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Studies on aldolase isozymes during amphibian development I. Evidence for the presence of two types of aldolase in eggs from Rana, pipiens
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 30, No. 4, 1968
STUDIES ON ALDOLASE ISOZYMES DURING AMPHIBIAN I.
EVIDENCE FOR THE PRESENCE OF TWO TiPES EGGS FROM Rana pipiens* Kozaburo
ReceivedJanuary
which
of investigation
with
and development.
ly, fetal
1967a)
are
aldolase major
tissues
reassociation
+
regard
to possible
changes
this
of animal classical
Five
and electrophoresis of mixtures
were 1959;
53706
represent during
(Penhoet
primarily
with
Cahn et al.,
1962).
Recent-
forms
of aldolase after
of each two-membered
of tissues
(Penhoet
and catalytic
aldolase
et al.,
either
and rat
et al.,
1966)
B from or from
1967)
(Rensing
in et al.,
properties,
liver, several
These and of the
and of the rat
have been demonstrated --in vitro set
dissociation
of parental
1966).
These
Supported by grants from the U.S. Atomic Energy Commission Contract No. AT(ll-l)-1631) and from the National Institutes (Grant No. AM-00922), U.S. Public Health Service. The abbreviations used are: FDP, fructose-1,6-diphosphate; fructose-l-phosphate.
343
present
have been demonstrated,
et al.,
(Herskovitz
differentiation
aldolase
of molecular
FDP aldolase
an interesting
concerned
--et al. 9 1967)
musclexenzyme,
brain
1967a).
field
and MBller,
(Herskovitz
of the chicken
in extracts
in
On the basis
rabbit
et al.,
chromatography
*
A, the
C from
(Rensing
--in vivo
types
forms
of fructose-1,6-diphosphate'
of the fowl
distinct
in multiple
(Markert
have appeared.
aldolase
and H. J. Sallach
exist
studies
on the types
tissues
three
Early
dehydrogenase
reports
Chen,
11, 1968
The many enzymes
lactate
Lee-Jing
OF ALDOLASE IN
From the Department of Physiological Chemistry, of Wisconsin Medical School, Madison, Wisconsin
University
area
Adachi,
DEVELOPMENT
by and
aldolases results
or are
(Research of Health FlP,
BIOCHEMICAL
Vol. 30, No. 4, 1968
explained three
most
readily
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
on the basis
of a molecule
four
rather
than
subunits. Studies
stage
on the relationship
of development
tory.
In this
of aldolase found
in the
in adult
killed
0.001
(eggs
the eggs before
shaken
gently
HCl buffer, times
these
from
of a pituitary stripped
during
homogenized
Gravid
liver
ovary) case,
gravid
suspension
labora-
to those
homogenization
with
four
pH 7.5,
for
this
treatment.
in an equal
of 0.125
40 minutes.
for
a column before
of Blostein
D. J.,
enzymatic
assay.
and Rutter
(1963)
J.
was removed which
G-25,
except
L.,
344
that
personal
a slight
in 0.005
was changed
were
supematant
eggs were containing centri-
solutions
equilibrated
0.008
was assayed M
M Tris-
three
procedure,
homogenates
activity
from
Eggs were
pH 7.5,
previously
Aldolase
is
buffer,
The resulting
of Sephadex
and Hedrick,
All
by in-
of Rugh (1961).
and Hedrick'.
M Tris-HCl
of
(eggs,
to ovulate
procedure
the dejellying
of 0.05
pH
of nonin-
ovulation
coat
The buffer
Following
volume
the ovary
M 2-mercaptoethanol
20 minutes.
buffer,
The two types
to the method
by Gusseck
The fresh
M Tris-HCl
induced
The jelly
were
removed.
after
were
following
described
about
were
obtained
later.
by the
volumes
(Rana pipiens)
of 0.05
females
at 100,OOOg
Gusseck,
this
of two types
compared
eggs from
according
24 to 48 hours
of the method
(w/v>
and those
fuged
method
are
grassfrogs
were
M 2-mercaptoethanol.
same buffer,
the presence
and muscle
studies
M EDTA and 0.01
through
and the in
M 2-mercaptoethanol.
