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Amino acid sequence near the amino terminus of porcine pepsin
Vol.
41,
No.
BIOCHEMICAL
3, 1970
AMINO
ACID
AND
SEQUENCE OF
BIOPHYSICAL
NEAR
Received
September
Institute, Copenhagen,
A
IN0
COMMUNICATIONS
TERMINUS
r
PEPSIN
Jordan Genetic
THE
PORCINE
RESEARCH
Tong2
Deportment Copenhagen,
II,
University Denmark
of
29, 1970
Summary: The amino acid sequence near the amino terminus of porcine pepsin wos By diogonal electrophoresis (l), a peptide was isolated containing 9 residues studied. from the amino terminus of pepsin. Structural studies established their sequence to be Ile-Gly-Asp-Glu-Pro-Leu-Glu-Asn-Tyr. Comparison of this amino-terminal sequence with thot known for rennin showed a definite homology. Alignment of the homologous residues revealed that the sites at which the respective rymogens ore cleaved to form active pepsin and rennin are 2 residues apart. The implications of this finding in the mechanism of activation of zymogens of the acidic proteases ore discussed. The
existence
pepsin,
rennin,
enzymes pepsin
and
descended and
denced to the
of o structural
bovine
gastricsin from
common
is now
a common
rennin,
by comparison
the
of partial
homology
sequence
Asp-Glu-Pro enzyme
‘This
(6).
was
well
ancestral
shared
are
amino
acid
elsewhere
The
partially
disparity
from
during
closely
homologous
in these
by
NIH
evolution.
Porcine
in structure,
as evi-
two
enzymes
are completely
surprising
one
by hydrolysis’of
AM-01
(4). the
In contrast first
dissimilar.
in pepsin
when
Grant
these
however,
whereas
including
Apparently,
molecules,
Research
proteases,
their
in the
(5),
zymogen
3).
protease
sequences
is especially
gastric
(2,
of pepsin and rennin
its respective
supported
certain
established
is Gly-Glu-Val-Ala-Ser
is activated
work
among
in particular,
residues from the amino tennini rennin,
homology
5
In
it is Ile-Gly-
considers
that
each
a peptide
bond
to
107.
n
‘Recipient Oklahoma Oklahoma
of NIH Career Development Medical Research Foundation, City, Oklahoma 73104.
Award 5 K04-AM-38638. University of Oklahoma
697
Permanent Medical
address: Center,
Vol.
41,
No.
3, 1970
form
a new
amino
near
the
amino
limited
terminus tennini
terminus it was
felt
rennin
would
amino
acid
phoresis below)
that
prove
Louis,
Japan.
to a much
One
to be more
RESEARCH
would
thus
homologous,
near
COMMUNICATIONS
expect
the
sequences
as a reflection
(1) was
isolation
Subtilisin
was
Other
because
purchased
purchased used
from
Novo
were
of the
5 residues
of
the
from
sequence
for
with
already
that
to establish
of pepsin.
pepsin
was
chemicals
undertaken
amino-terminal
Crystalline
Thermolysin
in pepsin
terminus
adopted
of specific
Methods:
were
amino
of only
amino-terminal
sequence
studies the
a sequence
longer
of a longer
et al.
MO.
Denmark.
BIOPHYSICAL
enzyme.
enzymes
revealing,
sequence
and
active
has identified
comparison
of Butler
Materials
on pepsin
as opposed
permit
AND
change.
work
(6),
in the
of these
evolutionary Previous
St.
BIOCHEMICAL
The
rennin
amino
(5).
Since
known
in further
method
techniques
the
,for
detail
of diagonal
involved
the electro-
(described
peptides. was
obtained
from
Daiwa
from Kaseai
Terapeutisk highest
Sigma
Chemical
K. C.
Co.,
Laboratorium, purity
Co., Osaka,
Copenhagen,
purchased
from
commercial
sources. The
amino
groups and
on the
protein
groups
of lysine
aminoethyl
maleyl
derivatives
excess
of maleic
anhydride
powder
protein,
and
cystein)
pH was
maintained
according
the
Within
10 minutes
against
0.05
carried
out
at room
M NH40H, by adding
N-ethylmorpholine
(such
to the
were
method was added between
temperature, the
protein
buffer,
amino-terminal
was
with
maleic
of Butler
et al.
