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Purification and some properties of autoprothrombin II-A: An anticoagulant perhaps also related to fibrinolysis
THROMBOSIS Printed
RESEARCH in the United
PURIFICATION
AND
AN ANTICOAGULANT Walter
SOME
I, pp. 443-460, 1372 Vol. Pergamon Press, Inc.
States
PROPERTIES
PERHAPS
ALSO
H. Seegers, Lowell Nobuo Sakuragawa,
OF AUTOPROTHROMBIN RELATED
TO
II-A:
FIBRINOLYSIS
E, McCoy, Hans D, Groben, and B. B. L. Agrawal
Department of Physiology, Thrombosis Specialized Center of Research, Wayne State University School of Medicine, Detroit, Michigan, U.S.A. [Received
8.8.1.972.
Accepted
by
Editor
L.
Vroman)
ABSTRACT Methods were developed for the assay and isolation of autoprothrombin II-A. The purified protein retarded blood coagulation in vitro as well as in vivo and induced fibrinolysis. It is tentatively concluded that the protein originated from prothrombin and possessed inhibitor-activator qualities respectively as anticoagulant and fibrinolytic agent. To obtain Auto II-A, concentrated prothrombin complex was digested with purified thrombin. Chromatography on a DEAE-cellulose column separated prethrombin, Auto II-A, and autoprothrombin III (Factor X1. The inhibitor-activator was then purified by using a Sephadex G-100 or G-100 superfine column. A single component was indicated by polyacrylamide gel electrophoresis and by ultracentrifugation. The equation for S;O w was 3.9 + 0.0114X. Isoelectric point = pH 3.9. It is a competitivd inhibitor of autoprothrombin C (Factor Xa). N-terminal amino acids were Ile and Gly. An amino acid analysis was compared with a new amino acid analysis of purified prothrombin. The latter had 518 amino acid residues per mole. The protein contained sialic acid, neutral sugars, and amino sugars. Serum from rabbits immunized with purified prothrombin crossreacted with purified Auto II-A. A working theory is proposed as follows: Thrombin functions in a negative feedback system which retards thrombin formation due to the production of prethrombin and Auto II-A. Platelet factor 3 also produced prethrombin and Auto II-A. This feedback system could be the molecular basis of latent coagulation and fibrinolysis. In accelerated coagula, tion, the latent coagulation sequences are by-passed with massive formation of fibrin. This investigation was supported by research grants HE-03424-15 and HE-14142-01 from the National Heart and Lung Institute, National Institutes of Health, U. S. Public Health Service. Hans D. Groben received a grant from the Deutsche Forschungsgemeinschaft, Bonn-Bad Godesberg, West Germany. Support was also given by the McGregor Fund, Detroit, Michigan,
444
AUTOPROTHROMBIN
In 1960, by Mammen,
Thomas,
and developed thrombin.
a previously
unrecognized
and Seegers
when purified
Under similar
(1).
conditions,
itor or autoprothrombin
II.
Later,
Seegers
It proved to be a competitive
conditions
In this paper, we describe
inhibition
either the inhib-
(2) fractionated
the activated
of autoprothrombin
In addition
by further work,
and fibrinolysis
of the inhib-
C (Factor X,1,
under which thrombin activity
generated
of autoprothrombin
to being an anticoagulant,
in blood samples from dog and man.
of coagulation
for obtaining
our work on the purification
of the product.
induced remains to be determined
generated,
column and obtained a concentrate (3,4)
II-A
with purified
II (Factor IX) activity
satisfactorily
inhibitor
to retard several
duced mild fibrinolysis
was found
was called autoprothrombin
and Marciniak
prothrombin complex on a DEAE-cellulose
and some of the properties
of blood coagulation
autoprothrombin
5
Vol.l,No.
prothrombin complex was digested at pH 7.9
to control conditions
thus functioned
inhibitor
The activity
but it was not possible
itor.
II-A
How the fibrinolysis
but tentatively
and (5).
II-A it inwas
it can be assumed that
was due to the same substance and that it was
derived from prothrombin.
METHODS Purified
by methods devised
(81, and sedimented
in this laboratory.
(8) were also according
gel electrophoresis cellulose
MATERIALS
bovine prothrombin complex (61, purified thrombin (71, purified prothrom-
bin (61, purified Ac-globulin
AC-globulin
AND
followed
was Whatman
Assays
amino acid analysis
microgranular,
preswollen
Fine Chemicals,
cellulose.
and 72 hours and for threonine,
serine,
instrumentation.
half-cystine,
Hydrolysis
methionine
to zero was made to correct for loss during hydrolysis,
hydrolysis
values were used.
method of Duggan and Udenfriend
made to contain
0.1
Sephadex
(13).
was determined N-terminal
A stock solution
mg protein per ml.
DEAEproducts
and the column effluents
trapolation
Tryptophan
and
Poiyacrylamide
with an LKB Uvicord II, recording at 280
was by chromatography
by the methods of Edman (14).
prothrombin (111,
procedures as adapted to our needs (12).
and columns were obtained from Pharmacia were monitored automatically
for thrombin (101,
(9) were obtained
to the methods of this laboratory.
described
DE-52
brain thromboplastin
nm. Quantitative was for 24,48,
and tyrosine,
an ex-
Otherwise,
22 hour
by the spectrophotofluorometric
amino acid analyses
were performed
of purified soybean trypsin inhibitor
The product was from Worthington
Biochemical
was _
AUTOPROTHROMBIN
Vol.l,No.5
For ihe ultracentrifuge was dissolved
work,
in 0.1
Phosphate
the Spinco
M potassium
buffers
we list the composition
were
analytical
chloride
reagents
445
instrument
was used,
The
protein
at pH 7.2.
made from stock
of stock
II-A
reagent
solutions
and then the buffers
Reagent
A:
One M dipotassium
Reagent
B:
One M potassium
Reagent
C:
One M sodium
hydrogen
to be at pH 7.0.
made from these
First
solutions:
phosphate
dihydrogen
phosphate
chloride
Buffer
1:
50
ml A +
50
ml B; 1.0
M phosphate
Buffer
2:
50
ml A +
50
ml B + water
Buffer
3:
50
ml A +
50
ml B +
140
ml C + water
to 2 liters;
0.07
M NaCl
Buffer
4:
50
ml A +
50
ml B +
260
ml C + water
to 2 liters;
0.13
M NaCl
Buffer
5:
50
ml A +
50
ml B +
360
ml C + water
to 2 liters;
0.18
M NaCl
Buffer
6:
50
ml A +
50
ml B +
800
ml C + water
to 2 liters;
0.40
M NaCl
to 2 liters;
CHROMATOGRAPHY PROTHROMBIN The column A stock
preparation
A sufficient layer
used was
was removed
COMPLEX 2.5
was
poured
and replaced About
Then
applied
outflow.
#2 was again
This
the buffer
complex
ml were
until
and in water thrombin
as described a million
solution at 37’
to the DEAE-cellulose
DEAE-CELLULOSE was done in a cold room (3 to 8’ C), with After
required
overnight
M phosphate
settling #l
until
buffer
to 20-25 at pH 7.0.
the effluent
of the inflow
operation.
and the column
#2.
cm,
the top
This
buffer
was
pH 7.0.
equaled
that of the
The flow was stopped
was now ready
when
for application
below.
units
of prothrombin,
(110-120
ml),
were
C and at pH 7.0. column.
0.05
buffer
the conductivity
the cellulose,
ml) of purified applied
300
had just entered
Approximately
Work
M phosphate
ACTIVATED
1 M phosphate
a convenient
prepared
cm.
into the column.
was usually
of the material
ON
was mixed
with
was at room temperature. buffer
x 20
of DEAE-cellulose
quantity
OF
0.05
in the form of purified mixed After
with 90
50,000
minutes,
prothrombin units
(in 2-3
tile mixture
was
446
AU'~OPl~O'I'IllIOMl3IN II-A
At 4’ C in the cold room, the activated lulose,
As soon as it went in, 0.05
nitrogen pressure. less,
absorbance
prothrombin was poured on top of the cel-
M phosphate buffer #2 was applied
This force was used throughout,
the buffer was changed to #3.
under 10 psi
When the absorbance
This eluted the prethrombin (Fig.
was again less than 0.1,
1).
was 0.1
or
When the
the buffer was changed to 44 and, in like manner,
to buffers 5 and 6.
The latter eluted inhibitor
column work usually
required 4-5
tions were used for special
Vol.l,No.5
hours.
and autoprothrombin
III respectively.
The prethrombin and autoprothrombin
The
III frac-
purposes.
+.07M+."M
FIG.
TUBE NUMBER
The inhibitor do this,
Prothrombin complex activated with thrombin and chromatographed on a DEAE-cellulose column. At pH 7.0 the prethrombin, inhibitor, and autoprothrombin III were eluted respectively with 0.07, 0.18 and 0.4 M sodium chloride in phosphate buffer, Cold room.
(I9 ML PER TUBE)
fraction was prepared for fractionation
we worked under cold conditions
solution.
The precipitate
dissolved
in a small volume of water.
was collected
night before precipitation,
and added 0.4
Sometimes
OF INHIBITOR
BY SEPHADEX G-100
ward flow at an approximate bonate at pH 7.8 applied.
to 8.0.
lnert material
in a refrigerated
the inhibitor
the dissolved
column.
To
per ml
centrifuge
and
fraction was frozen over-
ammonium sulfate
precipitate
was
days before further fractionation.
PURIFICATION
A Sephadex
on a Sephadex
gm ammonium sulfate
by centrifugation
and sometimes
stored frozen for several
1
column 2.5
FILTRATION
x 183
rate of 25 ml/l-u. The inhibitor
(Fraction
cm was used at 20 to 25’ C with upThe buffer was 0.1
from the DEAE-cellulose
1) appeared first,
later more inert protein was obtained
(Fig.
FRACTION
2).
followed
M ammonium bicarfractionation
by the desired
work was
inhibitor,
and
AUTOPROTHROMBIN
Vol.l,No.5
II-A
447
2
n
E 0.30 1
-=f
300
200
n
INHIBITOR
400
EFFLUENT
VOLUME
a
EFFLUENT
VOLUME
(ml)
(ml) FIG. Fig. 2.5
2
FIG.
