentration.
of estero-proteases et
rate
enzyme.
when enzyme stopped
sma1 ler,
on the
sulfate.
the
curve.
limited
Immune-electrophoretic
of their
amino acid
relatedness.
in composition proteolysis
on here dis-
“D”
by relatively converted
content
is smaller few amino “Al1 to rrD1t.
ACKNOWLEDGMENT The authors are grateful to Dr. R.C. Warner, Department of Biochemistry, N.Y.U. School of Medicine for the determinations of the Svedberg values. This work was supported by USPHS Grants nos. NB 07370 and AM 09873.
164
Vol. 36, No. 1, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
REFERENCES 1. 2.
;: 5. 6. 7.
0. 9. 10.
11.
Schenkein, I., Levy, M., Bueker, E.D. and Tokarsky, E., Science, I-& 640, 1968. Schenkein, I., Bueker, E.D. and Levy, M., Conference on Hormones in Deve lopment. 1968, Nottingham, England (in press). Cohen, S., Proc. Nat. Acad. Sci. (US), 4, 302, 1960. Pharmacia Fine Chemicals Inc. Sephadex ion exchangers, undated. Schenkein, I., Levy, M., and Weis, P., Analytical Biochem.,
25,
387,
Davz, B. J. PP. 321, Scheidegger,
1,
103,
1968.
and Ornstein,
4049 1964. J. J.,
Inter.
L., Arch.
1955.
Ann.
N.Y.
Allergy
Acad.
Sci.,
121,
Appl.
Immunol.,
Baines, N.,G., Baird, J.B. and Elmore, D.T., Biochemical J., 90, 470, 1964. Levy, M., IN: Methods in Enzymology, (S.P. Volowick and N.O. Kaplan, Eds. ), vol. 2, 454, 1957. A,ttardi, D.G., Schlessinger, M. J. and Schlessinger, S., Science, B, 1253, 1968. Calissano, P. and Angeletti, P.U., Biochem. Biophys. Acta, 156, 51, 1968.
165