(1).
in small 8 and
pH
portions
9 by the was
lyophilized.
to 8.0,
group
reacted
maleylation
1 mg of subtilisin acetate
as the
Thirty
incubating
E-amino
to form
times
molar
to a 1% solution addition
After
mixture
powder.
dialysis
digestion
protein the
of
of Na2C03
subtilisin
100 mg of maleylated and
the
anhydride
complete. The
and
was
in 5 ml of 0.2 for
16 hours
at 370%. Detailed described
procedures (7,
8).
After
in diagonal proteolysis
electrophoresis and
first-dimensional
698
were
performed electrophoresis,
as previously the
masking
M
Vol.
41,
No. 3,197O
maleyl
group
peptides
was
in the
accomplished pH
BIOCHEMICAL
3.5,
formed
2nd-dimensional
18 hours
Edman
identified
by
the
residue
produced
a pattern
(Fig. NT.This
of pepsin,
as judged
which
above
from
or near
to be lysine-containing
electrophoretic
to the
COMMUNICATIONS
mobility
Removal
was The
vapor
of the
of the maleyl
of a pyridine
involved
group
acetate
was buffer,
A)
peptide
peptides
the
line
were
of the
determined
newly by thin-
residues
of maleyl
major
in the
of the from
digest
spot
to have
change
derived
acids
Carboxyl-terminal
subtilisin
was assumed
neutral
by determination
amino
(10).
in which
its mobility the
dansyl
out
were
(11).
of the
1, Part
carried
sheets
digestion
electrophoresis
lay
(9).
carboxypeptidase
peptide
strips
on polyamide
Diagonal
was
paper
degradation
Results:
line
the
RESEARCH
(1).
sequential
chromatography
BIOPHYSICAL
electrophoresis.
at 60’
amino-terminal
layer
thus altering
by exposing for
The
removed,
AND
second
laying
derived two
porcine off
from
the
dimensions. dimension
carboxyl-terminal
the
region
diagonal
amino The
(L,-L9)
pepsin
terminus
peptide were
of the
assumed molecule
1 10
0 -0
10
20
:, w
30
I 20
CM. FROM Fig.
1.
ORIGIN,
1 st
DIMENSION
Diagrams of pH 6.5 diagonal electrophoresis subtilisin digest of porcine pepsin (A) and fmgment derived from the amino-terminal aminoethylated porcine pepsin (B).
699
I
10
spots
of demaleylated and a cyanogen bromide half of reduced and
Vol.
41,
No.
(12).
3, 1970
Deamidation
spots
that
appeared
(PI-Plo) that
were
sites.
To confirm
were
performed
reduced
was
line.
Numerous
near
the
diagonal
line.
Since
this
derived
(Fig,
analysis,
maleylation fragment
from
the
B).
again
Only
traces
peptides
CB2,
which
containing
from
peptides
these
as the
maior
P, -P4
aminoethyl
cleavage
were
160 (Tang,
laying
off
present.
cystein,
of
about
molecule
spot
autolytic
experiments
contained pepsin
peptide
showed
sites,
bromide
of the
of peptides
(13)
electrophoresis
cyanagen
emerged
few
intensity
et al.
produced
by
half
the
of minor
cleavage
diagonal
produced
for
Rajagopolan autolytic
and
Fragment
NT
spots
peptides
amino-terminal
Peptide
COMMUNICATIONS
to be responsible
many
amino-terminal
obviously
experiments
diagonal
of pepsin.
made
amino
acid Ile,
NT
the
same
digested
Tyr.
Peptide
NT
37”
C for
18 hours
gave
contained
portion the
4 residues,
determined
by the I).
Thus,
Pro-Leu-Glu-Asn-Tyr
peptide
was with
the
mobility the
had
of peptide
sequence
contained
with
and
sequence
peptide must
from
of the
have
the
Peptides
the sequence
peptides
of peptide
only
maior
from
the
with
protein.
The
of which
on paper
I).
By using
the
at different NT
.