2. Purification of autoprothrombin II-A on Sephadex G-100 x 183 cm. Center peak corresponds to active material.
Fig. 3. Purification of autoprothrombin II-A on Sephadex column 2.5 x 95 cm. Center peak represents inhibitor.
We also ward ties
flow
itated
rate was
with
frozen
Amicon
ml/hr
frozen
Diaflo
filter
without
About
41%
fraction.
derived
used.
and studied
and dialyzed
latter
were
We were
the amount
However,
unable
The up-
and other
procedure.
the salt.
Some
by dialysis
main
we precippreparations
with
to dry the product
proper-
The
Sometimes
was the most efficient
to the Sephadex
was about
column
protein
yield
prothrombin
3.770.
We could
no way has been devised quite
different
in the original
we did determine
column.
cm.
the
for preservfrom the
loss of activity.
applied
because
away
procedure
in the purified
activity
x 95
ways.
concentrated
mg of prothrombin fraction
2.5
superfine
activities
in various
the average
could
to the Sephadex
The specific
For 9 preparations,
if it is something
thrombin.
and a column
column
G-100
to be the same for either
and pH,
complete
of the precursor not assay
3).
Others
This
volume
in the active
of inhibitor
(Fig.
sulfate
of the protein
from 590
yield
combined
apparatus.
almost
superfine
appeared
ammonium
controlling
state
hibitor
or less II-A
were
with
G-100
and subsequently
ing activity,
yield
15
activity
the protein
were
tein
used Sephadex
of the autoprothrombin
fractions
3
The average
was in the purified
was
complex;
mixture
to measure
hence,
was 80%
specific
was 30,000
This
was
the pro-
the overall the concentration
Furthermore,
because
that the recovery activity
mg.
not calculate
from prothrombin.
activation
22.4
in-
we
it contained
of the activity u/mg
proapplied
protein.
1148
A1J1‘01’1~OT111~OM1~TN 1-T-A
Without
exception,
a small amount of thrombin remained
this was troublesome,
in some experiments
ample,
chemical
in the physical
a reaction
of autoprothrombin
mixture consisting
brain thromboplastin, thromboplastin
C (41,
Although
significance
as, for cx-
or the assay procedure.
To measure its effects
of the following:
purified Ac-globulin,
forms autoprothrombin
purified
in just adequate
quantitatively,
we devised
prothrombin complex,
and calcium chloride.
sedimented
In this mixture,
of thromboplastin
and Ac-globulin,
converts
By design, the reagents were put
amounts to convert a given amount of prothrombin (1000
Under those conditions,
with the function of autoprothrombin
the
C from the prothrombin complex and this autopro-
the prothrombin of the prothrombin complex to thrombin.
to thrombin.
5
PROCEDURES
thrombin C, with “help” of the lipoprotein
together
1 ,No.
II-A inhibits the formation of thrombin because it is a competi-
Autoprothrombin tive inhibitor
in the preparations.
it was of negligible
measurements
ASSAY
Vol.
there is a sensitive C.
The following
units)
response to any interference
standard activation
mixture was
arranged: Prothrombin complex (Prothrombin 2000
0.5
ml
Sedimented brain thromboplastin (5 mg/ml)
0.1
ml
Ac-globulin
0.1
ml
Sample or control
0.2
ml
Calcium chloride (0.1 M) in imidazole buffer, pH 7.2
0.1
ml
This reaction
purified
u/ml)
(2150
mixture was kept for 20 minutes at 37’
sample was taken for thrombin analysis. all the prothrombin being converted to the reaction
As the amount of inhibitor
creased.
Consequently,
The activation
to thrombin (Fig.
mixture in small quantity,
reduced.
of inhibitor
u/ml)
4).
C.
Every 5 minutes,
was complete
in 20 minutes with
By adding autoprothrombin
was increased,
mixture (Fig.
II-A
the rate of thrombin formation and its yield was the yield of thrombin was further de-
the reduced thrombin yield proved to be a reflection
in the reaction
a
4).
of the amount
5
Vol.l,No.
I
AUTOPROTHROMBIN
449
II-A
FIG.
CYTROL
4
Standard reaction mixture, top curve, contained prothrombin complex, tissue thromboplastin, purified Ac-globulin, and 0.01 M calcium chloride at pH 7.2 and 37’ C. Maximum lllrombin yield was
IO
ACTIVATION
ZD
TIME
The relationships concentrations, possible. formation
h4lh!)
are projected
the yield
We defined
reduced progressively in proportion to the amount of inhibitor added; namely, 0.02, 0.04, etc. mg/ml. Note approach to equilibrium in 20 minutes.
of thrombin
2 units
in another was easily
of inhibitor
of 1 unit of thrombin
way by means reduced,
as the amount
in the range
of 50%
of Figure
but a complete which
substrate
REWCTION OF THROMBIN YIELD WITH INHIBITOR
would
In low
block
was not
stop or prevent
(prothrombin)
FIG.
5.
the
inhibition.
5
Reduction in thrombin yield by autoprothrombin II-A when added to standard prothrombin activation mixture e Compare with Fig. 4. Approach to equilibrium at 5, 10, and 20 minutes as indicated by 3 curves. ’ ’ ’ ’ ’ O/Z345 PROTEIN CONCENTRATION (mg /mU 0
As an example, Fig.
4,
mixture.
0.04
The calculation
The
respective
ber,
dilution
a little nonlinear
numbers in mixture
This
relationship.
range
in thrombin if the first
preparation amount
was then refer
to:
1000
Usually yield. one failed,
-
was diluted
the reduction factor
a second
by 500
5 times
thrombin
to make the dilutions
experience,
yield
x 2 x 5 x 1 =
In case
an interpolation
we tried With
500
the thrombin
concentration,
dilution.
units,
reduced
of inhibitor
substrate
and original
more or less than 500
unit reduction within
mg curve).
a certain
(of
in the reaction
5000 yield,
u/ml
sample.
definition
in thrombin
was used.
units
This
num-
yield
was
involved
so that there was a 500 analysis,
if required,
fell
a
4 50
ATJTOPl?OTllROMl~TN
INHIBITED
CLOTTING
To study the effect of the inhibitor thrombelastograph, prothrombin II-A 0.2
ml blood.
TT-A
AND
62,000
on blood coagulation
Within
with the use of the
A selected
u/ml and 3 u/ml thrombin.
This began to clot almost at once (Fig.
rigid as that of the control.
‘,
FIBRINOLYSIS
we mixed dog blood with the inhibitor, contained
I,No.
Vol.
6).
1 hour and 30 minutes,
solution
To 0.1
of auto-
ml, we added
The clot never became as the clot had lysed completely.
__.._-c---------__~_
3
FIG. 6 Thrombelastogram of dog blood. Curve #1 was control. Curve #2 highest concentration of autoprothrombin II-A added to dog blood. Curve #3 one-fifth the quantity of autoprothrombin II-A as compared with curve #2. Inhibitor preparation contained small amount of thrombin.
By taking one-fifth cuvette. lysed.
the amount of inhibitor,
There was very little Thus,
of concentrations,
preparation,
Evidently,
there would have been no clotting
thrombin in order to demonstrate obtained;
of having thrombin in the preparation
that the autoprothrombin
and induces fibrinolysis.
however,
lysis.
we found,
II-A is an inhibitor of
if there had been no thrombin in the and it would have been necessary
to add
With the use of human blood, the same result was This latter result is in accord-
with rabbit blood no lysis followed.
ance with the fact that it is difficult
u/ml in the
and that small amount of fibrin which formed was
working with the difficulty
by proper selection coagulation
clotting
the thrombin was reduced to 0.2
to induce substantial
fibrinolysis
in the blood of
rabbits e Next,
we wanted to see whether the inhibition
lysis might also occur in vivo.
To obtain information
of clotting and induction on this point, we selected
of fibrinoa 12 kg
AUTOPROTHROMBIYN II-A
Vol.l,No.5
He was given
male clog as test animal. devices slowly
for blood infused
preparations,
heart
respiration,
over a period 56
Throughout
pressure,
of 18
mg of inhibitor
the experiment,
rate or blood
sodium
were
which
pentobarbital
and heart
minutes
with
anesthesia.
rate were
in 18
5 hours,
Recording
attached.
use of an infusion
dissolved
lasted
451
The pump.
ml physiological
there were
From saline
no effects
the infusion,
the infusion
the beginning firm as with some fibrin
the control; after
the infusion.
with
the recorded
hours after
dency
sample
7).
slope
control
it was
182
OF was studied
characteristics
for protein
in about
12 minutes.
progressively minutes
after
concentration
PURIFIED
were
there were After
was
12
was clotted
the use of a Spinco
quite
312
than taken in accord
mg% and 4 l/2 in the values
the infusion,
a bleeding
pressure
measuring
tensites.
II-A
Model
component
was positive,
were
hours
by add-
sample
no differences
AUTOPROTHROMBIN
dependence
clot was not as
but even after
times
and blood
that of a single
The
the first
concentration
at the infusion
71, we observed
in the thrombelastograph
clotting
analysis.
5 min-
(Fig.
the infusion
as with
Lee-White
mg% while
with
weaker,
less amplitude
fibrinogen
by the two-stage
from the wounds
The preparation
The
The
with
7
The next one was drawn
the thrombelastograph
but not as extensive!y
Our observations results.
30
produced
was observed,
PROPERTIES
sedimentation
drawn
The clot
measured
The
and became
A sample
was observed
was taken.
sample
the infusion,
for prothrombin
sample
of the latter
remained. (Fig.
a blood
With
the control
lysis
solution,
Thrombelastogram of blood taken from doy given Intravenous infusion of autoprothrombin II-A. Curve #1, top left, was control and is incompletely shown. Curve #2 blood sample 5 minutes after infusion. Curve #3 blood sample 30 minutes after infusion and clotted by adding thrombin. Center and bottom recordings are continuations of #2 and #3.
was completed.
of clotting
ing thrombin
three
pressure.