0.001
passed
for
female
M EDTA and 0.01
In the latter
modification
of aldolase
investigation
and these
in two volumes
used in
females
Eggs were
under
is presented
and brain,
homogenized
egg preparations
jection
are
eggs of Rana pipiens
and Methods.
were
spawned).
amphibian
the types
tissues.
containing
duced
between
evidence
by decapitation
tissues 7.5,
in the
report,
Materials
1
with
were
with
by the
FDP was used.
communication.
the
Zone
BIOCHEMICAL
Vol. 30, No. 4, 1968
electrophoresl:
was performed
which
contained
0.001
strips
(Gelman
acetate two hours
at 4'C.
The staining
solution
arsenate,
mg per
ml of rabbit
Sepraphore
contained
muscle
A strip
solution
electrophoresis, placed minutes
for
strips
color
were
Results extracts
(1963)
used
aldolase
activity
ratios
for
FlP obtained
demonstrated
tios
of brain. egg were
the
cent
fonnalin
their
I.
activity et&.,
for
egg preparations
activity
1.
ratios
however, here
--et al.,
345
10 to 20
the various and Rutter
as shown in Fig.
is not
saturated et al.
lowest (aldolase
reported
however,
(1967b),
that
Vm,,
of the reaction
for
was
and highest
A) was found previously
for
to this
The activity those
ra-
of muscle
from muscle, from
.
used in the
liver
1967a,b). between
1
by this
of the apparent
FlP of aldolase
of magnitude,
were
and staining
at the level
intermediate for
After
Blostein
by Rensing
were
than values
stain-
samples
for
studies,
muscle
Rensing
sample
The velocity
ratios
this
at 37OC for
on the basis
studies,
were
(Sigma),
fixing.
suggested
of Fig.
K m values
of the same order
both
activity
examined as
in
the
the dark
of FDP concentration
1963;
M
M NAD, 0.12
box.
containing
system,
tissues
ratio
0.00015
0.001
was soaked
In their
assay
the data
as follows:
pH 7.5,
M FlP,
cm for
dehydrogenase
staining,
The FDP/FlP
In these
The apparent
buffer, 0.03
per
activity
in a plastic
in
have been calculated
aldolases.
(Blostein for
After
in Table
The FDP/FlP
have a much lower tissue
strips
to be independent
system. brain
acetate
Therefore,
from
aldolase
paper
plate
in the
of FlP.
the
for
given
0.01 M FlP in
I,
acetate
and incubated
in 1 per
are
concentration
assay
strip
on cellulose
and 0.5 mg per ml of nitroblue
on a glass
and Discussion
tissue
and Table
methosulfate,
development.
soaked
for
0.1 M Tris-HCl
the cellulose
pH 8.5,
2.5 X 17 cm) at 25 volts
glyceraldehyde-3-phosphate
placed
on the staining
buffer,
M 2-mercaptoethanol,
stained
of cellulose
and then
barbital
M EDTA, 0.01 M FDP, or
24 pg per ml of phenazine
ing
M sodium
III,
were
Strip.5
0.001
tetrazolium.
in 0.06
M EDTA and 0.0025
The
sodium
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
liver
brain was
and and
Vol. 30, No. 4, 1968
BIOCHEMICAL
-100
0
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
loo
200 [FRUCTOSE- I -PHOSPHATE]-’
Fig. 1. Double reciprocal plots A, liver; x, brain; I, muscle;
of l/v with respect to l/[FlP]. o, eggs from ovary; l , eggs,
Table Aldolase extracts.
activity,
Organ
FDP/FlP
activity
Activity Units/mg
Muscle
Brain
5.5
Eggs from ovary
1.1
Eggs, *
of aldolase the aldol described
activity cleavage in the
FlP of frog
Km for
tissue
FlP
-2
5.7
1.1X10
1.3
0.41
"
1.1
"
8.6
0.95
"
7.9
1.4
"
12
spawned
One unit catalyzed conditions
and Km for
FDP/FlP activity ratio
52 2.7
spawned.
