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Evidence for a buried location of Nigeran in the cell wall of Aspergillus niger
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 28, No. 4, 1967
EVIDENCE FOR A BURIED LOCATION OF NIGERAN IN THE CELL WALL OF ASPERGILLUS NIGER K. K. Tung and J. H. Nordin Department of Biochemistry University of Massachusetts 01002 Amherst, Massachusetts
Received
July 6, 1967
Nigeran,
an unbranched
of the Aspergillus a(1+4)
species
consists
associated
of alternating
with
a(l-+3)
fungi and
linkages
1957).
It
between D glucopyranose units (Barker -et al. = has not been clearly resolved whether or not this
polysaccharide
is a constituent
Mandels 1964, Johnston mycelia
by heating
tates
1965).
Since
it
isolated
insolubility.
to attack
involved
in such a position by a hydrolytic
(Reese and from
to 100' and quickly in hot water,
precipi-
to room temperature. it
is not known whether
in the architecture wall
material
We wish to present a constituent
wall
can be extracted
soluble
in water
along with
is in fact
is located
cools
is insoluble
isintimately
or merely
nigeran
Nigeran
an aqueous suspension
when the filtrate
polymer
of the cell
The polysaccharide,
filtering.
this
polysaccharide
direct
of the wall
by virtue evidence
of the cell
wall
as to be practically
enzyme (mycodextranase)
the
of this
indicating of A. niger
and
inaccessible specific
for
polysaccharide.
Materials
and Methods
Aspergillus surface
culture
niger
QM326 was grown from spore inoculum
at room temperature.
519
The medium consisted
in of the
Vol. 28, No. 4, 1967
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
following
in
(NH412N03
2.6,
0.4,
grams
FeS04*
washing
of
the
of the
product
mycelium
(Dubois using
et --
walls
2-5'
at
Whatman
grams
was accomplished
Dr.
al.
54:8:18
1950).
E. T.
study
istic rotation
[aID+
the
that
fact
using
of
hydrolytic
the
Examination
indicated
com-
glucose
and B. of
is
the
method
was done systems:
A.
isopropanol,
components silver
acetic
on chromato-
nitrate
standard
(Trevelyan
was a gift
from
Laboratories.
polysaccharide
0.5,
acid
solvent
alkaline
from
(c,
sulfuric
following
was based
products
phenol
v/v
as a function
222'
dried.
chromatography
U. S. Army Natick
water
walls
exhaustive
paper
Detection
as nigeran
in
and cell sonication
microscopy
The tetrasaccharide
Reese,
properties
the
6:4:3
v/v.
Identification present
in
water
water
freeze
(NH4)H2P04
to
Following
by the
Descending
1 paper
pyridine,
prior
homogenization,
were
2.7
Mg CO3 0.27 Just
cell.
they
acid
hyphae.
1956). No.
tartaric
and washed
and electron
the
acid,
et --
of
was measured
al.
l-butanol,
process pressure
Carbohydrate
0.047.
was harvested
a French
of
46,
K2C03 0.47,
and ZnS04
by light
breakage
sucrose
0.17,
by a sequential use
plete
(NH412S04
the
and the
of
liter:
7H20 0.047
sporulation prepared
per
liberated
on its of
(a)
in
unusual
temperature;
mycodextranase
solubility
(b)
character-
action;
(c)
NaOH) (Barker
et --
al.
1957);
sole
of
its
total
product
the
optical
and
(d)
acid
hydrolysis. Mycodextranase and Mandels and Nordin nigeran glucose)
was produced
(1964)
and purified
unpublished).
by this
enzyme
are
linked has
nigerose
(0-a-g
been
(tetramer) by an a(1+4) proven 520
to
30 fold
products
together not
about
The only
and a tetrasaccharide
nigerose units 1 This structure
according
the
method
of
Reese
prior
to use
(Tung
the
hydrolysis
of
of
glucopyranosyl consisting bond'
unequivocally.