‘20
utes after
was
on respiration,
FIG.
Before
inhibitor
with
E ultracentrifuge. (Fig.
8).
the equation
being
452
AUTOPROTHROMBIN
FIG.
II-A
Vol.l,No.5
8
Ultracentrifuge schlieren patterns of autoprothrombin II-A at 8.0 mg/ml in 0.1 M potassium chloride at pH 7.0 and at a rotor speed of 59,780 rpm. Time in minutes given on each frame. Sedimentation from left to right.
$0 w =
3.9
+ 0.0114X
(Fig.
It is interesting
tratidn in mg/ml. centration
dependence
slope (151,
described
in an accompanying
9).
In this equation,
that 3.7s
X stands for protein concen-
thrombin also had a positive
and the same was true for the prothrombin preparation
article.
FIG.
s
0
5 M/ML.
/o
15
In our amino acid analysis with an analysis All indications
of prothrombin,
20
work, we were especially
for amino acid analysis, namely,
3800
interested
in a comparison
because the latter might be the precursor of the inhibitor
are in favor of that conclusion,
paper, an element of reservation
laboratory;
9
Concentration dependence of sedimentation constants of autoprothrombin II-A in 0.1 M potassium chloride and a rotor speed of 59,780 rpm.
40
g 3.5 (/, 3.0
protein con-
but even with the work presented
needs to be maintained.
had the highest specific u/mg dry weight.
activity
in this
Our prothrombin sample,
used
of any prepared to date in this
ATJTOPl~OTW?OMBIN II-A
Vol.l,No.5
TABLE Amino
Acid
Composition
1 of Bovine
and Autoprothrombin
Amino
Lysine Histidine Arginine Aspartic acid Threonine Serine Glutamic acid Proline Glycine Alanine Half-cystine Valine Methionine Isoleucine Leucine T yros i ne Phenylalanine Tryptophan NH3
(4.94) (1.80) (8.79) (9.66) (4.27) (4.66) (13.15) (4.82) (4.18) (3.59) (3.06) (5.11) (1.10) (2.87) (6.82) (3.82) (3.62) (3.61)
1.30
(1.46)
66.28
TOTAL
**
4.86 1.55 4.88 6.45 2.86 2.85 9.83 2.97 2,85 2.28 2.84 4.41 1.05 2.94 4.62 2.79 3.25 1.70
Figures Ratio
each
of appearance
of two separate
we found acids
518
alone.
imately
(91.42)
in parentheses
Our analysis
represent
of prothrombin hydrolyses. acid
of the molecular
appearance
and used a multiple
either
or insufficient
extra
acid,
numbers
a molecular
amino
sugars
weight
Based
amino
(24) (9) (38) (55) (27) (31) (68) (32) (42) (31) (19) (33) (6) (17) (40) (16) (17) (13)
424
357
(518)
weight
from duplicates
value
of 59,744
sugars
amounted
on several
acid for calculating
than acceptable
for
range for prothrombin
One less or an additional acids
29 8 24 42 20 23 51 22 32 22 20 32 6 19 30 13 17 8
;: 17 20 48 19 27 18 17 27 5 16 25 11 14 7
an average
and neutral
of prothrombin.
of amino
24 7
prothrombin.
molecular
giving
of 6 residues.
(32) (12) (50) (73) (36) (41) (89) (42) (56) (40) (25) (44) (8) (22) (52) (21) (22) (18)
prothrombin.
1) represents
as the reference
Residues RA x 5** RA x 6**
(683)
for purified
In the accepted
weight
we took methionine
496
6 for purified
(Table
residues,
sialic
33 10 28 48 24 27 67 26 38 26 24 38 7 22 35 15 20 8
(86.3)
analysis with
Residues per 105 gm
(4.0) (1.5) (6.4) (9.2) (4.5) (5.2) (11.3) (5.3) (7.0) (5.1) (3.2) (5.5) (1.0) (2.8) (6.6) (2.7) (2.8) (2.2)
70.7
x 5 or 6,
The total
10%
culations,
amino
4.7 1.4 4.0 6.9 3.4 3.9 9.5 3.7 5.4 3.6 3.4 5.3 1.0 3.2 5.0 2.2 2.8 1.3
Prothrombin
II-A
Ratio of Appearance
% Recovery
Acid*
453
for amino to approx-
exploratory
cal-
each
of
ratio
one involved
for the molecular
454
AUTOPROTHROMBIN
weight-of
prothrombin.
Additionally,
after treatment with bromcyanogen chain occurs at the methionine and thus, by this analysis,
II-A
Vol.l,No.5
we made a preliminary under conditions
where cleavage
residue of the sequence.
we can also conclude
estimate
of fragment numbers of the poiypeptide
There appeared to be 7 fragments
that there are 6 methionine
residues
in
prothrombin. When we assumed that the inhibitor evident
might have 6 methionine
that it could not be derived from prothrombin.
discarded to 357
in a degradation
process,
and the corresponding
our stated assumption
no lysine discarded Thr, Ser,
molecular
weight was 41,305
There is no evidence
and only a little histidine.
Glu, Pro, Gly, Ala,
however,
it was
that one was
our figure for total amino acid residues was reduced
as a working hypothesis,
rived from prothrombin.
Assuming,
residues,
and Leu (Table
for amino acids only.
the inhibitor
could theoretically
to the contrary.
With
be de-
It follows that there was
The main alterations
were with Arg, Asp,
11, each one being removed in substantial
amounts o In the N-terminal preparation
amino acid analysis,
for more extensive
sugars in proportions
isoleucine
work, we found sialic
found in prothrombin.
and glycine were found.
acid,
neutral sugars,
In
and amino
We hope to extend this work on carbohydrates
and present a report.
FIG.
10
Polyacrylamide gel electrophoresis of autoprothrombin II-A with 15.0 and 7.5 pg applied. Photograph at 20 minutes.
In the analysis ug of material material together,
by polyacrylamide
above the gel.
gel electrophoresis,
we applied
We observed mainly a single band (Fig.
was also studied and usually and just distinguishable.
7.5
10).
Freeze-dried
there were two bands of the same size, Likewise,
and 15.0
when we studied the freeze-dried
close protein
AUTOPROTMROMRIN
Vol.l,No.5
by I~licrozonal
ccllulosc
acchlc
there was a second
component
an isoelectric
of 3.9,
point
clcclrophorcsis with
!I55
(plrosplinLc
an isoelectric
and we presume
TI-A
buffers,
point of 5.8.
this corresponds
strcngLIi
ionic
0.04),
The main component to the isoelectric
hacl
point
of
the inhibitor. Our immunological
work
is considered
the use of rabbits,
we made an antibody
thrombin
according
to the procedures
inhibitor
cross-reacted
tation
band between
identity
with
investigation with
with
these
tests
is planned,
which
(6).
antiserum
Ouchtertony
(Fig.
11).
With
chromatographed
pro-
There
There
to thank
study.
plates
were
used.
was a single
The
precipi-
was a band of immunological
of the prothrombin-antiserum
and we wish
are being
only an introductory
DEAE-cellulose
and the antiserum.
one of the components of this
to twice
described
the rabbit
the inhibitor
as being
Glenn
interaction. R. Van
Further
Noord for his help
continued.
FIG.
11
Ouchterlony plates. Center contained full-strength rabbit prothrombin antiserum. Well #l prothrombin at 16.7 mg/ml. #4 prothrombin at 8.5 mg/ml . #2 and #6 autoprothrombin II-A at 0.5 mg/ml. #3 and #5 autoprothrombin 11-A at 0.25 mg/ml. Photograph at 48 hours.
DISCUSSION Autoprothrombin presented that
the first
it might
sive, Another
II-A
description
be an agent
are consistent possibility
one non-prothrombin
was first
with
which
found
in 1960
of its purification induces
(1);
and have obtained
fibrinolysis.
The facts
the idea that an inhibitor-activator
is that there precursor
however,
are two non-prothrombin for the two activities.
we believe the first
presented,
is derived precursors
we have
indication if not conclu-
from prothrombin.
for each activity
or
456
AUTOPROTHROMBIN
PROTHROMBIN
II-A
Vol.l,No.5
COMPLEX
PRETHkXtBlN AN
AlJTOPf?OTHROMBlN
III
co ions Tissue Eatmct Plotekt Foctol ,3 Plosmo Focta R Other Factors
1 ;-,$$~in* Co ions*
I
AUTOPROTHROMBIN + Peptide
??
I
C
JOLYSIN
THROMBIN + Peptidc Is)
??These occclemtei Autopmthmbin C alone is sufficknt . *In voriis sequences ond combinotiis. **Nomad AutopFothromMn II-A; pmbobly on8 molecule with two disttnct activities.
FIG.
12
Possible molecular basis for holding blood coagulation at level of latent coagulation and fibrinolysis through a negative feedback system. Under conditions favoring formation of large amounts of autoprothrombin C, prothrombin conversion to thrombin would occur, without the formation of much prethrombin or autoprothrombin II-A. A dependence of fibrinolysis on the prothrombin system does not conflict with other pathways for fibrinolysis.
By adopting a conservative interesting
interpretation
ideas can be developed
and staying nearest the facts,
as avenues for further experimental
Small amounts of thrombin are not readily
removed by antithrombin
amounts of thrombin arise in our circulation,
the high affinity
as prothrombin (17);
be for thrombin formation to be retarded. hibitor of autoprothrombin The induced fibrinolysis of fibrinolysis minogen). dimension
11-A (Fig.
or possibly
the concept of latent coagulation
added which is outlined
in terms of molecular
12).
in-
for that reason also. The acceleration
of profibrinolysin
and fibrinolysis mechanics.
Prethrom.
is a competitive
in the removal of fibrin. by direct activation
When small
the tendency would
II-A
C, thrombin formation would be inhibited
could be indirect
In this way,
III(16).
therefore,
Since autoprothrombin
would be operational
exploration.
for prothrombin would re-
sult in the formation of prethrombin as well as autoprothrombin bin does not form thrombin as readily
some
(plas-
has another
This is essentially
considered
a negative
its own formation
feedback
system,
and to lyse the first
In case of perceptible autoprothrombin
C would
of prothrombin
to thrombin
18).