I
ratio,
for FDP tissue*
Liver
300
M
was defined as that amount of enzyme which of 1 micromole of FDP per minute under the assay procedure.
lower. The electrophoretic
patterns
of aldolase
346
from
various
organs
of the
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 30, No. 4, 1968
c
AB
Fig. frog A: B: C: D: E: F:
CD
are
patterns
shown in Fig.
activity,
which
two bands
of activity,
more anodic
results
are
et al.,
1966) than
Fig. 3. Electrophoretic patterns of aldolase staided for FlP and FDP. A: Muscle, stained for FlP. B: Liver, stained for FlP. C: Liver, stained for FDP. D: Muscle, stained for FDP.
of
The muscle
preparation
at the most
one coinciding band,
in contrast and rat
aldolase
and B was not
2.
was localized
second,
lity
EF
2. Electrophoretic tissue aldolases. Eggs from ovary. Spawned eggs. Brain. Spawned eggs. Liver. Muscle.
frog
Origin
A.
detected
which
found et al.,
The possible in
these
cathodic that
was specific
to those (Rensing
with
with 1967a),
presence
experiments.
347
showed
only
site,
whereas
of muscle
for
liver
aldolase which of hybrids
one band of liver
(aldolase
(aldolase B from
gave A) and a
B).
rabbit
These (Penhoet
had more cathodic between
The localization
mobi-
aldolase of aldolase
A
BIOCHEMICAL
Vol. 30, No. 4, 1968
activity
for
FlP
muscle
preparation
activity
in this
from
liver
that
the high
could
et al.,
aldolase
A in brain
that
ever,
this
both it
Brain
muscle
1966).
aldolases
additional
egg preparation
those
phoretical
in egg,
have
tissues
not
been
the predominance of the
with
the presence
rat
followed
development. of aldolase
How-
that
In order
of
to provide
of types
A and C,
extract
and then
bands
of egg aldolase
in an increased
must
during
later
that
in-
the aldolases
await
the results
of aldolase by a shift other
C, as well
to the
the
at earlier
stages,
--et al.
type)
as A, in embryonic
(1967a)
in most
organ-specific
Kaplan's
electro-
of development.
Rensing
A (muscle
hand,
in
stages
present
previously.
348
of brain
The electro-
the changes
of aldolase
On the
to that
are in progress.
isozymes
investigated
than
present.
suggests
concerning
the forms
or rabbit
concentration
or muscle
proof
results
between
and resulted
to
of aldo-
1967a)
C.
of all
Additional
reports
of aldolase
type
egg consists
brain
which
the
were
ratio.
observation
studies
several
to our knowledge,
have demonstrated
ported
and other
patterns
of aldolase
This
of the A and C types.
have been
either
and muscle
staining.
with
et al.,
over
B
1963;
was composed
forms
The distribution
of brain
of enzymatic
There
fetal
with
et al.,
egg was intermediate
the aldolases
was mixed
with
i.e.
A predominated from
aldolase
egg was similar
hybrid
of the low
has been proposed
in greater
from
from
coincided
However,
C was present
that
to electrophoresis.
of immunochemical
(Rensing
activity
subjected
of egg are
rat
as was the FDP/FlP
evidence
tensity
type
(Rutter
the frog
The
FlP may be related
in agreement
A and C and their
of aldolase
and of brain
is
Aldolase
that It
for
tissue
B.
because
suggests
liver
from
either
aldolase
FDP and FlP.
this
This
2).
in that
pattern
in
Aldolase
(Fig.
also
B from
aldolase
from
of liver
FlP activity
of both
hybrids.
tissue
differed
phoretical
cleavage
metabolism
A and C and their
for
observation
of aldolase
1964).
(Penhoet
the
the
of fructose
for
be stained
This
specificity
obtained
in
not
tissue.
et al.,
lases
3) was the same as that
catalyzes
the pathway Spolter
(Fig.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
type
group
has re-
muscle
of the
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 30, No. 4, 1968
chick
(Herskovitz
the existence three
et al., of two parent
hybrids,
type)
1967).
However,
has been observed
blastocyst
stage
although
the early
muscle
types
type
(Auerbach
frog.
(Markert
in sea urchin
tion
et al.,
(Patton
upon fertilization
multiple
in unfertilized a singl.e
lactate
tissues
1967;
The number
eggs was shown to decrease
1967).
Possible
changes
and during
early
developmental
their
of malate eggs isozyme
the unfertilized
Rapola
for
with
forms
sea urchin
ovum to the
and Koskimies,
of mammals contain 1962).
evidence
dehydrogenase
in mouse ova from
and Ursprung,
ase isozymes
provide
A and C, together
Similarly,
and Brinster,
embryonic
studies
of aldolases,
have been demonstrated
et al.,
(heart
The present
in the egg of the
dehydrogenase (Patton
1967).