700
was
established
of
12.5%.
residue of SO:1
at pH 6.5.
and
and
the
from dansyl
Peptide acids
at
Peptide
derived
degradation
The steps
yield
ratio
to be Ile-Giy-Afp-Gb-Pro. * Le,v-G$-Afn-Txr.
terminus
carboxyl-terminal
apparently
Edman
amino
present
Its amino-terminal
electrophoresis Ile,
peptide
a molar
at a substrate-enzyme
an amino-terminal
sequence
derived
(Table
whole
bands
established
the
9 residues
thermolysin
NT.
of the
NT,
100 mg of pepsin,
it to contain
as that
two
5 residues
amino-terminal
purified
showed
was
that
patterns,
was
analysis was
procedures,
it evident
electrophoretic
Peptide
residue,
(Table
contains
RESEARCH
(4).
These
NTT
presumed
to be the
1, Part
were
is known
pepsin
pepsin.
results).
diagonal
in both
diagonal
aminoethylated
unpublished
AT -A6
the
on a purified
and
residues,
below
assumed
was
BIOPHYSICAL
heating
crystalline
were
AND
during
found
commercial
PT-PI0
The
BIOCHEMICAL
amides
of Edman
degradation
to be:
Ile-Gly-Asp-Glu-
NT2 were
1. 2. 3. 4.
-0.47
o.094
NT2-1
NT2-2
:
(9
f&d
Orange
Red
Red
-
(S)
Red
Red
- Ninhydrin Color
Orange
Orange
Cadmium
1.00
1.07
in Edman degradation. peptide is considered
1.08
Glu 2.04
Amino
1.22
Asp 1.97
Characteristics of Region of Pepsin
The electrophoretic mobilities are relative to that of Asp ( = -1 .O). The sign (S) designates that color development was slow. the number of residues removed The numbers after the - sign indicate the Slight mobility is associated with an asparagine amino terminus;
-0.69
Degradation3
NT,-3
Edman
-0.38
-0.84
-0.73
in pH 6.5’ 2nd Dim.
-1.05
from
-1.05
Electr. Mobility 1st Dim.
NT,-2
Peptides
NT2
NT’
NT
Peptide
I
Amino Acid Composition and Peptides from Amino-Terminal
TABLE
neutral.
-
1.00
1.10 -
GIY 1.00
Composition mtio)
Pro 1.01
Acid (molar
-
0.96
Ile 0.98
1.01
-
Leu 1.18
0.70
-
TY~ 0.96
Vol.
41,
No.
3, 1970
Discussion: porcine first
Peptide pepsin,
contains aligned, respective
in the
peptide and
more
zymogens. portion
Perlmann
of pepsinogen
(14)
is a Glu-lie Glu-Val
amino
terminus
of the
difference
hydrolysis
of an X-Gly of pepsin
that
The
However, bond
and
two rennin
the
residues
Pepsin:
-Ala-Glu m-m -
which
in proteolysis
very
1 2 3 456789 Ile-Gly-Asp-Glu-Pro-Leu-Glu-Asn-Tyrt m-w -mm ---
two
2.
activation
is a closely
is accompanied
The
9
finding sites
10 -
by since
on the
11 -
--
Homology in amino acid sequence of the amino-terminal regions in The solid underlines indicate bovine rennin (5) and porcine pepsin. the residues which are identical; the broken underlines indicate the residues whose difference could be the result of a single-step mutation. The numbering of amino acid residues, in both cases, starts at the amino terminus of the enzymes. The two residues on the left of amino terminus of pepsin ( -Ala-Glu) are the last two residues in the portion of 41 residues which are cleaved off during the activation of pepsinogen (14) -
702
that
residues
Activation Cleavage in Zymogen
Fig.
amino-
activation
during
surprising
8 -
last
in rennin
similar.