Autoprothrombin
the fibrinogen
when
often
Whenever thrombin
II-A
in 1939
when
complex
form fibrin,
mentioned,
fact that platelets, autoprothrombin
II-A
when
for the fact that platelet extensive ops,
intravascular
accelerated
coagulation.
deals
with
lated
factor
phenomena
In many respects, and extrinsic
or compartmentalization
for
that autopro-
was historically
(15,
to a prothrombin
has frequently
Most
interesting
and platelet complex.
can be infused
II-A
coagulation, and is subsumed
producing devel-
is to function
to explore
or latent
because
form
activity
membranes
is more meaningful
is the
that accounts
without
be useful
been
membranes
Possibly
3 and platelet
noticed
state
20).
It might
first
thrombin
into the imperceptible this
coagu-
thus accounting
we can assume
refractory
platelets
intravascular
It may be that autoprothrombin
of platelet
coagulation
it was shown
and that more arises anticoagulants
thrombin
3 or “lysed”
physiologi-
coagulation.
purified
prothrombin
of
further
aspects
and
than the division that arbitrary
of
division
by the idea of latent
and
coagulation,
Recently plasma
to purified
(15, Mosl
Under
fibrinolysis,
membranes,
than as a procoagulant.
into intrinsic
anatomy
accelerated
effect
rather
of blood
coagulation
added
red cell
coagulation,
the division
blood
3,
added
laboratory
of
quantities
conditions.
not lyse.
develops,
the two-stage
from this
factor
factor
and thus the initial
as an anticoagulant
that time,
induce
(19)
amounts
of appreciable
disseminated
the inhibitor
and Smith
in papers
platelet
state
large
under those
intravascular
refractory
is to retard
play a role in autocatalysis
with
would
disseminated
Seegers,
but mostly
would
not form extensively
that perspective,
Since
relatively
the conversion
Thrombin
11-A formation
From
preparation.
force
of thrombin
that might appear,
formation,
be a time associated
follows
Mertz,
fibrin
effect
and in a test tube it would
the two-stage
forms.
the initial
strands
would
12).
would
autoprothrombin
the fact that lysis
fibrin
This
(Fig.
there would
because
or massive
form.
II-A
would
cal conditions, lation
1-I 57
AUTOPROTIIROMBIN Tl--A
Vol.l,No.5
II-A
when
Since
use of purified
prothrombin
Although
metabolically
from plasma.
its function
(21).
that much two-stage
derived
direct
and quantitative
under physiological
synthesis
conditions.
the formation methods,
thrombin
is stopped
proof is lacking,
from the prothrombin
we have demonstrated
proteins
refractory
this
complex
zymogen
with could
we can attempt
Such a substance
Coumadin
or re-
be due to autopro-
as the latter
of autoprothrombin
is in
disappears
II-A
to accurately
with
the
imagine
has been postulated
by
458
AUTOPROTHROMBIN
still another approach by Hemker, kinetic
study,
deficiency. synthesis
they postulated
Veltkamp,
There is only limited due to complications
refractory
On the basis of a
inhibitor arises
They believed
in plasma in vitamin K
that vitamin K deficiency
or nonidentity
information
of autoprothrombin
II-A
to make advances
based on degradation
(23-25)
on that account.
Additionally,
and that is presumably
beyond the point of maximum inhibitor
producing autoprothrombin
II-A
C produces the two-stage
refractory
activity.
state,
destruction
Multiple
For instance,
ways of when puri-
one cannot be certain The courage to
reduce these problems is bound to be rewarded and perhaps with practical is known to function as a lytic agent (26) and esterase (27,
II-A
of the protein,
due to inhibitor
magnify chances for confusion.
shown to produce lysis in blood vessels
and pivka.
the two-stage
whether this is a direct effect or whether thrombin is first produced.
Thrombin
induced
on the maximum yi.eld of autoprothrombin
such as the formation of prethrombin and the lability
state is reversed
fied autoprothrombin
(22).
Was it derived from prothrombin ? That question remains as well as
many others regarding the identity
It will be difficult
Vol.l,No.5
and Loeliger
that a competitive
This was called pivka. of pivka.
II-A
applications.
thrombin also has been
28).
REFERENCES 1.
MAMMEN, E.F., THOMAS, W.R., and SEEGERS, W.H. Activation of purified prothrombin to autoprothrombin I or autoprothrombin II (platelet cofactor II) or autoprothrombin II-A. Thromb. Diath. Haemorrh.: 5, 218, 1960. =
2.
SEEGERS, prethrombin
3.
SEEGERS, W.H., HEENE, D.L., and MARCINIAK, E. Activation of purified Purification of autoprothrombin C. prothrombin in ammonium sulfate solutions: Thromb. Diath. Haemorrh.: 15, 1, 1966,
4.
MARCINIAK, E., MURANO, G., and SEEGERS, W.H. Inhibitor of blood clotting derived from prothrombin, Thromb. Diath. Haemorrh.: =18, 161, 1967.
5.
MARCINIAI<, 1970.
6.
MCCOY, L .E. mci SEEGERS, W .H. and purified prothrombin, Thrombosis
7.
SEEGERS, W.H., MCCOY, L., KIPFER, R.K., and MURANO, G. Preparation and properties of thrombin. Arch. Biochem. Biophys.: 128, 194, 1968.
W .H, and MARCINIAK, subunit of prothrombin.
E.
Coagulation
E. Some activation Life Sci.: 2, 1721,
inhibitor
elicited
characteristics 1965.
by thrombin.
Science:
of the
170,
452,
Preparation of bovine prothrombin complex Res, =I , 40 I, 197:~.
Vol.l,No. 5
AUTOPROTHROMBIN
3. ‘DOMBROSE,
F.A., YASUI, T., ROUBAL, W .H, Ac-globulin (factor V): Preparation Biochem.: In press.
9.
II-A
453
Z., ROUBAL, A., and SEEGERS, of a practical product. Preparative
HECHT, E.R., CHO, M.H., and SEEGERS, W.H. ture and preparation of protein-free material different activator. Amer. J. Physiol.: 193, 584, 1958.
Thromboplastin: Nomenclafrom platelet factor 3 or lipid
10,
SEEGERS, W .H . and SMITH, H.P. Factors fied thrombin. Amer. J. Physiol.: 137, 348,
11.
WARE, A.G. determination 1949.
12.
SEEGERS, W.H., MCCOY, L.E., REUTERBY, J., SAKURAGAWA, N., MURANO, G., and AGRAWAL, B.B.L. Further observations on the purification and properties of autoprothrombin III (factor X1. Thrombosis Res .: 1, 209, = 1972.
13.
S . The spectrophotofluorometric DUGGAN, D.E. and UDENFRIEND, tion of tryptophan in plasma and of tryptophan and tyrosine in protein J. Biol. Chem.: 223, 313, 1956.
14.
EDMAN, P. Sequence S .B. Needleman (Ed.)
and SEEGERS, of prothrombin
which influence 1942.
the activity
of puri-
W .H. Two-stage procedure for the quantitative concentration. Amer. J. Clin. Path.: 2, 471,
determinations. In: Berlin-Heidelberg-New
determinahydrolysates.
Protein Sequence Determinations. York: Springer-Verlag, 1970,
p. 211. 15.
SEEGERS,
W .H.
Prothrombin.
Cambridge:
Harvard
University
Press,
1962.
16.
DOMBROSE, F.A., SEEGERS, W.H., and SEDENSKY, J.A. Antithrombin: Inhibition of thrombin and autoprothrombin C (F-Xa) as a mutual depletion system, Thromb. Diath. Haemorrh.: 26, 103, 1971. =
17.
SEEGERS, W.H., DOMBROSE, F.A. and autoprothrombin
18.
SEEGERS, Three basic
19.
MERTZ, E.T., SEEGERS, W.H., and SMITH, by purified thrombin solutions. Proc. Sot. Exp.
20.
SEEGERS, W.H., MURANO, G., and MCCOY, thrombin during activation: A theory. Thromb.
21.
OUYANG, C., SEEGERS, W.H., MCCOY, L.E., and MiLLER-BERGHAUS, Metabolic formation of a prothrombin derivative. Thromb. Diath. Haemorrh.: 332, 1971.
SAKURAGAWA, N., MCCOY, L.E., SEDENSKY, J.A., and Prothrombin activation: Ac-globulin, lipid, platelet membrane, C (factor X,1 requirements. Thrombosis Res.: In press.
W.H., MCCOY, reactions. Clin.
L., and MARCINIAK, E. Chem.: 14, 97, 1968. = H.P. Biol.
Blood-clotting
Inactivation Med.: 4&
L. Structural Diath. Haemorrh
enzymology:
of prothrombin 657, 1939.
changes in pro.: 23, 26, 1970. i G. 25, _
h6c-l
.A~JTC)l’R0Tlll?OMIITN
TT-A
Vol.l,No.5
22.
H.EMI
23.
WARE, A.G. and SEEGERS, W.H. tivation with thrombin, and activation Chem.: 174, 565, 1948.
24.
SEEGERS, W.H., ANDREWS, E.B., and McCLAUGHRY, R.I. Formation prothrombin derivatives from purified prothrombin. Amer. J. Physiol.: 164, 1951.
25.
CHO, M.H. and SEEGERS, Exp. Biol. Med.: z, 642,
26.
BRAMBEL, C.E. 68, 67, 1957.
27.
BROERSMA, R.J., MCCOY, L.E., and SEEGERS, W.H. Production of microvascular thrombosis and lysis with acetylated thrombin. Thromb. Diath. Haemorrh. Suppl.: 47, 353, 1971. -=
28.
MCCOY, L.E., GRISCOM, H.A., imental fibrinolysis with acetylated 47, 339, 1971.
Proteases
W.H. 1958.
Studies on prothrombin: Purification, inacwith thromboplastin and calcium. J, Biol y
Prothrombin
in the clotting
DIEKAMP, thrombin.
activation
mechanism.
cycle.
Proc.
of 722,
Sot.
Ann. N. Y. Acad.