1967),
predominantly
the
of malate
dehydrogen-
following
fertiliza-
in aldolase stages
types are
in frog
under
eggs
investiga-
tion. REFERENCES Auerbach, S. and Brinster, R. L., Exp. Cell Res., 46, 89 (1967). Blostein, R. and Rutter, W. J., J. Biol. Chem., 238, 3280 (1963). Cahn, R. D., Kaplan, N. O., Levine, L., and Zwilling, E., Science, 136. 962 (1962). Herskovitz, J. J., Masters, C. J., Wasserman, P. M., and Kaplan, N. O., Biochem. Biophys. Res. Commun., 26, 24 (1967). Markert, C. L. and Mbller, F., Proc. Natl. Acad. Sci., 45, 753 (1959). Markert, C. L. and Ursprung, H., Develop. Biol., 2, 363 (19.62). Patton, G. W., Jr., Mets, L., and Villee, C. A., Science, 156, 400 (1967). Penhoet, E., Rajikumar, T. V., and Rutter, W. J., Proc. Natl. Adac. Sci. U. S ., If?, 1275 (1966). Rapola, J. and Koskimies, O., Science, 157, 1311 (1967). Rensing, U., Schmid, A., and Leuhardt, F., Hoppe-Seyler's Z. Physiol. Chem., 348, 921 (1967a). Rensing, U., S&aid, A., Christen, P., and Leuhardt, F., Hoppe-Seyler's Z. Physiol. Chem., 348, 1004 (1967b). Rugh, R., "Experimental Embryology: A Manual Techniques and Procedures", Burgess, Minneapolis, Minn., 1961, p. 102. Rutter, W. J., Blostein, R. E., Woodfin, B. M., and Weber, C. S., in Weber, G. (Editor), Advances in Enzyme Regulation, vol. 1, Pergamon Press Ltd., London, 1963, p. 39. Rutter, W. J., Federation Proc., 23, 1248 (1964). Spolter, P. D., Adelman, R. C., DiPietro, D. L., and Weinhouse, S., in Weber, G. (Editor), Advances in Enzyme Regulation, vol. 2, Pergamon Press Ltd., London, 1964, p. 79.
349
Vol. 30, No. 4, 1968
STUDIES ON ALDOLASE ISOZYMES DURING AMPHIBIAN I.
EVIDENCE FOR THE PRESENCE OF TWO TiPES EGGS FROM Rana pipiens* Kozaburo
ReceivedJanuary
which
of investigation
with
and development.
ly, fetal
1967a)
are
aldolase major
tissues
reassociation
+
regard
to possible
changes
this
of animal classical
Five
and electrophoresis of mixtures
were 1959;
53706
represent during
(Penhoet
primarily
with
Cahn et al.,
1962).
Recent-
forms
of aldolase after
of each two-membered
of tissues
(Penhoet
and catalytic
aldolase
et al.,
either
and rat
et al.,
1966)
B from or from
1967)
(Rensing
in et al.,
properties,
liver, several
These and of the
and of the rat
have been demonstrated --in vitro set
dissociation
of parental
1966).
These
Supported by grants from the U.S. Atomic Energy Commission Contract No. AT(ll-l)-1631) and from the National Institutes (Grant No. AM-00922), U.S. Public Health Service. The abbreviations used are: FDP, fructose-1,6-diphosphate; fructose-l-phosphate.
343
present
have been demonstrated,
et al.,
(Herskovitz
differentiation
aldolase
of molecular
FDP aldolase
an interesting
concerned
--et al. 9 1967)
musclexenzyme,
brain
1967a).
field
and MBller,
(Herskovitz
of the chicken
in extracts
in
On the basis
rabbit
et al.,
chromatography
*
A, the
C from
(Rensing
--in vivo
types
forms
of fructose-1,6-diphosphate'
of the fowl
distinct
in multiple
(Markert
have appeared.
aldolase
and H. J. Sallach
exist
studies
on the types
tissues
three
Early
dehydrogenase
reports
Chen,
11, 1968
The many enzymes
lactate
Lee-Jing
OF ALDOLASE IN
From the Department of Physiological Chemistry, of Wisconsin Medical School, Madison, Wisconsin
University
area
Adachi,
DEVELOPMENT
by and
aldolases results
or are
(Research of Health FlP,
BIOCHEMICAL
Vol. 30, No. 4, 1968
explained three
most
readily
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
on the basis
of a molecule
four
rather
than
subunits. Studies
stage
on the relationship
of development
tory.