7 -
the
the
41 in pepsinagen).
of pro-rennin
are
for
residues
during
the
is broken
a somewhat
with
homologous
into
40 and
(6)
of
It is interesting
sites
position
activation away,
2.
the
extends
bond
Activation Cleavage in Zymogen I 1 2 3 4 5 6 Gly-Glu-Val-Ala-Ser-Val-Pro-Leu-Thr-Asn-Tyr---------
Rennin:
in Fig.
in cleavage
corresponding the
a homology
residue
peptide
residues
by Stepanov
when
homology
COMMUNICATIONS
9 amino-terminal reported
at the
the
RESEARCH
established,
( -Ala-Glu,
bond.
bond.
now
that
as shown
However,
showed
with
the
clear,
of pepsinagen
analogous
specificities
(5) becomes
as a result
from
agrees
9 residues
residues
BIOPHYSICAL
derived
of NT with
evidently
of the
Ong
sequence
of rennin two
AND
is apparently
However,
sequence
rennin
NT
The
5 residues.
terminal
are
BIOCHEMICAL
the B-chain
BIOCHEMICAL
Vol. 41, No. 3,197O
of oxidized tical. the
Were bonds
limited the
insulin
alternative hydrolyzed
for
the
specificity
pro-rennin
hydrolyzed
during
conformation
zymogen
zymogens
may
of the requires
activation, On
be independent
thus
producing
when
one
the
presence
(17,
18),
of
cleavage
sites
would
other
hand,
it seems
hydrolytic change
an internal
considers
of no preformed
iden-
the
by
second,
nearly hydrolysis
two
of pepsinogen and
are for
of be
5,
(16)
responsible
be triggered
in the activation enzyme
the
might
plausible
Glu-lie
rennin
site
a pK of about
and rennin
(15)
and
of the zymogen.
is especially bond
pepsin
of pepsin
of a specific
with
by
activity
above
of these
of a group
are
hydrolytic
Cleavage
the
and
the
activation
enzymes.
This
the
discussed by
state
that
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
that
be
possible
that
activities of the
of the
ionization
rearrangement other
factors:
is relatively
of bonds. first,
that
unfavorable
the activation
of pepsinogen
enzyme.
Acknowledgement: The author wishes to thank Professor Institute, II, Univenity of Copenhagen, for the helpful of facilities during the course of this work.
Bent Foltmann, discussions and
for
Genetic the use
REFERENCES
(1) (2) (3) (4) (5) (6)
(12) (13) (14) (15)
(16) (17)
(18)
Butler, P.J.G., Harris, J.I ., Hartley, B. S., and Leberman, R., 112 : 679 (1969). mmann, 8. and Hartley, B.S., Biochem. J ., 104 : 1064 (1967). Huang, W.Y.,and Tang, J., J. Biol. Chem., 245: 2189 (1970). Tang, J. and Hartley, B.S., Biochem. J., 1183611 (1970). Trans. Roy. Sot. LondorB 257 : 147 (1970). Foltmann, B., Phil.
Biochem.,
Stepanov, V.M., Abstr. Fed. Europ. Biochem. Sot., 5th Meeting, No. 1089, (1968). Brown, J. R. and Hartley, B.S., Biochem. J., 101 : 214 (1966). Tang, J. and Hartley, B.S., Biochem. J., 102793 (1967). Gray, W.R., Methods in Enzymology, Vol .x p. 469, Ed. Hirs, C.H .W., N.Y. Acad. Press, Inc. (1967). Woods, K.R. and Wang, K.T., Biochim. Biophys. Acta, 133 : 369 (1967). Ambler, R. P., Methods in Enzymology, Vol. II, p. 417,x by Hirs, C.H.W., N.Y. Acad. Press, Inc. (1967). Dopheide, T.A.A ., Moore, S., and Stein, W.H., J. Biol . Chem., -242 : 1833 (1967). Rajagopalan, T.G., Stein, W.H ., and Moore, S., J. Biol. Chem., 241 : 4940 (1966). Ong, E.B. and Perlmann, G.E., J. Biol. Chem., 243 : 6104 (1968). Sanger, F. and Tuppy, H., Biochem. J., 49 : 481 (11). Foltmann, B., Compt. Rend. Trav. Lab. Czlsberg, 35 : 143 (1966). Tang, J., Nature, 199: 1094 (1963). 7 Fruton, J.S., Symposium on Structure and Function Relationships of Proteolytic Enzymes, p. 222, Ed. Desnuelle, P., Neurath, H. and Ottesen, M., Munksgaard, Copenhagen, Denmark (1970). 703
J.,
41,
No.