(1+3)D of
(Reese
two and
=
Vol. 28, No. 4, 1967
Mandels
in
a highly or
to
clearly
determined
from
wall
Thus
since
it
only
is
the
has more
give
assay
these
for
the
quantity
total
the
of in
of
amount
of
Preliminary
ratio
identical
two
enzymatic
preparations.
that
one)
to
to
by measuring
demonstrated (about
walls.
found
possible manner
produced
disaccharide
unheated
is
specific
dimer
experiments
was also
It
exclusively.
tetramer
ide
Our enzyme
1964).
products attack
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
tetrasacchar-
heated
tetramer
carbohydrate
and
present
per
mole
was of
compound. Results The chromatographic in
comparison
I)
similarity
with
authentic
indicates
clearly
they
wall
as substrate.
cell
of
nigerose are
the
hydrolysis
products
and tetrasaccharide with
same
Table Chromatographic
the
either
(Table
nigeran
1
Mobilities of Compounds Released by Mycodestranase from Nigeran and A. niger Cell Walls
Compound
Solvent
Glucose Nigerose Tetrasaccharide
ARglcta)
Solvent
BRglc
1.00 0.74 0.32
1.00 .70 .33
Fast Slow
component component
from from
Nigeran Nigeran
0.74 0.33
.70 .30
Fast Slow
component component
from from
cell cell
0.73 0.32
.70 .33
(a)
Mobility
of
A four in
heated
this of
through bation
the
fold
difference
being
tetramer
enzyme
relative in
walls
the (Table
an integral
detected
preparation with
wall wall
compound
and unheated
polymer the
or
of
is the
should
to g glucose amount II)
of is
component from
walls, eliminate
521
of
exogenous one would
nigeran
strong the
evidence
for
If
part
wall.
nigeran
carried
expect
or decrease
hydrolyzed
the
that
preincu-
amount
Vol. 28, No. 4, 1967
liberated
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
from the unheated
walls
during
Table Enzymatic
Hydrolysis
Preincubation (min.)
incubation.
II
of Nigeran
time
the regular
in Cell
Wall
Preparations
M icro
moles of tetramer liberated per 10 mg of cell walls Unheated walls (a) Heated walls (a)
0 0 30
60 120
.07
.28
.07(b) .035 .035 .035
.27(b) .28 .27 .27
Cell wall suspensions (10 mg per m l.) in 0.02M citrate phosphate buffer pH 4.5 were preincubated at 30' with 0.1 unit (c) of mycodextranase for the times indicated. They were then washed three times in ice cold buffer and resuspended to the same concentration. Each suspension was divided into two portions, one of which was heated 10 m inutes in a boiling water bath and cooled. After equilibration at 40° 1.0 m l suspensions of walls were then incubated 20 m inutes with 0.1 unit of enzyme in a total volume of 1.1 m l. (The quantitative values above represent the product released during the second time period.) The reaction was stopped by heat and the water soluble material deionized and chromatographed in solvent B for 36 hours. The areas on the dry chromatogram corresponding to the tetramer were excised and eluted with water and the quantity of tetramer (above blank values) determined by the phenol sulfuric acid method using a glucose standard. (a) While these walls contain a very low level of reducing power (Nelson 1944) per unit weight prior to enzymatic attack, there is no detectable difference between heated and unheated walls, and neither contain any tetrasaccharide or nigerose as evidenced by paper chromatography. (b) 0.2 unit
of enzyme.
(c) One unit of enzyme will liberate 1.0 m icro mole of reducing equivalents expressed as glucose per m inute from a 0.4% suspension of nigran at 50“ and pH 4.5. This
was found to be the case.
did not reduce heated walls,
unheated centration released nigeran
the amount of nigeran indicating
Limiting
the enzyme. walls
In addition,
a definite
subsequently
more nigeran
does not change the quantity It
also
indicates
in the heated walls. 522
since
preincubation
liberated
inaccessibility
enzyme is not responsible
to yield
from them.
extended
from
of nigeran for
doubling
the failure enzyme con-
of tetrasaccharide complete
digestion
of
to of
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 28, No. 4, 1967
It
is probable
that
of tetrasaccharide unheated bation
walls
the continued
occurring
extended
is due to enzymatic
at a number of restricted To check this
the wall. which walls
for
incubated
directly
it
attack
of nigeran
without
In control completely
hours
experiments,
hydrolyzed
indicating
in unheated walls Further,
that
at an identical
nigeran
is alkali
soluble,
thereby
permitting
the wall
than heat will
the polymer likely
ionic
heat alone a possibility the wall resistance
frees that
and that
nigeran
at 40' during
this for
for
a heat labile
to enzymic hydrolysis.
523
four
Since from
Thus a method
another
of
is most molecule
attack.
arrangement
since
There is also
in some crystalline
molecular
dif-
the inaccessibility
enzymatic
may exist
pH.
inaccessibility
with
was
is
the polymer
hydrolysis.
to indicate
bonding
rapid
as compared to walls
agent extracts
This
a
walls
inhibitor
but neutral
enzymatic
the polymer
If
in 0.5N_ NaOH for
of nigeran
to mycodextranase.
not due to covalent
subjected
added to unheated
of walls
this
in
incubation.
strength,
suffice
both
would lead to the observed
in release
treated
20 m inutes.
heating.
no heat labile
preincubation
at O" resulted
and the
and become available
nigeran
in
and then
1944) after
additional
the final
in
was conducted
and those
were occurring
would have accumulated
ference.
exposed sites
power was present
60 m inutes,
by the enzyme during
present
the second incu-
at 40“ in the absence
(Nelson
of reducing
at 40° for
slow extraction
attack
during
of
enzymic preincubation
measured
level
to enzymatic
period,
attack
of up to 60 m inutes
power liberated
Only the low basal walls
preincubation
an experiment
through
amounts
Enzyme was again added to these preparations
of enzyme. reducing
periods
of small
or partially
point
were carried
incubated
other
with
release
array confers
in
Vol. 28, No. 4, 1967
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COAWJNICATIONS
Calculations tetrasaccharide
based on measurements released
up 7-8% of the weight
from heated walls
of these
material
liberated
from the wall
methanol
insoluble
fraction,
quantities
of glucose
of the wall. since
it
indicate
by heat
is a water
of this
other
equimolar
which makes up about fraction
in protecting
makes
soluble,
composed of approximately
Investigation
and
nigeran
The only
preparations.
and galactose,
may be involved
of both nigerose
LO-12%
is now underway
the nigeran
from enzymatic
attack. Acknowledgement This work was supported National
Science
by a grant
(GB 5162) from the
Foundation. REFERENCES
Barker, S. A., Bourne, E. J., O'Mant, D. M . and Stacey, M ., J. Chem. E., 2448 (1957). Dubois, M ., Gilles, K. A., Hamilton,.J. K., Rebers, P. A., and Smith, F., Anal. Chem. 28, 350 (1956). Johnston, I. R.,Biochem. J. E, 65 (1965). 375 (1944). Nelson, N., J. Biol. Chem.-E, M ., Can. J. M icrobial. 10, 103 (1964). Reese, E. T.-andndz Trevelyan, W. E., Proctor, D. cana Harrison, J. S., Nature 166, 444 (1950).
524
Vol. 28, No. 4, 1967
EVIDENCE FOR A BURIED LOCATION OF NIGERAN IN THE CELL WALL OF ASPERGILLUS NIGER K. K. Tung and J. H. Nordin Department of Biochemistry University of Massachusetts 01002 Amherst, Massachusetts
Received
July 6, 1967
Nigeran,
an unbranched
of the Aspergillus a(1+4)
species
consists
associated
of alternating
with
a(l-+3)
fungi and
linkages
1957).
It
between D glucopyranose units (Barker -et al. = has not been clearly resolved whether or not this
polysaccharide
is a constituent
Mandels 1964, Johnston mycelia
by heating
tates
1965).
Since
it
isolated
insolubility.
to attack
involved
in such a position by a hydrolytic
(Reese and from
to 100' and quickly in hot water,
precipi-
to room temperature. it
is not known whether
in the architecture wall
material
We wish to present a constituent
wall
can be extracted
soluble
in water
along with
is in fact
is located
cools
is insoluble
isintimately
or merely
nigeran
Nigeran
an aqueous suspension
when the filtrate
polymer
of the cell
The polysaccharide,
filtering.
this
polysaccharide
direct
of the wall
by virtue evidence
of the cell
wall
as to be practically
enzyme (mycodextranase)
the
of this
indicating of A. niger
and
inaccessible specific
for
polysaccharide.
Materials
and Methods
Aspergillus surface
culture
niger
QM326 was grown from spore inoculum
at room temperature.
519
The medium consisted
in of the
Vol. 28, No. 4, 1967
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
following
in
(NH412N03
2.6,
0.4,
grams
FeS04*
washing
of
the
of the
product
mycelium
(Dubois using
et --
walls
2-5'
at
Whatman
grams
was accomplished
Dr.
al.
54:8:18
1950).
E. T.
study
istic rotation
[aID+
the
that
fact
using
of
hydrolytic
the
Examination
indicated
com-
glucose
and B. of
is
the
method
was done systems:
A.
isopropanol,
components silver
acetic
on chromato-
nitrate
standard
(Trevelyan
was a gift
from
Laboratories.
polysaccharide
0.5,
acid
solvent
alkaline
from
(c,
sulfuric
following
was based
products
phenol
v/v
as a function
222'
dried.
chromatography
U. S. Army Natick
water
walls
exhaustive
paper
Detection
as nigeran
in
and cell sonication
microscopy
The tetrasaccharide
Reese,
properties
the
6:4:3
v/v.
Identification present
in
water
water
freeze
(NH4)H2P04
to
Following
by the
Descending
1 paper
pyridine,
prior
homogenization,
were
2.7
Mg CO3 0.27 Just
cell.
they
acid
hyphae.
1956). No.
tartaric
and washed
and electron
the
acid,
et --
of
was measured
al.
l-butanol,
process pressure
Carbohydrate
0.047.
was harvested
a French
of
46,
K2C03 0.47,
and ZnS04
by light
breakage
sucrose
0.17,
by a sequential use
plete
(NH412S04
the
and the
of
liter:
7H20 0.047
sporulation prepared
per
liberated
on its of
(a)
in
unusual
temperature;
mycodextranase
solubility
(b)
character-
action;
(c)
NaOH) (Barker
et --
al.
1957);
sole
of
its
total
product
the
optical
and
(d)
acid
hydrolysis. Mycodextranase and Mandels and Nordin nigeran glucose)
was produced
(1964)
and purified
unpublished).
by this
enzyme
are
linked has
nigerose
(0-a-g
been
(tetramer) by an a(1+4) proven 520
to
30 fold
products
together not
about
The only
and a tetrasaccharide
nigerose units 1 This structure
according
the
method
of
Reese
prior
to use
(Tung
the
hydrolysis
of
of
glucopyranosyl consisting bond'
unequivocally.
(1+3)D of
(Reese
two and
=
Vol. 28, No. 4, 1967
Mandels
in
a highly or
to
clearly
determined
from
wall
Thus
since
it
only
is
the
has more
give
assay
these
for
the
quantity
total
the
of in
of
amount
of
Preliminary
ratio
identical
two
enzymatic
preparations.
that
one)
to
to
by measuring
demonstrated (about
walls.
found
possible manner
produced
disaccharide
unheated
is
specific
dimer
experiments
was also
It
exclusively.
tetramer
ide
Our enzyme
1964).
products attack
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
tetrasacchar-
heated
tetramer
carbohydrate
and
present
per
mole
was of
compound. Results The chromatographic in
comparison
I)
similarity
with
authentic
indicates
clearly
they
wall
as substrate.
cell
of
nigerose are
the
hydrolysis
products
and tetrasaccharide with
same
Table Chromatographic
the
either
(Table
nigeran
1
Mobilities of Compounds Released by Mycodestranase from Nigeran and A. niger Cell Walls
Compound
Solvent
Glucose Nigerose Tetrasaccharide
ARglcta)
Solvent
BRglc
1.00 0.74 0.32
1.00 .70 .33
Fast Slow
component component
from from
Nigeran Nigeran
0.74 0.33
.70 .30
Fast Slow
component component
from from
cell cell
0.73 0.32
.70 .33
(a)
Mobility
of
A four in
heated
this of
through bation
the
fold
difference
being
tetramer
enzyme
relative in
walls
the (Table
an integral
detected
preparation with
wall wall
compound
and unheated
polymer the
or
of
is the
should
to g glucose amount II)
of is
component from
walls, eliminate
521
of
exogenous one would
nigeran
strong the
evidence
for
If
part
wall.
nigeran
carried
expect
or decrease
hydrolyzed
the
that
preincu-
amount
Vol. 28, No. 4, 1967
liberated
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
from the unheated
walls
during
Table Enzymatic
Hydrolysis
Preincubation (min.)
incubation.
II
of Nigeran
time
the regular
in Cell
Wall
Preparations
M icro
moles of tetramer liberated per 10 mg of cell walls Unheated walls (a) Heated walls (a)
0 0 30
60 120
.07
.28
.07(b) .035 .035 .035
.27(b) .28 .27 .27
Cell wall suspensions (10 mg per m l.) in 0.02M citrate phosphate buffer pH 4.5 were preincubated at 30' with 0.1 unit (c) of mycodextranase for the times indicated. They were then washed three times in ice cold buffer and resuspended to the same concentration. Each suspension was divided into two portions, one of which was heated 10 m inutes in a boiling water bath and cooled. After equilibration at 40° 1.0 m l suspensions of walls were then incubated 20 m inutes with 0.1 unit of enzyme in a total volume of 1.1 m l. (The quantitative values above represent the product released during the second time period.) The reaction was stopped by heat and the water soluble material deionized and chromatographed in solvent B for 36 hours. The areas on the dry chromatogram corresponding to the tetramer were excised and eluted with water and the quantity of tetramer (above blank values) determined by the phenol sulfuric acid method using a glucose standard. (a) While these walls contain a very low level of reducing power (Nelson 1944) per unit weight prior to enzymatic attack, there is no detectable difference between heated and unheated walls, and neither contain any tetrasaccharide or nigerose as evidenced by paper chromatography. (b) 0.2 unit
of enzyme.
(c) One unit of enzyme will liberate 1.0 m icro mole of reducing equivalents expressed as glucose per m inute from a 0.4% suspension of nigran at 50“ and pH 4.5. This
was found to be the case.
did not reduce heated walls,
unheated centration released nigeran
the amount of nigeran indicating
Limiting
the enzyme. walls
In addition,
a definite
subsequently
more nigeran
does not change the quantity It
also
indicates
in the heated walls. 522
since
preincubation
liberated
inaccessibility
enzyme is not responsible
to yield
from them.
extended
from
of nigeran for
doubling
the failure enzyme con-
of tetrasaccharide complete
digestion
of
to of
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 28, No. 4, 1967
It
is probable
that
of tetrasaccharide unheated bation
walls
the continued
occurring
extended
is due to enzymatic
at a number of restricted To check this
the wall. which walls
for
incubated
directly
it
attack
of nigeran
without
In control completely
hours
experiments,
hydrolyzed
indicating
in unheated walls Further,
that
at an identical
nigeran
is alkali
soluble,
thereby
permitting
the wall
than heat will
the polymer likely
ionic
heat alone a possibility the wall resistance
frees that
and that
nigeran
at 40' during
this for
for
a heat labile
to enzymic hydrolysis.
523
four
Since from
Thus a method
another
of
is most molecule
attack.
arrangement
since
There is also
in some crystalline
molecular
dif-
the inaccessibility
enzymatic
may exist
pH.
inaccessibility
with
was
is
the polymer
hydrolysis.
to indicate
bonding
rapid
as compared to walls
agent extracts
This
a
walls
inhibitor
but neutral
enzymatic
the polymer
If
in 0.5N_ NaOH for
of nigeran
to mycodextranase.
not due to covalent
subjected
added to unheated
of walls
this
in
incubation.
strength,
suffice
both
would lead to the observed
in release
treated
20 m inutes.
heating.
no heat labile
preincubation
at O" resulted
and the
and become available
nigeran
in
and then
1944) after
additional
the final
in
was conducted
and those
were occurring
would have accumulated
ference.
exposed sites
power was present
60 m inutes,
by the enzyme during
present
the second incu-
at 40“ in the absence
(Nelson
of reducing
at 40° for
slow extraction
attack
during
of
enzymic preincubation
measured
level
to enzymatic
period,
attack
of up to 60 m inutes
power liberated
Only the low basal walls
preincubation
an experiment
through
amounts
Enzyme was again added to these preparations
of enzyme. reducing
periods
of small
or partially
point
were carried
incubated
other
with
release
array confers
in
Vol. 28, No. 4, 1967
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COAWJNICATIONS
Calculations tetrasaccharide
based on measurements released
up 7-8% of the weight
from heated walls
of these
material
liberated
from the wall
methanol
insoluble
fraction,
quantities
of glucose
of the wall. since
it
indicate
by heat
is a water
of this
other
equimolar
which makes up about fraction
in protecting
makes
soluble,
composed of approximately
Investigation
and
nigeran
The only
preparations.
and galactose,
may be involved
of both nigerose
LO-12%
is now underway
the nigeran
from enzymatic
attack. Acknowledgement This work was supported National
Science
by a grant
(GB 5162) from the
Foundation. REFERENCES
Barker, S. A., Bourne, E. J., O'Mant, D. M . and Stacey, M ., J. Chem. E., 2448 (1957). Dubois, M ., Gilles, K. A., Hamilton,.J. K., Rebers, P. A., and Smith, F., Anal. Chem. 28, 350 (1956). Johnston, I. R.,Biochem. J. E, 65 (1965). 375 (1944). Nelson, N., J. Biol. Chem.-E, M ., Can. J. M icrobial. 10, 103 (1964). Reese, E. T.-andndz Trevelyan, W. E., Proctor, D. cana Harrison, J. S., Nature 166, 444 (1950).
524