In this
of aldolase found
in the
in adult
killed
0.001
(eggs
the eggs before
shaken
gently
HCl buffer, times
these
from
of a pituitary stripped
during
homogenized
Gravid
liver
ovary) case,
gravid
suspension
labora-
to those
homogenization
with
four
pH 7.5,
for
this
treatment.
in an equal
of 0.125
40 minutes.
for
a column before
of Blostein
D. J.,
enzymatic
assay.
and Rutter
(1963)
J.
was removed which
G-25,
except
L.,
344
that
personal
a slight
in 0.005
was changed
were
supematant
eggs were containing centri-
solutions
equilibrated
0.008
was assayed M
M Tris-
three
procedure,
homogenates
activity
from
Eggs were
pH 7.5,
previously
Aldolase
is
buffer,
The resulting
of Sephadex
and Hedrick,
All
by in-
of Rugh (1961).
and Hedrick'.
M Tris-HCl
of
(eggs,
to ovulate
procedure
the dejellying
of 0.05
pH
of nonin-
ovulation
coat
The buffer
Following
volume
the ovary
M 2-mercaptoethanol
20 minutes.
buffer,
The two types
to the method
by Gusseck
The fresh
M Tris-HCl
induced
The jelly
were
removed.
after
were
following
described
about
were
obtained
later.
by the
volumes
(Rana pipiens)
of 0.05
females
at 100,OOOg
Gusseck,
this
of two types
compared
eggs from
according
24 to 48 hours
of the method
(w/v>
and those
fuged
method
are
grassfrogs
were
M 2-mercaptoethanol.
same buffer,
the presence
and muscle
studies
M EDTA and 0.01
through
and the in
M 2-mercaptoethanol.
0.001
passed
for
female
M EDTA and 0.01
In the latter
modification
of aldolase
investigation
and these
in two volumes
used in
females
Eggs were
under
is presented
and brain,
homogenized
egg preparations
jection
are
eggs of Rana pipiens
and Methods.
were
spawned).
amphibian
the types
tissues.
containing
duced
between
evidence
by decapitation
tissues 7.5,
in the
report,
Materials
1
with
were
with
by the
FDP was used.
communication.
the
Zone
BIOCHEMICAL
Vol. 30, No. 4, 1968
electrophoresl:
was performed
which
contained
0.001
strips
(Gelman
acetate two hours
at 4'C.
The staining
solution
arsenate,
mg per
ml of rabbit
Sepraphore
contained
muscle
A strip
solution
electrophoresis, placed minutes
for
strips
color
were
Results extracts
(1963)
used
aldolase
activity
ratios
for
FlP obtained
demonstrated
tios
of brain. egg were
the
cent
fonnalin
their
I.
activity et&.,
for
egg preparations
activity
1.
ratios
however, here
--et al.,
345
10 to 20
the various and Rutter
as shown in Fig.
is not
saturated et al.
lowest (aldolase
reported
however,
(1967b),
that
Vm,,
of the reaction
for
was
and highest
A) was found previously
for
to this
The activity those
ra-
of muscle
from muscle, from
.
used in the
liver
1967a,b). between
1
by this
of the apparent
FlP of aldolase
of magnitude,
were
and staining
at the level
intermediate for
After
Blostein
by Rensing
were
than values
stain-
samples
for
studies,
muscle
Rensing
sample
The velocity
ratios
this
at 37OC for
on the basis
studies,
were
(Sigma),
fixing.
suggested
of Fig.
K m values
of the same order
both
activity
examined as
in
the
the dark
of FDP concentration
1963;
M
M NAD, 0.12
box.
containing
system,
tissues
ratio
0.00015
0.001
was soaked
In their
assay
the data
as follows:
pH 7.5,
M FlP,
cm for
dehydrogenase
staining,
The FDP/FlP
In these
The apparent
buffer, 0.03
per
activity
in a plastic
in
have been calculated
aldolases.