Sci.:
U., and SEEGERS, W.H. ExperThromb. Diath. Haemorrh. Suppl.:
RESEARCH in the United
PURIFICATION
AND
AN ANTICOAGULANT Walter
SOME
I, pp. 443-460, 1372 Vol. Pergamon Press, Inc.
States
PROPERTIES
PERHAPS
ALSO
H. Seegers, Lowell Nobuo Sakuragawa,
OF AUTOPROTHROMBIN RELATED
TO
II-A:
FIBRINOLYSIS
E, McCoy, Hans D, Groben, and B. B. L. Agrawal
Department of Physiology, Thrombosis Specialized Center of Research, Wayne State University School of Medicine, Detroit, Michigan, U.S.A. [Received
8.8.1.972.
Accepted
by
Editor
L.
Vroman)
ABSTRACT Methods were developed for the assay and isolation of autoprothrombin II-A. The purified protein retarded blood coagulation in vitro as well as in vivo and induced fibrinolysis. It is tentatively concluded that the protein originated from prothrombin and possessed inhibitor-activator qualities respectively as anticoagulant and fibrinolytic agent. To obtain Auto II-A, concentrated prothrombin complex was digested with purified thrombin. Chromatography on a DEAE-cellulose column separated prethrombin, Auto II-A, and autoprothrombin III (Factor X1. The inhibitor-activator was then purified by using a Sephadex G-100 or G-100 superfine column. A single component was indicated by polyacrylamide gel electrophoresis and by ultracentrifugation. The equation for S;O w was 3.9 + 0.0114X. Isoelectric point = pH 3.9. It is a competitivd inhibitor of autoprothrombin C (Factor Xa). N-terminal amino acids were Ile and Gly. An amino acid analysis was compared with a new amino acid analysis of purified prothrombin. The latter had 518 amino acid residues per mole. The protein contained sialic acid, neutral sugars, and amino sugars. Serum from rabbits immunized with purified prothrombin crossreacted with purified Auto II-A. A working theory is proposed as follows: Thrombin functions in a negative feedback system which retards thrombin formation due to the production of prethrombin and Auto II-A. Platelet factor 3 also produced prethrombin and Auto II-A. This feedback system could be the molecular basis of latent coagulation and fibrinolysis. In accelerated coagula, tion, the latent coagulation sequences are by-passed with massive formation of fibrin. This investigation was supported by research grants HE-03424-15 and HE-14142-01 from the National Heart and Lung Institute, National Institutes of Health, U. S. Public Health Service. Hans D. Groben received a grant from the Deutsche Forschungsgemeinschaft, Bonn-Bad Godesberg, West Germany. Support was also given by the McGregor Fund, Detroit, Michigan,
444
AUTOPROTHROMBIN
In 1960, by Mammen,
Thomas,
and developed thrombin.
a previously
unrecognized
and Seegers
when purified
Under similar
(1).
conditions,
itor or autoprothrombin
II.
Later,
Seegers
It proved to be a competitive
conditions
In this paper, we describe
inhibition
either the inhib-
(2) fractionated
the activated
of autoprothrombin
In addition
by further work,
and fibrinolysis
of the inhib-
C (Factor X,1,
under which thrombin activity
generated
of autoprothrombin
to being an anticoagulant,
in blood samples from dog and man.
of coagulation
for obtaining
our work on the purification
of the product.
induced remains to be determined
generated,
column and obtained a concentrate (3,4)
II-A
with purified
II (Factor IX) activity
satisfactorily
inhibitor
to retard several
duced mild fibrinolysis
was found
was called autoprothrombin
and Marciniak
prothrombin complex on a DEAE-cellulose
and some of the properties
of blood coagulation
autoprothrombin
5
Vol.l,No.
prothrombin complex was digested at pH 7.9
to control conditions
thus functioned
inhibitor
The activity
but it was not possible
itor.
II-A
How the fibrinolysis
but tentatively
and (5).
II-A it inwas
it can be assumed that
was due to the same substance and that it was
derived from prothrombin.
METHODS Purified
by methods devised
(81, and sedimented
in this laboratory.
(8) were also according
gel electrophoresis cellulose
MATERIALS
bovine prothrombin complex (61, purified thrombin (71, purified prothrom-
bin (61, purified Ac-globulin
AC-globulin
AND
followed
was Whatman
Assays
amino acid analysis
microgranular,
preswollen
Fine Chemicals,
cellulose.
and 72 hours and for threonine,
serine,
instrumentation.
half-cystine,
Hydrolysis
methionine
to zero was made to correct for loss during hydrolysis,
hydrolysis
values were used.
method of Duggan and Udenfriend
made to contain
0.1
Sephadex
(13).
was determined N-terminal
A stock solution
mg protein per ml.
DEAEproducts
and the column effluents
trapolation
Tryptophan
and
Poiyacrylamide
with an LKB Uvicord II, recording at 280
was by chromatography
by the methods of Edman (14).
prothrombin (111,
procedures as adapted to our needs (12).
and columns were obtained from Pharmacia were monitored automatically
for thrombin (101,
(9) were obtained
to the methods of this laboratory.
described
DE-52
brain thromboplastin
nm. Quantitative was for 24,48,
and tyrosine,
an ex-
Otherwise,
22 hour
by the spectrophotofluorometric
amino acid analyses
were performed
of purified soybean trypsin inhibitor
The product was from Worthington
Biochemical
was _
AUTOPROTHROMBIN
Vol.l,No.5
For ihe ultracentrifuge was dissolved
work,
in 0.1
Phosphate
the Spinco
M potassium
buffers
we list the composition
were
analytical
chloride
reagents
445
instrument
was used,
The
protein
at pH 7.2.
made from stock
of stock
II-A
reagent
solutions
and then the buffers
Reagent
A:
One M dipotassium
Reagent
B:
One M potassium
Reagent
C:
One M sodium
hydrogen
to be at pH 7.0.
made from these
First
solutions:
phosphate
dihydrogen
phosphate
chloride
Buffer
1:
50
ml A +
50
ml B; 1.0
M phosphate
Buffer
2:
50
ml A +
50
ml B + water
Buffer
3:
50
ml A +
50
ml B +
140
ml C + water
to 2 liters;
0.07
M NaCl
Buffer
4:
50
ml A +
50
ml B +
260
ml C + water
to 2 liters;
0.13
M NaCl
Buffer
5:
50
ml A +
50
ml B +
360
ml C + water
to 2 liters;
0.18
M NaCl
Buffer
6:
50
ml A +
50
ml B +
800
ml C + water
to 2 liters;
0.40
M NaCl
to 2 liters;
CHROMATOGRAPHY PROTHROMBIN The column A stock
preparation
A sufficient layer
used was
was removed
COMPLEX 2.5
was
poured
and replaced About
Then
applied
outflow.
#2 was again
This
the buffer
complex
ml were
until
and in water thrombin
as described a million
solution at 37’
to the DEAE-cellulose
DEAE-CELLULOSE was done in a cold room (3 to 8’ C), with After
required
overnight
M phosphate
settling #l
until
buffer
to 20-25 at pH 7.0.
the effluent
of the inflow
operation.
and the column
#2.
cm,
the top
This
buffer
was
pH 7.0.
equaled
that of the
The flow was stopped
was now ready
when
for application
below.
units
of prothrombin,
(110-120
ml),
were
C and at pH 7.0. column.
0.05
buffer
the conductivity
the cellulose,
ml) of purified applied
300
had just entered
Approximately
Work
M phosphate
ACTIVATED
1 M phosphate
a convenient
prepared
cm.
into the column.
was usually
of the material
ON
was mixed
with
was at room temperature. buffer
x 20
of DEAE-cellulose
quantity
OF
0.05
in the form of purified mixed After
with 90
50,000
minutes,
prothrombin units
(in 2-3
tile mixture
was
446
AU'~OPl~O'I'IllIOMl3IN II-A
At 4’ C in the cold room, the activated lulose,
As soon as it went in, 0.05
nitrogen pressure. less,
absorbance
prothrombin was poured on top of the cel-
M phosphate buffer #2 was applied
This force was used throughout,
the buffer was changed to #3.
under 10 psi
When the absorbance
This eluted the prethrombin (Fig.
was again less than 0.1,
1).
was 0.1
or
When the
the buffer was changed to 44 and, in like manner,
to buffers 5 and 6.
The latter eluted inhibitor
column work usually
required 4-5
tions were used for special
Vol.l,No.5
hours.
and autoprothrombin
III respectively.
The prethrombin and autoprothrombin
The
III frac-
purposes.
+.07M+."M
FIG.
TUBE NUMBER
The inhibitor do this,
Prothrombin complex activated with thrombin and chromatographed on a DEAE-cellulose column. At pH 7.0 the prethrombin, inhibitor, and autoprothrombin III were eluted respectively with 0.07, 0.18 and 0.4 M sodium chloride in phosphate buffer, Cold room.
(I9 ML PER TUBE)
fraction was prepared for fractionation
we worked under cold conditions
solution.
The precipitate
dissolved
in a small volume of water.
was collected
night before precipitation,
and added 0.4
Sometimes
OF INHIBITOR
BY SEPHADEX G-100
ward flow at an approximate bonate at pH 7.8 applied.
to 8.0.
lnert material
in a refrigerated
the inhibitor
the dissolved
column.
To
per ml
centrifuge
and
fraction was frozen over-
ammonium sulfate
precipitate
was
days before further fractionation.
PURIFICATION
A Sephadex
on a Sephadex
gm ammonium sulfate
by centrifugation
and sometimes
stored frozen for several
1
column 2.5
FILTRATION
x 183
rate of 25 ml/l-u. The inhibitor
(Fraction
cm was used at 20 to 25’ C with upThe buffer was 0.1
from the DEAE-cellulose
1) appeared first,
later more inert protein was obtained
(Fig.
FRACTION
2).
followed
M ammonium bicarfractionation
by the desired
work was
inhibitor,
and
AUTOPROTHROMBIN
Vol.l,No.5
II-A
447
2
n
E 0.30 1
-=f
300
200
n
INHIBITOR
400
EFFLUENT
VOLUME
a
EFFLUENT
VOLUME
(ml)
(ml) FIG. Fig. 2.5
2
FIG.