BIOCHEMICAL
3, 1970
AMINO
ACID
AND
SEQUENCE OF
BIOPHYSICAL
NEAR
Received
September
Institute, Copenhagen,
A
IN0
COMMUNICATIONS
TERMINUS
r
PEPSIN
Jordan Genetic
THE
PORCINE
RESEARCH
Tong2
Deportment Copenhagen,
II,
University Denmark
of
29, 1970
Summary: The amino acid sequence near the amino terminus of porcine pepsin wos By diogonal electrophoresis (l), a peptide was isolated containing 9 residues studied. from the amino terminus of pepsin. Structural studies established their sequence to be Ile-Gly-Asp-Glu-Pro-Leu-Glu-Asn-Tyr. Comparison of this amino-terminal sequence with thot known for rennin showed a definite homology. Alignment of the homologous residues revealed that the sites at which the respective rymogens ore cleaved to form active pepsin and rennin are 2 residues apart. The implications of this finding in the mechanism of activation of zymogens of the acidic proteases ore discussed. The
existence
pepsin,
rennin,
enzymes pepsin
and
descended and
denced to the
of o structural
bovine
gastricsin from
common
is now
a common
rennin,
by comparison
the
of partial
homology
sequence
Asp-Glu-Pro enzyme
‘This
(6).
was
well
ancestral
shared
are
amino
acid
elsewhere
The
partially
disparity
from
during
closely
homologous
in these
by
NIH
evolution.
Porcine
in structure,
as evi-
two
enzymes
are completely
surprising
one
by hydrolysis’of
AM-01
(4). the
In contrast first
dissimilar.
in pepsin
when
Grant
these
however,
whereas
including
Apparently,
molecules,
Research
proteases,
their
in the
(5),
zymogen
3).
protease
sequences
is especially
gastric
(2,
of pepsin and rennin
its respective
supported
certain
established
is Gly-Glu-Val-Ala-Ser
is activated
work
among
in particular,
residues from the amino tennini rennin,
homology
5
In
it is Ile-Gly-
considers
that
each
a peptide
bond
to
107.
n
‘Recipient Oklahoma Oklahoma
of NIH Career Development Medical Research Foundation, City, Oklahoma 73104.
Award 5 K04-AM-38638. University of Oklahoma
697
Permanent Medical
address: Center,
Vol.
41,
No.
3, 1970
form
a new
amino
near
the
amino
limited
terminus tennini
terminus it was
felt
rennin
would
amino
acid
phoresis below)
that
prove
Louis,
Japan.
to a much
One
to be more
RESEARCH
would
thus
homologous,
near
COMMUNICATIONS
expect
the
sequences
as a reflection
(1) was
isolation
Subtilisin
was
Other
because
purchased
purchased used
from
Novo
were
of the
5 residues
of
the
from
sequence
for
with
already
that
to establish
of pepsin.
pepsin
was
chemicals
undertaken
amino-terminal
Crystalline
Thermolysin
in pepsin
terminus
adopted
of specific
Methods:
were
amino
of only
amino-terminal
sequence
studies the
a sequence
longer
of a longer
et al.
MO.
Denmark.
BIOPHYSICAL
enzyme.
enzymes
revealing,
sequence
and
active
has identified
comparison
of Butler
Materials
on pepsin
as opposed
permit
AND
change.
work
(6),
in the
of these
evolutionary Previous
St.
BIOCHEMICAL
The
rennin
amino
(5).
Since
known
in further
method
techniques
the
,for
detail
of diagonal
involved
the electro-
(described
peptides. was
obtained
from
Daiwa
from Kaseai
Terapeutisk highest
Sigma
Chemical
K. C.
Co.,
Laboratorium, purity
Co., Osaka,
Copenhagen,
purchased
from
commercial
sources. The
amino
groups and
on the
protein
groups
of lysine
aminoethyl
maleyl
derivatives
excess
of maleic
anhydride
powder
protein,
and
cystein)
pH was
maintained
according
the
Within
10 minutes
against
0.05
carried
out
at room
M NH40H, by adding
N-ethylmorpholine
(such
to the
were
method was added between
temperature, the
protein
buffer,
amino-terminal
was
with
maleic
of Butler
et al.