(Blostein for
After
in Table
The FDP/FlP
have a much lower tissue
strips
to be independent
system. brain
acetate
Therefore,
from
aldolase
paper
plate
in the
of FlP.
the
for
given
0.01 M FlP in
I,
acetate
and incubated
in 1 per
are
concentration
assay
strip
on cellulose
and 0.5 mg per ml of nitroblue
on a glass
and Discussion
tissue
and Table
methosulfate,
development.
soaked
for
0.1 M Tris-HCl
the cellulose
pH 8.5,
2.5 X 17 cm) at 25 volts
glyceraldehyde-3-phosphate
placed
on the staining
buffer,
M 2-mercaptoethanol,
stained
of cellulose
and then
barbital
M EDTA, 0.01 M FDP, or
24 pg per ml of phenazine
ing
M sodium
III,
were
Strip.5
0.001
tetrazolium.
in 0.06
M EDTA and 0.0025
The
sodium
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
liver
brain was
and and
Vol. 30, No. 4, 1968
BIOCHEMICAL
-100
0
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
loo
200 [FRUCTOSE- I -PHOSPHATE]-’
Fig. 1. Double reciprocal plots A, liver; x, brain; I, muscle;
of l/v with respect to l/[FlP]. o, eggs from ovary; l , eggs,
Table Aldolase extracts.
activity,
Organ
FDP/FlP
activity
Activity Units/mg
Muscle
Brain
5.5
Eggs from ovary
1.1
Eggs, *
of aldolase the aldol described
activity cleavage in the
FlP of frog
Km for
tissue
FlP
-2
5.7
1.1X10
1.3
0.41
"
1.1
"
8.6
0.95
"
7.9
1.4
"
12
spawned
One unit catalyzed conditions
and Km for
FDP/FlP activity ratio
52 2.7
spawned.
I
ratio,
for FDP tissue*
Liver
300
M
was defined as that amount of enzyme which of 1 micromole of FDP per minute under the assay procedure.
lower. The electrophoretic
patterns
of aldolase
346
from
various
organs
of the
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 30, No. 4, 1968
c
AB
Fig. frog A: B: C: D: E: F:
CD
are
patterns
shown in Fig.
activity,
which
two bands
of activity,
more anodic
results
are
et al.,
1966) than
Fig. 3. Electrophoretic patterns of aldolase staided for FlP and FDP. A: Muscle, stained for FlP. B: Liver, stained for FlP. C: Liver, stained for FDP. D: Muscle, stained for FDP.
of
The muscle
preparation
at the most
one coinciding band,
in contrast and rat
aldolase
and B was not
2.
was localized
second,
lity
EF
2. Electrophoretic tissue aldolases. Eggs from ovary. Spawned eggs. Brain. Spawned eggs. Liver. Muscle.
frog
Origin
A.
detected
which
found et al.,
The possible in
these
cathodic that
was specific
to those (Rensing
with
with 1967a),
presence
experiments.
347
showed
only
site,
whereas
of muscle
for
liver
aldolase which of hybrids
one band of liver
(aldolase
(aldolase B from
gave A) and a
B).
rabbit
These (Penhoet
had more cathodic between
The localization
mobi-
aldolase of aldolase
A
BIOCHEMICAL
Vol. 30, No. 4, 1968
activity
for
FlP
muscle
preparation
activity
in this
from
liver
that
the high
could
et al.,
aldolase
A in brain
that
ever,
this
both it
Brain
muscle
1966).
aldolases
additional
egg preparation
those
phoretical
in egg,
have
tissues
not
been
the predominance of the
with
the presence
rat
followed
development. of aldolase
How-
that
In order
of
to provide
of types
A and C,
extract
and then
bands
of egg aldolase
in an increased
must
during
later
that
in-
the aldolases
await
the results
of aldolase by a shift other
C, as well
to the
the
at earlier
stages,
--et al.
type)
as A, in embryonic
(1967a)
in most
organ-specific
Kaplan's
electro-
of development.
Rensing
A (muscle
hand,
in
stages
present
previously.
348
of brain
The electro-
the changes
of aldolase
On the
to that
are in progress.
isozymes
investigated
than
present.
suggests
concerning
the forms
or rabbit
concentration
or muscle
proof
results
between
and resulted
to
of aldo-
1967a)
C.
of all
Additional
reports
of aldolase
type
egg consists
brain
which
the
were
ratio.
observation
studies
several
to our knowledge,
have demonstrated
ported
and other
patterns
of aldolase
This
of the A and C types.
have been
either
and muscle
staining.
with
et al.,
over
B
1963;
was composed
forms
The distribution
of brain
of enzymatic
There
fetal
with
et al.,
egg was intermediate
the aldolases
was mixed
with
i.e.