2. Purification of autoprothrombin II-A on Sephadex G-100 x 183 cm. Center peak corresponds to active material.
Fig. 3. Purification of autoprothrombin II-A on Sephadex column 2.5 x 95 cm. Center peak represents inhibitor.
We also ward ties
flow
itated
rate was
with
frozen
Amicon
ml/hr
frozen
Diaflo
filter
without
About
41%
fraction.
derived
used.
and studied
and dialyzed
latter
were
We were
the amount
However,
unable
The up-
and other
procedure.
the salt.
Some
by dialysis
main
we precippreparations
with
to dry the product
proper-
The
Sometimes
was the most efficient
to the Sephadex
was about
column
protein
yield
prothrombin
3.770.
We could
no way has been devised quite
different
in the original
we did determine
column.
cm.
the
for preservfrom the
loss of activity.
applied
because
away
procedure
in the purified
activity
x 95
ways.
concentrated
mg of prothrombin fraction
2.5
superfine
activities
in various
the average
could
to the Sephadex
The specific
For 9 preparations,
if it is something
thrombin.
and a column
column
G-100
to be the same for either
and pH,
complete
of the precursor not assay
3).
Others
This
volume
in the active
of inhibitor
(Fig.
sulfate
of the protein
from 590
yield
combined
apparatus.
almost
superfine
appeared
ammonium
controlling
state
hibitor
or less II-A
were
with
G-100
and subsequently
ing activity,
yield
15
activity
the protein
were
tein
used Sephadex
of the autoprothrombin
fractions
3
The average
was in the purified
was
complex;
mixture
to measure
hence,
was 80%
specific
was 30,000
This
was
the pro-
the overall the concentration
Furthermore,
because
that the recovery activity
mg.
not calculate
from prothrombin.
activation
22.4
in-
we
it contained
of the activity u/mg
proapplied
protein.
1148
A1J1‘01’1~OT111~OM1~TN 1-T-A
Without
exception,
a small amount of thrombin remained
this was troublesome,
in some experiments
ample,
chemical
in the physical
a reaction
of autoprothrombin
mixture consisting
brain thromboplastin, thromboplastin
C (41,
Although
significance
as, for cx-
or the assay procedure.
To measure its effects
of the following:
purified Ac-globulin,
forms autoprothrombin
purified
in just adequate
quantitatively,
we devised
prothrombin complex,
and calcium chloride.
sedimented
In this mixture,
of thromboplastin
and Ac-globulin,
converts
By design, the reagents were put
amounts to convert a given amount of prothrombin (1000
Under those conditions,
with the function of autoprothrombin
the
C from the prothrombin complex and this autopro-
the prothrombin of the prothrombin complex to thrombin.
to thrombin.
5
PROCEDURES
thrombin C, with “help” of the lipoprotein
together
1 ,No.
II-A inhibits the formation of thrombin because it is a competi-
Autoprothrombin tive inhibitor
in the preparations.
it was of negligible
measurements
ASSAY
Vol.
there is a sensitive C.
The following
units)
response to any interference
standard activation
mixture was
arranged: Prothrombin complex (Prothrombin 2000
0.5
ml
Sedimented brain thromboplastin (5 mg/ml)
0.1
ml
Ac-globulin
0.1
ml
Sample or control
0.2
ml
Calcium chloride (0.1 M) in imidazole buffer, pH 7.2
0.1
ml
This reaction
purified
u/ml)
(2150
mixture was kept for 20 minutes at 37’
sample was taken for thrombin analysis. all the prothrombin being converted to the reaction
As the amount of inhibitor
creased.
Consequently,
The activation
to thrombin (Fig.
mixture in small quantity,
reduced.
of inhibitor
u/ml)
4).
C.
Every 5 minutes,
was complete
in 20 minutes with
By adding autoprothrombin
was increased,
mixture (Fig.
II-A
the rate of thrombin formation and its yield was the yield of thrombin was further de-
the reduced thrombin yield proved to be a reflection
in the reaction
a
4).
of the amount
5
Vol.l,No.
I
AUTOPROTHROMBIN
449
II-A
FIG.
CYTROL
4
Standard reaction mixture, top curve, contained prothrombin complex, tissue thromboplastin, purified Ac-globulin, and 0.01 M calcium chloride at pH 7.2 and 37’ C. Maximum lllrombin yield was
IO
ACTIVATION
ZD
TIME
The relationships concentrations, possible. formation
h4lh!)
are projected
the yield
We defined
reduced progressively in proportion to the amount of inhibitor added; namely, 0.02, 0.04, etc. mg/ml. Note approach to equilibrium in 20 minutes.
of thrombin
2 units
in another was easily
of inhibitor
of 1 unit of thrombin
way by means reduced,
as the amount
in the range
of 50%
of Figure
but a complete which
substrate
REWCTION OF THROMBIN YIELD WITH INHIBITOR
would
In low
block
was not
stop or prevent
(prothrombin)
FIG.
5.
the
inhibition.
5
Reduction in thrombin yield by autoprothrombin II-A when added to standard prothrombin activation mixture e Compare with Fig. 4. Approach to equilibrium at 5, 10, and 20 minutes as indicated by 3 curves. ’ ’ ’ ’ ’ O/Z345 PROTEIN CONCENTRATION (mg /mU 0
As an example, Fig.
4,
mixture.
0.04
The calculation
The
respective
ber,
dilution
a little nonlinear
numbers in mixture
This
relationship.
range
in thrombin if the first
preparation amount
was then refer
to:
1000
Usually yield. one failed,
-
was diluted
the reduction factor
a second
by 500
5 times
thrombin
to make the dilutions
experience,
yield
x 2 x 5 x 1 =
In case
an interpolation
we tried With
500
the thrombin
concentration,
dilution.
units,
reduced
of inhibitor
substrate
and original
more or less than 500
unit reduction within
mg curve).
a certain
(of
in the reaction
5000 yield,
u/ml
sample.
definition
in thrombin
was used.
units
This
num-
yield
was
involved
so that there was a 500 analysis,
if required,
fell
a
4 50
ATJTOPl?OTllROMl~TN
INHIBITED
CLOTTING
To study the effect of the inhibitor thrombelastograph, prothrombin II-A 0.2
ml blood.
TT-A
AND
62,000
on blood coagulation
Within
with the use of the
A selected
u/ml and 3 u/ml thrombin.
This began to clot almost at once (Fig.
rigid as that of the control.
‘,
FIBRINOLYSIS
we mixed dog blood with the inhibitor, contained
I,No.
Vol.
6).
1 hour and 30 minutes,
solution
To 0.1
of auto-
ml, we added
The clot never became as the clot had lysed completely.
__.._-c---------__~_
3
FIG. 6 Thrombelastogram of dog blood. Curve #1 was control. Curve #2 highest concentration of autoprothrombin II-A added to dog blood. Curve #3 one-fifth the quantity of autoprothrombin II-A as compared with curve #2. Inhibitor preparation contained small amount of thrombin.
By taking one-fifth cuvette. lysed.
the amount of inhibitor,
There was very little Thus,
of concentrations,
preparation,
Evidently,
there would have been no clotting
thrombin in order to demonstrate obtained;
of having thrombin in the preparation
that the autoprothrombin
and induces fibrinolysis.
however,
lysis.
we found,
II-A is an inhibitor of
if there had been no thrombin in the and it would have been necessary
to add
With the use of human blood, the same result was This latter result is in accord-
with rabbit blood no lysis followed.
ance with the fact that it is difficult
u/ml in the
and that small amount of fibrin which formed was
working with the difficulty
by proper selection coagulation
clotting
the thrombin was reduced to 0.2
to induce substantial
fibrinolysis
in the blood of
rabbits e Next,
we wanted to see whether the inhibition
lysis might also occur in vivo.
To obtain information
of clotting and induction on this point, we selected
of fibrinoa 12 kg
AUTOPROTHROMBIYN II-A
Vol.l,No.5
He was given
male clog as test animal. devices slowly
for blood infused
preparations,
heart
respiration,
over a period 56
Throughout
pressure,
of 18
mg of inhibitor
the experiment,
rate or blood
sodium
were
which
pentobarbital
and heart
minutes
with
anesthesia.
rate were
in 18
5 hours,
Recording
attached.
use of an infusion
dissolved
lasted
451
The pump.
ml physiological
there were
From saline
no effects
the infusion,
the infusion
the beginning firm as with some fibrin
the control; after
the infusion.
with
the recorded
hours after
dency
sample
7).
slope
control
it was
182
OF was studied
characteristics
for protein
in about
12 minutes.
progressively minutes
after
concentration
PURIFIED
were
there were After
was
12
was clotted
the use of a Spinco
quite
312
than taken in accord
mg% and 4 l/2 in the values
the infusion,
a bleeding
pressure
measuring
tensites.
II-A
Model
component
was positive,
were
hours
by add-
sample
no differences
AUTOPROTHROMBIN
dependence
clot was not as
but even after
times
and blood
that of a single
The
the first
concentration
at the infusion
71, we observed
in the thrombelastograph
clotting
analysis.
5 min-
(Fig.
the infusion
as with
Lee-White
mg% while
with
weaker,
less amplitude
fibrinogen
by the two-stage
from the wounds
The preparation
The
The
with
7
The next one was drawn
the thrombelastograph
but not as extensive!y
Our observations results.
30
produced
was observed,
PROPERTIES
sedimentation
drawn
The clot
measured
The
and became
A sample
was observed
was taken.
sample
the infusion,
for prothrombin
sample
of the latter
remained. (Fig.
a blood
With
the control
lysis
solution,
Thrombelastogram of blood taken from doy given Intravenous infusion of autoprothrombin II-A. Curve #1, top left, was control and is incompletely shown. Curve #2 blood sample 5 minutes after infusion. Curve #3 blood sample 30 minutes after infusion and clotted by adding thrombin. Center and bottom recordings are continuations of #2 and #3.
was completed.
of clotting
ing thrombin
three
pressure.
‘20
utes after
was
on respiration,
FIG.
Before
inhibitor
with
E ultracentrifuge. (Fig.