(1).
in small 8 and
pH
portions
9 by the was
lyophilized.
to 8.0,
group
reacted
maleylation
1 mg of subtilisin acetate
as the
Thirty
incubating
E-amino
to form
times
molar
to a 1% solution addition
After
mixture
powder.
dialysis
digestion
protein the
of
of Na2C03
subtilisin
100 mg of maleylated and
the
anhydride
complete. The
and
was
in 5 ml of 0.2 for
16 hours
at 370%. Detailed described
procedures (7,
8).
After
in diagonal proteolysis
electrophoresis and
first-dimensional
698
were
performed electrophoresis,
as previously the
masking
M
Vol.
41,
No. 3,197O
maleyl
group
peptides
was
in the
accomplished pH
BIOCHEMICAL
3.5,
formed
2nd-dimensional
18 hours
Edman
identified
by
the
residue
produced
a pattern
(Fig. NT.This
of pepsin,
as judged
which
above
from
or near
to be lysine-containing
electrophoretic
to the
COMMUNICATIONS
mobility
Removal
was The
vapor
of the
of the maleyl
of a pyridine
involved
group
acetate
was buffer,
A)
peptide
peptides
the
line
were
of the
determined
newly by thin-
residues
of maleyl
major
in the
of the from
digest
spot
to have
change
derived
acids
Carboxyl-terminal
subtilisin
was assumed
neutral
by determination
amino
(10).
in which
its mobility the
dansyl
out
were
(11).
of the
1, Part
carried
sheets
digestion
electrophoresis
lay
(9).
carboxypeptidase
peptide
strips
on polyamide
Diagonal
was
paper
degradation
Results:
line
the
RESEARCH
(1).
sequential
chromatography
BIOPHYSICAL
electrophoresis.
at 60’
amino-terminal
layer
thus altering
by exposing for
The
removed,
AND
second
laying
derived two
porcine off
from
the
dimensions. dimension
carboxyl-terminal
the
region
diagonal
amino The
(L,-L9)
pepsin
terminus
peptide were
of the
assumed molecule
1 10
0 -0
10
20
:, w
30
I 20
CM. FROM Fig.
1.
ORIGIN,
1 st
DIMENSION
Diagrams of pH 6.5 diagonal electrophoresis subtilisin digest of porcine pepsin (A) and fmgment derived from the amino-terminal aminoethylated porcine pepsin (B).
699
I
10
spots
of demaleylated and a cyanogen bromide half of reduced and
Vol.
41,
No.
(12).
3, 1970
Deamidation
spots
that
appeared
(PI-Plo) that
were
sites.
To confirm
were
performed
reduced
was
line.
Numerous
near
the
diagonal
line.
Since
this
derived
(Fig,
analysis,
maleylation fragment
from
the
B).
again
Only
traces
peptides
CB2,
which
containing
from
peptides
these
as the
maior
P, -P4
aminoethyl
cleavage
were
160 (Tang,
laying
off
present.
cystein,
of
about
molecule
spot
autolytic
experiments
contained pepsin
peptide
showed
sites,
bromide
of the
of peptides
(13)
electrophoresis
cyanagen
emerged
few
intensity
et al.
produced
by
half
the
of minor
cleavage
diagonal
produced
for
Rajagopolan autolytic
and
Fragment
NT
spots
peptides
amino-terminal
Peptide
COMMUNICATIONS
to be responsible
many
amino-terminal
obviously
experiments
diagonal
of pepsin.
made
amino
acid Ile,
NT
the
same
digested
Tyr.
Peptide
NT
37”
C for
18 hours
gave
contained
portion the
4 residues,
determined
by the I).
Thus,
Pro-Leu-Glu-Asn-Tyr
peptide
was with
the
mobility the
had
of peptide
sequence
contained
with
and
sequence
peptide must
from
of the
have
the
Peptides
the sequence
peptides
of peptide
only
maior
from
the
with
protein.
The
of which
on paper
I).
By using
the
at different NT
.