A predominated from
aldolase
egg was similar
hybrid
of the low
has been proposed
in greater
from
from
coincided
However,
C was present
that
to electrophoresis.
of immunochemical
(Rensing
activity
subjected
of egg are
rat
as was the FDP/FlP
evidence
tensity
type
(Rutter
the frog
The
FlP may be related
in agreement
A and C and their
of aldolase
and of brain
is
Aldolase
that It
for
tissue
B.
because
suggests
liver
from
either
aldolase
FDP and FlP.
this
This
2).
in that
pattern
in
Aldolase
(Fig.
also
B from
aldolase
from
of liver
FlP activity
of both
hybrids.
tissue
differed
phoretical
cleavage
metabolism
A and C and their
for
observation
of aldolase
1964).
(Penhoet
the
the
of fructose
for
be stained
This
specificity
obtained
in
not
tissue.
et al.,
lases
3) was the same as that
catalyzes
the pathway Spolter
(Fig.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
type
group
has re-
muscle
of the
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 30, No. 4, 1968
chick
(Herskovitz
the existence three
et al., of two parent
hybrids,
type)
1967).
However,
has been observed
blastocyst
stage
although
the early
muscle
types
type
(Auerbach
frog.
(Markert
in sea urchin
tion
et al.,
(Patton
upon fertilization
multiple
in unfertilized a singl.e
lactate
tissues
1967;
The number
eggs was shown to decrease
1967).
Possible
changes
and during
early
developmental
their
of malate eggs isozyme
the unfertilized
Rapola
for
with
forms
sea urchin
ovum to the
and Koskimies,
of mammals contain 1962).
evidence
dehydrogenase
in mouse ova from
and Ursprung,
ase isozymes
provide
A and C, together
Similarly,
and Brinster,
embryonic
studies
of aldolases,
have been demonstrated
et al.,
(heart
The present
in the egg of the
dehydrogenase (Patton
1967).
1967),
predominantly
the
of malate
dehydrogen-
following
fertiliza-
in aldolase stages
types are
in frog
under
eggs
investiga-
tion. REFERENCES Auerbach, S. and Brinster, R. L., Exp. Cell Res., 46, 89 (1967). Blostein, R. and Rutter, W. J., J. Biol. Chem., 238, 3280 (1963). Cahn, R. D., Kaplan, N. O., Levine, L., and Zwilling, E., Science, 136. 962 (1962). Herskovitz, J. J., Masters, C. J., Wasserman, P. M., and Kaplan, N. O., Biochem. Biophys. Res. Commun., 26, 24 (1967). Markert, C. L. and Mbller, F., Proc. Natl. Acad. Sci., 45, 753 (1959). Markert, C. L. and Ursprung, H., Develop. Biol., 2, 363 (19.62). Patton, G. W., Jr., Mets, L., and Villee, C. A., Science, 156, 400 (1967). Penhoet, E., Rajikumar, T. V., and Rutter, W. J., Proc. Natl. Adac. Sci. U. S ., If?, 1275 (1966). Rapola, J. and Koskimies, O., Science, 157, 1311 (1967). Rensing, U., Schmid, A., and Leuhardt, F., Hoppe-Seyler's Z. Physiol. Chem., 348, 921 (1967a). Rensing, U., S&aid, A., Christen, P., and Leuhardt, F., Hoppe-Seyler's Z. Physiol. Chem., 348, 1004 (1967b). Rugh, R., "Experimental Embryology: A Manual Techniques and Procedures", Burgess, Minneapolis, Minn., 1961, p. 102. Rutter, W. J., Blostein, R. E., Woodfin, B. M., and Weber, C. S., in Weber, G. (Editor), Advances in Enzyme Regulation, vol. 1, Pergamon Press Ltd., London, 1963, p. 39. Rutter, W. J., Federation Proc., 23, 1248 (1964). Spolter, P. D., Adelman, R. C., DiPietro, D. L., and Weinhouse, S., in Weber, G. (Editor), Advances in Enzyme Regulation, vol. 2, Pergamon Press Ltd., London, 1964, p. 79.
349