8).
the equation
being
452
AUTOPROTHROMBIN
FIG.
II-A
Vol.l,No.5
8
Ultracentrifuge schlieren patterns of autoprothrombin II-A at 8.0 mg/ml in 0.1 M potassium chloride at pH 7.0 and at a rotor speed of 59,780 rpm. Time in minutes given on each frame. Sedimentation from left to right.
$0 w =
3.9
+ 0.0114X
(Fig.
It is interesting
tratidn in mg/ml. centration
dependence
slope (151,
described
in an accompanying
9).
In this equation,
that 3.7s
X stands for protein concen-
thrombin also had a positive
and the same was true for the prothrombin preparation
article.
FIG.
s
0
5 M/ML.
/o
15
In our amino acid analysis with an analysis All indications
of prothrombin,
20
work, we were especially
for amino acid analysis, namely,
3800
interested
in a comparison
because the latter might be the precursor of the inhibitor
are in favor of that conclusion,
paper, an element of reservation
laboratory;
9
Concentration dependence of sedimentation constants of autoprothrombin II-A in 0.1 M potassium chloride and a rotor speed of 59,780 rpm.
40
g 3.5 (/, 3.0
protein con-
but even with the work presented
needs to be maintained.
had the highest specific u/mg dry weight.
activity
in this
Our prothrombin sample,
used
of any prepared to date in this
ATJTOPl~OTW?OMBIN II-A
Vol.l,No.5
TABLE Amino
Acid
Composition
1 of Bovine
and Autoprothrombin
Amino
Lysine Histidine Arginine Aspartic acid Threonine Serine Glutamic acid Proline Glycine Alanine Half-cystine Valine Methionine Isoleucine Leucine T yros i ne Phenylalanine Tryptophan NH3
(4.94) (1.80) (8.79) (9.66) (4.27) (4.66) (13.15) (4.82) (4.18) (3.59) (3.06) (5.11) (1.10) (2.87) (6.82) (3.82) (3.62) (3.61)
1.30
(1.46)
66.28
TOTAL
**
4.86 1.55 4.88 6.45 2.86 2.85 9.83 2.97 2,85 2.28 2.84 4.41 1.05 2.94 4.62 2.79 3.25 1.70
Figures Ratio
each
of appearance
of two separate
we found acids
518
alone.
imately
(91.42)
in parentheses
Our analysis
represent
of prothrombin hydrolyses. acid
of the molecular
appearance
and used a multiple
either
or insufficient
extra
acid,
numbers
a molecular
amino
sugars
weight
Based
amino
(24) (9) (38) (55) (27) (31) (68) (32) (42) (31) (19) (33) (6) (17) (40) (16) (17) (13)
424
357
(518)
weight
from duplicates
value
of 59,744
sugars
amounted
on several
acid for calculating
than acceptable
for
range for prothrombin
One less or an additional acids
29 8 24 42 20 23 51 22 32 22 20 32 6 19 30 13 17 8
;: 17 20 48 19 27 18 17 27 5 16 25 11 14 7
an average
and neutral
of prothrombin.
of amino
24 7
prothrombin.
molecular
giving
of 6 residues.
(32) (12) (50) (73) (36) (41) (89) (42) (56) (40) (25) (44) (8) (22) (52) (21) (22) (18)
prothrombin.
1) represents
as the reference
Residues RA x 5** RA x 6**
(683)
for purified
In the accepted
weight
we took methionine
496
6 for purified
(Table
residues,
sialic
33 10 28 48 24 27 67 26 38 26 24 38 7 22 35 15 20 8
(86.3)
analysis with
Residues per 105 gm
(4.0) (1.5) (6.4) (9.2) (4.5) (5.2) (11.3) (5.3) (7.0) (5.1) (3.2) (5.5) (1.0) (2.8) (6.6) (2.7) (2.8) (2.2)
70.7
x 5 or 6,
The total
10%
culations,
amino
4.7 1.4 4.0 6.9 3.4 3.9 9.5 3.7 5.4 3.6 3.4 5.3 1.0 3.2 5.0 2.2 2.8 1.3
Prothrombin
II-A
Ratio of Appearance
% Recovery
Acid*
453
for amino to approx-
exploratory
cal-
each
of
ratio
one involved
for the molecular
454
AUTOPROTHROMBIN
weight-of
prothrombin.
Additionally,
after treatment with bromcyanogen chain occurs at the methionine and thus, by this analysis,
II-A
Vol.l,No.5
we made a preliminary under conditions
where cleavage
residue of the sequence.
we can also conclude
estimate
of fragment numbers of the poiypeptide
There appeared to be 7 fragments
that there are 6 methionine
residues
in
prothrombin. When we assumed that the inhibitor evident
might have 6 methionine
that it could not be derived from prothrombin.
discarded to 357
in a degradation
process,
and the corresponding
our stated assumption
no lysine discarded Thr, Ser,
molecular
weight was 41,305
There is no evidence
and only a little histidine.
Glu, Pro, Gly, Ala,
however,
it was
that one was
our figure for total amino acid residues was reduced
as a working hypothesis,
rived from prothrombin.
Assuming,
residues,
and Leu (Table
for amino acids only.
the inhibitor
could theoretically
to the contrary.
With
be de-
It follows that there was
The main alterations
were with Arg, Asp,
11, each one being removed in substantial
amounts o In the N-terminal preparation
amino acid analysis,
for more extensive
sugars in proportions
isoleucine
work, we found sialic
found in prothrombin.
and glycine were found.
acid,
neutral sugars,
In
and amino
We hope to extend this work on carbohydrates
and present a report.
FIG.
10
Polyacrylamide gel electrophoresis of autoprothrombin II-A with 15.0 and 7.5 pg applied. Photograph at 20 minutes.
In the analysis ug of material material together,
by polyacrylamide
above the gel.
gel electrophoresis,
we applied
We observed mainly a single band (Fig.
was also studied and usually and just distinguishable.
7.5
10).
Freeze-dried
there were two bands of the same size, Likewise,
and 15.0
when we studied the freeze-dried
close protein
AUTOPROTMROMRIN
Vol.l,No.5
by I~licrozonal
ccllulosc
acchlc
there was a second
component
an isoelectric
of 3.9,
point
clcclrophorcsis with
!I55
(plrosplinLc
an isoelectric
and we presume
TI-A
buffers,
point of 5.8.
this corresponds
strcngLIi
ionic
0.04),
The main component to the isoelectric
hacl
point
of
the inhibitor. Our immunological
work
is considered
the use of rabbits,
we made an antibody
thrombin
according
to the procedures
inhibitor
cross-reacted
tation
band between
identity
with
investigation with
with
these
tests
is planned,
which
(6).
antiserum
Ouchtertony
(Fig.
11).
With
chromatographed
pro-
There
There
to thank
study.
plates
were
used.
was a single
The
precipi-
was a band of immunological
of the prothrombin-antiserum
and we wish
are being
only an introductory
DEAE-cellulose
and the antiserum.
one of the components of this
to twice
described
the rabbit
the inhibitor
as being
Glenn
interaction. R. Van
Further
Noord for his help
continued.
FIG.
11
Ouchterlony plates. Center contained full-strength rabbit prothrombin antiserum. Well #l prothrombin at 16.7 mg/ml. #4 prothrombin at 8.5 mg/ml . #2 and #6 autoprothrombin II-A at 0.5 mg/ml. #3 and #5 autoprothrombin 11-A at 0.25 mg/ml. Photograph at 48 hours.
DISCUSSION Autoprothrombin presented that
the first
it might
sive, Another
II-A
description
be an agent
are consistent possibility
one non-prothrombin
was first
with
which
found
in 1960
of its purification induces
(1);
and have obtained
fibrinolysis.
The facts
the idea that an inhibitor-activator
is that there precursor
however,
are two non-prothrombin for the two activities.
we believe the first
presented,
is derived precursors
we have
indication if not conclu-
from prothrombin.
for each activity
or
456
AUTOPROTHROMBIN
PROTHROMBIN
II-A
Vol.l,No.5
COMPLEX
PRETHkXtBlN AN
AlJTOPf?OTHROMBlN
III
co ions Tissue Eatmct Plotekt Foctol ,3 Plosmo Focta R Other Factors
1 ;-,$$~in* Co ions*
I
AUTOPROTHROMBIN + Peptide
??
I
C
JOLYSIN
THROMBIN + Peptidc Is)
??These occclemtei Autopmthmbin C alone is sufficknt . *In voriis sequences ond combinotiis. **Nomad AutopFothromMn II-A; pmbobly on8 molecule with two disttnct activities.
FIG.
12
Possible molecular basis for holding blood coagulation at level of latent coagulation and fibrinolysis through a negative feedback system. Under conditions favoring formation of large amounts of autoprothrombin C, prothrombin conversion to thrombin would occur, without the formation of much prethrombin or autoprothrombin II-A. A dependence of fibrinolysis on the prothrombin system does not conflict with other pathways for fibrinolysis.
By adopting a conservative interesting
interpretation
ideas can be developed
and staying nearest the facts,
as avenues for further experimental
Small amounts of thrombin are not readily
removed by antithrombin
amounts of thrombin arise in our circulation,
the high affinity
as prothrombin (17);
be for thrombin formation to be retarded. hibitor of autoprothrombin The induced fibrinolysis of fibrinolysis minogen). dimension
11-A (Fig.
or possibly
the concept of latent coagulation
added which is outlined
in terms of molecular
12).
in-
for that reason also. The acceleration
of profibrinolysin
and fibrinolysis mechanics.
Prethrom.
is a competitive
in the removal of fibrin. by direct activation
When small
the tendency would
II-A
C, thrombin formation would be inhibited
could be indirect
In this way,
III(16).
therefore,
Since autoprothrombin
would be operational
exploration.
for prothrombin would re-
sult in the formation of prethrombin as well as autoprothrombin bin does not form thrombin as readily
some
(plas-
has another
This is essentially
considered
a negative
its own formation
feedback
system,
and to lyse the first
In case of perceptible autoprothrombin
C would
of prothrombin
to thrombin
18).