700
was
established
of
12.5%.
residue of SO:1
at pH 6.5.
and
and
the
from dansyl
Peptide acids
at
Peptide
derived
degradation
The steps
yield
ratio
to be Ile-Giy-Afp-Gb-Pro. * Le,v-G$-Afn-Txr.
terminus
carboxyl-terminal
apparently
Edman
amino
present
Its amino-terminal
electrophoresis Ile,
peptide
a molar
at a substrate-enzyme
an amino-terminal
sequence
derived
(Table
whole
bands
established
the
9 residues
thermolysin
NT.
of the
NT,
100 mg of pepsin,
it to contain
as that
two
5 residues
amino-terminal
purified
showed
was
that
patterns,
was
analysis was
procedures,
it evident
electrophoretic
Peptide
residue,
(Table
contains
RESEARCH
(4).
These
NTT
presumed
to be the
1, Part
were
is known
pepsin
pepsin.
results).
diagonal
in both
diagonal
aminoethylated
unpublished
AT -A6
the
on a purified
and
residues,
below
assumed
was
BIOPHYSICAL
heating
crystalline
were
AND
during
found
commercial
PT-PI0
The
BIOCHEMICAL
amides
of Edman
degradation
to be:
Ile-Gly-Asp-Glu-
NT2 were
1. 2. 3. 4.
-0.47
o.094
NT2-1
NT2-2
:
(9
f&d
Orange
Red
Red
-
(S)
Red
Red
- Ninhydrin Color
Orange
Orange
Cadmium
1.00
1.07
in Edman degradation. peptide is considered
1.08
Glu 2.04
Amino
1.22
Asp 1.97
Characteristics of Region of Pepsin
The electrophoretic mobilities are relative to that of Asp ( = -1 .O). The sign (S) designates that color development was slow. the number of residues removed The numbers after the - sign indicate the Slight mobility is associated with an asparagine amino terminus;
-0.69
Degradation3
NT,-3
Edman
-0.38
-0.84
-0.73
in pH 6.5’ 2nd Dim.
-1.05
from
-1.05
Electr. Mobility 1st Dim.
NT,-2
Peptides
NT2
NT’
NT
Peptide
I
Amino Acid Composition and Peptides from Amino-Terminal
TABLE
neutral.
-
1.00
1.10 -
GIY 1.00
Composition mtio)
Pro 1.01
Acid (molar
-
0.96
Ile 0.98
1.01
-
Leu 1.18
0.70
-
TY~ 0.96
Vol.
41,
No.
3, 1970
Discussion: porcine first
Peptide pepsin,
contains aligned, respective
in the
peptide and
more
zymogens. portion
Perlmann
of pepsinogen
(14)
is a Glu-lie Glu-Val
amino
terminus
of the
difference
hydrolysis
of an X-Gly of pepsin
that
The
However, bond
and
two rennin
the
residues
Pepsin:
-Ala-Glu m-m -
which
in proteolysis
very
1 2 3 456789 Ile-Gly-Asp-Glu-Pro-Leu-Glu-Asn-Tyrt m-w -mm ---
two
2.
activation
is a closely
is accompanied
The
9
finding sites
10 -
by since
on the
11 -
--
Homology in amino acid sequence of the amino-terminal regions in The solid underlines indicate bovine rennin (5) and porcine pepsin. the residues which are identical; the broken underlines indicate the residues whose difference could be the result of a single-step mutation. The numbering of amino acid residues, in both cases, starts at the amino terminus of the enzymes. The two residues on the left of amino terminus of pepsin ( -Ala-Glu) are the last two residues in the portion of 41 residues which are cleaved off during the activation of pepsinogen (14) -
702
that
residues
Activation Cleavage in Zymogen
Fig.
amino-
activation
during
surprising
8 -
last
in rennin
similar.
7 -
the
the
41 in pepsinagen).
of pro-rennin
are
for
residues
during
the
is broken
a somewhat
with
homologous
into
40 and
(6)
of
It is interesting
sites
position
activation away,
2.
the
extends
bond
Activation Cleavage in Zymogen I 1 2 3 4 5 6 Gly-Glu-Val-Ala-Ser-Val-Pro-Leu-Thr-Asn-Tyr---------
Rennin:
in Fig.
in cleavage
corresponding the
a homology
residue
peptide
residues
by Stepanov
when
homology
COMMUNICATIONS
9 amino-terminal reported
at the
the
RESEARCH
established,
( -Ala-Glu,
bond.
bond.
now
that
as shown
However,
showed
with
the
clear,
of pepsinagen
analogous
specificities
(5) becomes
as a result
from
agrees
9 residues
residues
BIOPHYSICAL
derived
of NT with
evidently
of the
Ong
sequence
of rennin two
AND
is apparently
However,
sequence
rennin
NT
The
5 residues.
terminal
are
BIOCHEMICAL
the B-chain
BIOCHEMICAL
Vol. 41, No. 3,197O
of oxidized tical. the
Were bonds
limited the
insulin
alternative hydrolyzed
for
the
specificity
pro-rennin
hydrolyzed
during
conformation
zymogen
zymogens
may
of the requires
activation, On
be independent
thus
producing
when
one
the
presence
(17,
18),
of
cleavage
sites
would
other
hand,
it seems
hydrolytic change
an internal
considers
of no preformed
iden-
the
by
second,
nearly hydrolysis
two
of pepsinogen and
are for
of be
5,
(16)
responsible
be triggered
in the activation enzyme
the
might
plausible
Glu-lie
rennin
site
a pK of about
and rennin
(15)
and
of the zymogen.
is especially bond
pepsin
of pepsin
of a specific
with
by
activity
above
of these
of a group
are
hydrolytic
Cleavage
the
and
the
activation
enzymes.
This
the
discussed by
state
that
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
that
be
possible
that
activities of the
of the
ionization
rearrangement other
factors:
is relatively
of bonds. first,
that
unfavorable
the activation
of pepsinogen
enzyme.
Acknowledgement: The author wishes to thank Professor Institute, II, Univenity of Copenhagen, for the helpful of facilities during the course of this work.
Bent Foltmann, discussions and
for
Genetic the use
REFERENCES
(1) (2) (3) (4) (5) (6)
(12) (13) (14) (15)
(16) (17)
(18)
Butler, P.J.G., Harris, J.I ., Hartley, B. S., and Leberman, R., 112 : 679 (1969). mmann, 8. and Hartley, B.S., Biochem. J ., 104 : 1064 (1967). Huang, W.Y.,and Tang, J., J. Biol. Chem., 245: 2189 (1970). Tang, J. and Hartley, B.S., Biochem. J., 1183611 (1970). Trans. Roy. Sot. LondorB 257 : 147 (1970). Foltmann, B., Phil.
Biochem.,
Stepanov, V.M., Abstr. Fed. Europ. Biochem. Sot., 5th Meeting, No. 1089, (1968). Brown, J. R. and Hartley, B.S., Biochem. J., 101 : 214 (1966). Tang, J. and Hartley, B.S., Biochem. J., 102793 (1967). Gray, W.R., Methods in Enzymology, Vol .x p. 469, Ed. Hirs, C.H .W., N.Y. Acad. Press, Inc. (1967). Woods, K.R. and Wang, K.T., Biochim. Biophys. Acta, 133 : 369 (1967). Ambler, R. P., Methods in Enzymology, Vol. II, p. 417,x by Hirs, C.H.W., N.Y. Acad. Press, Inc. (1967). Dopheide, T.A.A ., Moore, S., and Stein, W.H., J. Biol . Chem., -242 : 1833 (1967). Rajagopalan, T.G., Stein, W.H ., and Moore, S., J. Biol. Chem., 241 : 4940 (1966). Ong, E.B. and Perlmann, G.E., J. Biol. Chem., 243 : 6104 (1968). Sanger, F. and Tuppy, H., Biochem. J., 49 : 481 (11). Foltmann, B., Compt. Rend. Trav. Lab. Czlsberg, 35 : 143 (1966). Tang, J., Nature, 199: 1094 (1963). 7 Fruton, J.S., Symposium on Structure and Function Relationships of Proteolytic Enzymes, p. 222, Ed. Desnuelle, P., Neurath, H. and Ottesen, M., Munksgaard, Copenhagen, Denmark (1970). 703
J.,