Autoprothrombin
the fibrinogen
when
often
Whenever thrombin
II-A
in 1939
when
complex
form fibrin,
mentioned,
fact that platelets, autoprothrombin
II-A
when
for the fact that platelet extensive ops,
intravascular
accelerated
coagulation.
deals
with
lated
factor
phenomena
In many respects, and extrinsic
or compartmentalization
for
that autopro-
was historically
(15,
to a prothrombin
has frequently
Most
interesting
and platelet complex.
can be infused
II-A
coagulation, and is subsumed
producing devel-
is to function
to explore
or latent
because
form
activity
membranes
is more meaningful
is the
that accounts
without
be useful
been
membranes
Possibly
3 and platelet
noticed
state
20).
It might
first
thrombin
into the imperceptible this
coagu-
thus accounting
we can assume
refractory
platelets
intravascular
It may be that autoprothrombin
of platelet
coagulation
it was shown
and that more arises anticoagulants
thrombin
3 or “lysed”
physiologi-
coagulation.
purified
prothrombin
of
further
aspects
and
than the division that arbitrary
of
division
by the idea of latent
and
coagulation,
Recently plasma
to purified
(15, Mosl
Under
fibrinolysis,
membranes,
than as a procoagulant.
into intrinsic
anatomy
accelerated
effect
rather
of blood
coagulation
added
red cell
coagulation,
the division
blood
3,
added
laboratory
of
quantities
conditions.
not lyse.
develops,
the two-stage
from this
factor
factor
and thus the initial
as an anticoagulant
that time,
induce
(19)
amounts
of appreciable
disseminated
the inhibitor
and Smith
in papers
platelet
state
large
under those
intravascular
refractory
is to retard
play a role in autocatalysis
with
would
disseminated
Seegers,
but mostly
would
not form extensively
that perspective,
Since
relatively
the conversion
Thrombin
11-A formation
From
preparation.
force
of thrombin
that might appear,
formation,
be a time associated
follows
Mertz,
fibrin
effect
and in a test tube it would
the two-stage
forms.
the initial
strands
would
12).
would
autoprothrombin
the fact that lysis
fibrin
This
(Fig.
there would
because
or massive
form.
II-A
would
cal conditions, lation
1-I 57
AUTOPROTIIROMBIN Tl--A
Vol.l,No.5
II-A
when
Since
use of purified
prothrombin
Although
metabolically
from plasma.
its function
(21).
that much two-stage
derived
direct
and quantitative
under physiological
synthesis
conditions.
the formation methods,
thrombin
is stopped
proof is lacking,
from the prothrombin
we have demonstrated
proteins
refractory
this
complex
zymogen
with could
we can attempt
Such a substance
Coumadin
or re-
be due to autopro-
as the latter
of autoprothrombin
is in
disappears
II-A
to accurately
with
the
imagine
has been postulated
by
458
AUTOPROTHROMBIN
still another approach by Hemker, kinetic
study,
deficiency. synthesis
they postulated
Veltkamp,
There is only limited due to complications
refractory
On the basis of a
inhibitor arises
They believed
in plasma in vitamin K
that vitamin K deficiency
or nonidentity
information
of autoprothrombin
II-A
to make advances
based on degradation
(23-25)
on that account.
Additionally,
and that is presumably
beyond the point of maximum inhibitor
producing autoprothrombin
II-A
C produces the two-stage
refractory
activity.
state,
destruction
Multiple
For instance,
ways of when puri-
one cannot be certain The courage to
reduce these problems is bound to be rewarded and perhaps with practical is known to function as a lytic agent (26) and esterase (27,
II-A
of the protein,
due to inhibitor
magnify chances for confusion.
shown to produce lysis in blood vessels
and pivka.
the two-stage
whether this is a direct effect or whether thrombin is first produced.
Thrombin
induced
on the maximum yi.eld of autoprothrombin
such as the formation of prethrombin and the lability
state is reversed
fied autoprothrombin
(22).
Was it derived from prothrombin ? That question remains as well as
many others regarding the identity
It will be difficult
Vol.l,No.5
and Loeliger
that a competitive
This was called pivka. of pivka.
II-A
applications.
thrombin also has been
28).
REFERENCES 1.
MAMMEN, E.F., THOMAS, W.R., and SEEGERS, W.H. Activation of purified prothrombin to autoprothrombin I or autoprothrombin II (platelet cofactor II) or autoprothrombin II-A. Thromb. Diath. Haemorrh.: 5, 218, 1960. =
2.
SEEGERS, prethrombin
3.
SEEGERS, W.H., HEENE, D.L., and MARCINIAK, E. Activation of purified Purification of autoprothrombin C. prothrombin in ammonium sulfate solutions: Thromb. Diath. Haemorrh.: 15, 1, 1966,
4.
MARCINIAK, E., MURANO, G., and SEEGERS, W.H. Inhibitor of blood clotting derived from prothrombin, Thromb. Diath. Haemorrh.: =18, 161, 1967.
5.
MARCINIAI<, 1970.
6.
MCCOY, L .E. mci SEEGERS, W .H. and purified prothrombin, Thrombosis
7.
SEEGERS, W.H., MCCOY, L., KIPFER, R.K., and MURANO, G. Preparation and properties of thrombin. Arch. Biochem. Biophys.: 128, 194, 1968.
W .H, and MARCINIAK, subunit of prothrombin.
E.
Coagulation
E. Some activation Life Sci.: 2, 1721,
inhibitor
elicited
characteristics 1965.
by thrombin.
Science:
of the
170,
452,
Preparation of bovine prothrombin complex Res, =I , 40 I, 197:~.
Vol.l,No. 5
AUTOPROTHROMBIN
3. ‘DOMBROSE,
F.A., YASUI, T., ROUBAL, W .H, Ac-globulin (factor V): Preparation Biochem.: In press.
9.
II-A
453
Z., ROUBAL, A., and SEEGERS, of a practical product. Preparative
HECHT, E.R., CHO, M.H., and SEEGERS, W.H. ture and preparation of protein-free material different activator. Amer. J. Physiol.: 193, 584, 1958.
Thromboplastin: Nomenclafrom platelet factor 3 or lipid
10,
SEEGERS, W .H . and SMITH, H.P. Factors fied thrombin. Amer. J. Physiol.: 137, 348,
11.
WARE, A.G. determination 1949.
12.
SEEGERS, W.H., MCCOY, L.E., REUTERBY, J., SAKURAGAWA, N., MURANO, G., and AGRAWAL, B.B.L. Further observations on the purification and properties of autoprothrombin III (factor X1. Thrombosis Res .: 1, 209, = 1972.
13.
S . The spectrophotofluorometric DUGGAN, D.E. and UDENFRIEND, tion of tryptophan in plasma and of tryptophan and tyrosine in protein J. Biol. Chem.: 223, 313, 1956.
14.
EDMAN, P. Sequence S .B. Needleman (Ed.)
and SEEGERS, of prothrombin
which influence 1942.
the activity
of puri-
W .H. Two-stage procedure for the quantitative concentration. Amer. J. Clin. Path.: 2, 471,
determinations. In: Berlin-Heidelberg-New
determinahydrolysates.
Protein Sequence Determinations. York: Springer-Verlag, 1970,
p. 211. 15.
SEEGERS,
W .H.
Prothrombin.
Cambridge:
Harvard
University
Press,
1962.
16.
DOMBROSE, F.A., SEEGERS, W.H., and SEDENSKY, J.A. Antithrombin: Inhibition of thrombin and autoprothrombin C (F-Xa) as a mutual depletion system, Thromb. Diath. Haemorrh.: 26, 103, 1971. =
17.
SEEGERS, W.H., DOMBROSE, F.A. and autoprothrombin
18.
SEEGERS, Three basic
19.
MERTZ, E.T., SEEGERS, W.H., and SMITH, by purified thrombin solutions. Proc. Sot. Exp.
20.
SEEGERS, W.H., MURANO, G., and MCCOY, thrombin during activation: A theory. Thromb.
21.
OUYANG, C., SEEGERS, W.H., MCCOY, L.E., and MiLLER-BERGHAUS, Metabolic formation of a prothrombin derivative. Thromb. Diath. Haemorrh.: 332, 1971.
SAKURAGAWA, N., MCCOY, L.E., SEDENSKY, J.A., and Prothrombin activation: Ac-globulin, lipid, platelet membrane, C (factor X,1 requirements. Thrombosis Res.: In press.
W.H., MCCOY, reactions. Clin.
L., and MARCINIAK, E. Chem.: 14, 97, 1968. = H.P. Biol.
Blood-clotting
Inactivation Med.: 4&
L. Structural Diath. Haemorrh
enzymology:
of prothrombin 657, 1939.
changes in pro.: 23, 26, 1970. i G. 25, _
h6c-l
.A~JTC)l’R0Tlll?OMIITN
TT-A
Vol.l,No.5
22.
H.EMI
23.
WARE, A.G. and SEEGERS, W.H. tivation with thrombin, and activation Chem.: 174, 565, 1948.
24.
SEEGERS, W.H., ANDREWS, E.B., and McCLAUGHRY, R.I. Formation prothrombin derivatives from purified prothrombin. Amer. J. Physiol.: 164, 1951.
25.
CHO, M.H. and SEEGERS, Exp. Biol. Med.: z, 642,
26.
BRAMBEL, C.E. 68, 67, 1957.
27.
BROERSMA, R.J., MCCOY, L.E., and SEEGERS, W.H. Production of microvascular thrombosis and lysis with acetylated thrombin. Thromb. Diath. Haemorrh. Suppl.: 47, 353, 1971. -=
28.
MCCOY, L.E., GRISCOM, H.A., imental fibrinolysis with acetylated 47, 339, 1971.
Proteases
W.H. 1958.
Studies on prothrombin: Purification, inacwith thromboplastin and calcium. J, Biol y
Prothrombin
in the clotting
DIEKAMP, thrombin.
activation
mechanism.
cycle.
Proc.
of 722,
Sot.
Ann. N. Y. Acad.
Sci.:
U., and SEEGERS, W.H. ExperThromb. Diath. Haemorrh. Suppl.: