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Role of singlet oxygen in the degradation of hyaluronic acid
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS Pages 894-901
Vol. 115, No. 3, 1983 September 30, 1983
ROLE OF SINGLET OXYGEN IN THE DEGRADATION OF HYALURONIC ACID Usha P. Andley I and Bireswar Chakrabarti I'2 Eye Research Institute of Retina Foundation 1 and Harvard Medical School, 2 Boston, Massachusetts 02114 Received August 12, 1983
To investigate the effect of singlet oxygen on the molecular properties of hyaluronic acid, the polymer was irradiated in the presence of a dye sensitizer for singlet oxygen. Viscosity and circular dichroism techniques were used to monitor these changes. The relative viscosity of the polymer solution decreased steadily with increasing duration of irradiation, indicating an apparent decrease in molecular weight of hyaluronic acid. Circular dichroism measurements of the irradiated sample, however, did not show any appreciable change in the secondary structure, but do suggest that the generated singlet oxygen changes the tertiary structure and that this change is followed by a minor depolymerization. Hyaluronic acid molecular
primary
ride
units
structure of
alternating (I-4)
molecular
a glycosaminoglycan,
component of vitreous humor,
Its
tory
(HA),
consists
D-glucuronic
8(I+3) have
and
of
acid
8(I+4)
synovial
unbranched and
is a major macrofluid,
skin,
repeating
disaccha-
N-acetyl-D-glucosamine
linkages.
Studies
etc.
in this
with
labora-
shown that the conformation of HA in solution
weight dependent.
This
is
is evident by the fact that the
chiroptical properties of lower and higher oligosaccharides differ (4), and
and
the
conformational
in the presence of Cu 2+ This
change
of
HA
in organic
solvent
(3) cannot be detected with
cular-weight
HA.
phenomenon
to determine
the relationship
must
between
be considered
(2)
low-mole-
in attempts
conformation and biological
function of the molecule. In the aging or pathological vitreous and in synovial fluids, degradaton of HA is known change
(5,6)
to occur,
and this may
lead to a
in conformation of the molecule and thus of the structural
integrity
of
the
tissues.
It is generally
0006-291X/83 $1.50 Copyright © 1983 ~ A c a ~ m ~ Press, ~c. AHr~h~ofreproduction ~ a ~ f o r m r e s e ~ .
894
believed
that depoly-
Vol. 115, No. 3, 1 9 8 3
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
merization of HA occurs through production of free radicals during autooxidation of reductants and the reduction of molecular oxygen. McCord
(7)
(O2~)
reacts
merizing (6),
that
with
HA of
H202
bovine
degeneration
of oxygen, 102,
found
generated
to produce hydroxy radical synovial
singlet oxygen
fluid.
As
(102).
exposure
to
sensitizer singlet
sources of
oxygen
can also be generated
light,
effectsr
a photosensitizer, proceed
via
the
and
produced
oxygen.
triplet
by by
Most
state o f
the
(11).
The to
radicals
produce
free
triplet
may
radicals
or
interact radical
with
a
anions.
can produce univalent reduction of molecufurther
dismutate to H202 and react with H202 to form the hydroxyl
radical
with
Alternatively,
molecular
energy
generate
sensitizer
can
(OH').
to
tissues
it has a much longer lifetime than the excited
substrate
These product
other
various potential sources
or photooxidative
oxidations
because
oxygen
(11),
visible
state
reducing
of molecular
action
photosensitized
in many
(8-10).
species
photodynamic
anion
(OH.), depoly-
The major biological
02~ , OH., or H202 remain unknownr
Active
superoxide
can also be caused by another molecular species
have been reviewed
lar
enzymatically
oxygen,
superoxide
the
anion
sensitizer
and more
02?,
triplet
commonly
which
interacts
it involves
directly
transfer of
from the triplet sensitizer to ground state oxygen to pro-
duce singlet oxygen
(102).
In the present study, we have Used a dye-sensitized photooxidation
system
oxygen
on HA.
oxygen
is also effective in bringing about changes in HA structure
manifested
to
study
Our
the
results
effect show
for
of
photogenerated
the
first
time
species that
of
singlet
in viscosity and circular dichroism measurements.
MATERIALS AND METHODS Purified hyaluronic acid (Grade I), prepared from human umbilical cord, was obtained from Sigma Chemical Co. HA solutions were prepared by dialysis at 4"C against 0 . 1 M NaCI solution, con895
Vol. 115, No. 3, 1983
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
t a i n i n g the desired solvent c o m p o s i t i o n and h y d r o g e n ion concentration (2). HA c o n c e n t r a t i o n was d e t e r m i n e d by the carbazole reaction method (12). As p h o t o s e n s i t i z e r s we used m e t h y l e n e blue or riboflavin. The photosensitizer was added to the HA s o l u t i o n (0.1 to 0.3 mg/ml) prior to i l l u m i n a t i o n at 37°C with 300 foot candles of w h i t e light from a 15 W D a y l i g h t f l u o r e s c e n t bulb. Controls inc l u d e d HA plus light w i t h o u t p h o t o s e n s i t i z e r , HA plus p h o t o s e n s i t i z e r kept in the dark, and HA plus light and p h o t o s e n s i t i z e r under deaerated conditions. The samples were irradiated for v a r i o u s time periods and used for v i s c o s i t y and c i r c u l a r d i c h r o i s m measurements. V i s c o s i t y was m e a s u r e d in an O s t w a l d - t y p e Cannon v i s e o m e t e r at 25.0 ° ± 0. I°C, and intrinsic v i s c o s i t y values were c a l c u l a t e d as r e p o r t e d p r e v i o u s l y (2). To study the effect of D20 on the c h a n g e in intrinsic v i s c o s i t y of HA, the water in the p h o s p h a t e b u f f e r used for the p r e p a r a t i o n of the HA samples was replaced by D20. Circular dichroism (CD) was recorded in an Aviv s p e c t r o p o l a r i m e t e r model #100 m o d i f i e d from a Cary 60 s p e c t r o p o l a r i m e t e r w i t h a CD a t t a c h m e n t at room temperature using 0.1 to I cm quartz cells.
RESULTS
The blue
is
relative tion.0 in
effect shown
state
of o x y g e n The
superoxide to
droxyl
radical
crease
in
Mcdord 6 and
cher
which
Singlet relative
in
also
is present
and
the
oxygen-mediated because
prevented
processes of the
longer
896
not
generated in large the
irra-
neither quanti-
a known
hy-
inhibit
the
027,
used
by
quantity
to
as
enough
singlet
oxygen
dimethylfuran
of
de-
quen-
and
1,3-
in viscosity.
to be enhanced
lifetime
active
to
that
the d e c r e a s e
are known
involved
be p r e v e n t e d
Mannitol,
scavengers
was
in sufficient
did
However,
102
(5) completely
to H20,
process.
irradia-
prior
not
The
of
each
indicating
is g e n e r a t e d
the
for
HA could
catalase,
in viscosity.
azide
of o x y g e n
mixture
methylene
change.
duration
specific
of
with
viscosity
species
Enzymatically study,
the
reaction
scavenger,
viscosity.
cyclohexadiene
to the
or
solution
increasing
in v i s c o s i t y
change
in this
of
HA
inhibitors
02 - nor H202
(OH')
a decrease sodium
added
dismutase
any
an
terms with
HA,
decrease
of
molecular
of
were
radical
produce
I in
decreased
degradation
superoxide
cause
Fig.
viscosity
diation.
ty
in
illumination
To i d e n t i f y
the
by
of
in D20
iO 2 in D20.
An
Vol. 115, No. 3, 1983
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
361
/",
24
o\
4°', ' \~'\%'N %
20
I
I
,
I
60
,
"~
120
180
Time of irradiation, mill
Fig. I. Viscosity change of purified HA in the presence of methylene blue (--). The samples contained 0.3 m g / m l HA, 10 -4 M methylene blue, and 0.1 M phosphate buffer, pH 7.8, in a total volume of 3 ml. The effect of addition of the following inhibitors and scavengers on the viscosity change is also shown: 15 mM sodium azide (o---l); 2 mM c y c l o h e x a d i e n e (x---x); 0.5 mM dimethylfuran (A--A); 10 u g / m l superoxide dismutase (V--V); 20 p g / m l catalase (o---~); 10 mM m a n n i t o l (*--*). The viscosity change in the p r e s e n c e of D20 (- - -) was measured by preparing the sample buffer in D20 instead of H20.
increased H20
rate
of
in the buffer Table
presence ation H20 hr.
was
I shows
in b u f f e r s
was
about
With
after This
glet
oxygen
in
When
one-third
3
with
the
result
hr, of
its
the
viscosity
before
buffer,
the
decrease
of with
intrinsic value
was
confirms HA
by
viscosity
897
in
about
the
I).
HA
irradi-
of
[n] with
In]
26%
of
with and
for
was
involvement
oxidase of
in the
irradiation
irradiation
xanthine
(Table
and after
The value
after
value
when
of HA solutions
value
the
observed
I).
H20 and D20.
further
treated
control
(Fig.
HA. was
control
degradation
HA was
by D20
of
and r i b o f l a v i n
irradiation;
value.
for
blue
D20-containing
trol
blue.
of
viscosity
intrinsic
prepared
62%
of
replaced
the
of m e t h y l e n e
pronounced
(7)
decrease
16
more
the
con-
of
sin-
methylene
hypoxanthine
decreased
to
about
Vol. 115, No. 3, 1983 Table
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Intrinsic viscosity conditions
I.
[q] of HA solutions
Sample
under various
[q], ml g-i
HA + riboflavin in H20 buffer
(control)
1,380
HA + riboflavin in H20 buffer (irradiated 16 hr) HA + MB in H20 buffer
811
(control)
1,430
HA + MB in H20 buffer (irradiated 16 hr) HA + MB in D20 buffer
890
(control)
1,250
HA + MB in D20 buffer (irradiated 16 hr) HA + hypoxanthine
(0.12 mM)
HA + hypoxanthine
(0.12 mM) + xanthine
oxidase
330 1,553 510
(0.04 units/ml) treated for 3 hr
HA concentration was varied between 0.1 and 0.28 mg/ml for intrinsic viscosity measurements. Dilutions were made with the appropriate buffer. Riboflavin 0oncentration was 10 -5 M. MB concentration was 10 -4 M. Irradiations were done in white light as described in Materials and Methods. The xanthine oxidase reaction was carried out in 0 . 1 M phosphate buffer, pH 6.8. HA, hyaluronic acid; MB, methylene blue
To
see
whether
a
accompanies
the
change
we
CD
spectra
measured
two
characteristic
other was
around
190
observed
studies
in
at
ethanol/80% and
a strong
225
nm
in the with
nm
low
pH.
to pH
These
blue
spectroscopic
CD
change
(2)
with have
band
below
CD
changes (2).
undergoes
near
the
shown
of
negative
an 210
200 nm and represent
To d e t e r m i n e such
898
210
of
a change,
displays and
nm b a n d
an
solution
a positive
7
Previous
unusual
nm b a n d
the
at pH
solvent/water HA
HA
system,
nm
blue.
that
in o r g a n i c
HA
210
methylene
acidification the
solution,
one in
properties
photooxidation
aqueous
bands,
No
2.5,
of H A
in o u r
In
is o b s e r v e d
Upon
conformation
methylene
HA.
irradiation
negative
appear.
of
(1,2).
of H A
water
in
viscosity
laboratory
in the CD s p e c t r a solvent
in
negative
upon
this
change
change mixed in
20%
disappears band
around
a dramatic
alteration
whether
irradiated
the
CD
HA
spectra
at pH
VoI. 115, No. 3, 1 9 8 3
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
% -6 E
0
%
/
-2 -4 -6 I
I
210
2;0
Wavelength
'
2~0
nm
Fig. 2. CD spectra of HA before ( ) and after (---) 4 hr of ~i-at ion with methylene blue. The samples were dialyzed against aqueous (20%, v/v) ethanol, pH 2.5.
2.5
in
20%
ethanol/80%
measured. reduced
After
water
of
irradiation,
to about
one-third
control
the
its
and
positive
intensity
irradiated
CD
band
(Fig.
at
HA
225
were
nm was
2).
DISCUSSION The gen,
decrease
apparently
polymer.
in
viscosity
indicates
However,
a
change
macromolecule.
A drastic
due
to
ascorbic generally tion
of
assumed free
radicals
of
suggested
that
stage,
drastic in
the
ever,
(secondary
the
change
secondary
in
or
during
metal
oxygen.
the
free
structure,
a prolonged
off
tertiary
(13)
radicals, HA
of
related
the
to of
presence
reducing
a a
produc-
reductants CD
studies
least
at
groups,
ini-
causing
a
change
viscosity. occurred.
and (14)
the
a subsequent the
of
It was
through of
at
and
the
of HA, p r e s u m a b -
of
side
oxy-
structure)
occurred
depolymerization
899
weight
also
in
results
the
singlet
ions Fe 3+ and Cu 2+.
structure
thereby
time,
is
autooxidation The
by
molecular
tertiary
noted
the
cleaved
induced
in the v i s c o s i t y
was
generated
randomly
in
depolymerization
molecular
change
after
that
as
viscosity
and the t r a n s i t i o n
reduction
tial
in
depolymerization,
acid
HA,
decrease
change
conformational
ly
a
of
HowIn
the
Vol. 115, No. 3, 1983
current
study,
significant molecule, ly
singlet
indicating
of
HA
(2)
that
to
a
the
the
weight do
not
disappearance)
of a change absence
between
the
of
suffered
225
molecule,
similar
to the change
(14),
structure
major
that
the
research
of
cannot of on
be
the
singlet
the
effect
of
decrease that the
the pos-
be considered. structure
it is likely
that
structure
of the
of Cu 2+ and
ascor-
secondary
tertiary
may occur. show
that
In the
present vessels
in the
only
properties role.
enough on
can
normal
of eye
the
of HA,
The eye
presence
singlet
evidence
species
not
in diabetic of
strong
900
The
of
and
both
body.
cules.
samples
in
the
this
the
On prolonged
some positive
is
provided
depolymerization.
Moreover,
oxygen
probably
must
in t e r t i a r y
photogeneration
ignored.
change,
indicate
samples,
has
blood
as a test
in s e c o n d a r y
in the m o l e c u l a r
riboflavin
from ruptured
possibility
generation
as
such
of
virtual-
reported
change. may
the
was
enough;
structure
is to
changes oxygen
It
in the presence
report
here
solvent,
band
of
depolymerization;
changes
by a minor
organ
used
difference
alteration
cause
photoreceptor
vitreous
some
this
singlet
products
CD
by d e p o l y m e r i z a t i o n of
anion
tosensitizer heme
drastic
purpose
superoxide also
a
followed
The
but
followed
been
large
and u n i r r a d i a t e d
caused
irradiation
nm
of a significant
102 has
acid
is
nm)
by a
conformational
structure.
significant
generated
bic
the
organic
in the tertiary
irradiated
of
conformational
the
(210
remains
a conformational
polymer
this
band
structure
has
HA
acidic
the
in
sibility the
not
(2)
was not followed
CD
phenomenon
solvent
show
has
the
in
of
molecule
In
the s e c o n d a r y
undergoes
helix,
change
intrinsic
integrity
molecule
4-fold
<10,000
the
that
in o r g a n i c
determining
molecular
in
Howeverr
for
(not
oxygen-induced
alteration
unchanged.
change
MW
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
is a
a pho(5)
or
retinopathy, oxygen
(8-10)
for
to warrant
biological
in
the
in vivo further
macromole-
Vol. 115, No. 3, 1 9 8 3 ACKNOWLEDGMENTS: pr0ject EY04342,
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS Supported by NIH grant EY01760, and Charles A. King Trust Fellowship.
NIH
pilot
REFERENCES 1 •
2. 3. 4. 5.
6. 7o
8. 9t 10. 11.
12 13. 14
Chakrabarti, B., and Park, J.W. (1980) CRC Crit. Rev. Biochem. 8, 225-313 (and references therein). Park, J.W., and Chakrabarti, B. (1978) Biopolymers 17, 13231333. Figueroa, N., and Chakrabarti, B. (1978) Biopolymers 17:24152426. Chakrabarti, B, (1981) In Solution Properties of Polysaccharides, Brant DA (ed.). ACS Symposium Series, No. 150. American Chemical Society, Washington, D.C.F pp. 275-292. Berman, E.R. and Voaden, M. (1970) In Biochemistry of the Eye, Graymore CN (ed.). Academic Press, New York, 1970, pp. 373-471. Furthmayr, H. and Timpl, R. (1976) In International Review of Connective Tissue Research, Hall, D.A.. and Jackson, D.S. (eds.), Academic Press, New York, vol. 7, pp. 61-99. McCord, J.M• (1974) Science 185, 529-531. Fridovich, I. (1976) In Free Radicals in Biology, vol. II, Pryor, W.A. (ed.). Aca-demic Press, New York, pp. 239-287. Fridovich, I. (1978) Science 201, 875. Halliwell, B. (1978) Cell Biol. Int. Rep. 2, 113. Foote, C.S. (1976) In Free Radicals in Biology, vol. II, Pryor, W.A. (ed.). Academic Press, New York, pp. 85-133. Bitter, T., and Muir, H.M. (1962) Anal. Biochem. 4, 330-334. Harris, M.J., Herp, A., and Pigman, W. (1971) Arch. Biochem. Biophys. 142, 615-622. Figueroa, N., and Chakrabarti, B. (1977) Invest. Ophthalmol. Vis. Sci. 16(ARVO Suppl.), 67.
901
Vol. 115, No. 3, 1983 September 30, 1983
ROLE OF SINGLET OXYGEN IN THE DEGRADATION OF HYALURONIC ACID Usha P. Andley I and Bireswar Chakrabarti I'2 Eye Research Institute of Retina Foundation 1 and Harvard Medical School, 2 Boston, Massachusetts 02114 Received August 12, 1983
To investigate the effect of singlet oxygen on the molecular properties of hyaluronic acid, the polymer was irradiated in the presence of a dye sensitizer for singlet oxygen. Viscosity and circular dichroism techniques were used to monitor these changes. The relative viscosity of the polymer solution decreased steadily with increasing duration of irradiation, indicating an apparent decrease in molecular weight of hyaluronic acid. Circular dichroism measurements of the irradiated sample, however, did not show any appreciable change in the secondary structure, but do suggest that the generated singlet oxygen changes the tertiary structure and that this change is followed by a minor depolymerization. Hyaluronic acid molecular
primary
ride
units
structure of
alternating (I-4)
molecular
a glycosaminoglycan,
component of vitreous humor,
Its
tory
(HA),
consists
D-glucuronic
8(I+3) have
and
of
acid
8(I+4)
synovial
unbranched and
is a major macrofluid,
skin,
repeating
disaccha-
N-acetyl-D-glucosamine
linkages.
Studies
etc.
in this
with
labora-
shown that the conformation of HA in solution
weight dependent.
This
is
is evident by the fact that the
chiroptical properties of lower and higher oligosaccharides differ (4), and
and
the
conformational
in the presence of Cu 2+ This
change
of
HA
in organic
solvent
(3) cannot be detected with
cular-weight
HA.
phenomenon
to determine
the relationship
must
between
be considered
(2)
low-mole-
in attempts
conformation and biological
function of the molecule. In the aging or pathological vitreous and in synovial fluids, degradaton of HA is known change
(5,6)
to occur,
and this may
lead to a
in conformation of the molecule and thus of the structural
integrity
of
the
tissues.
It is generally
0006-291X/83 $1.50 Copyright © 1983 ~ A c a ~ m ~ Press, ~c. AHr~h~ofreproduction ~ a ~ f o r m r e s e ~ .
894
believed
that depoly-
Vol. 115, No. 3, 1 9 8 3
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
merization of HA occurs through production of free radicals during autooxidation of reductants and the reduction of molecular oxygen. McCord
(7)
(O2~)
reacts
merizing (6),
that
with
HA of
H202
bovine
degeneration
of oxygen, 102,
found
generated
to produce hydroxy radical synovial
singlet oxygen
fluid.
As
(102).
exposure
to
sensitizer singlet
sources of
oxygen
can also be generated
light,
effectsr
a photosensitizer, proceed
via
the
and
produced
oxygen.
triplet
by by
Most
state o f
the
(11).
The to
radicals
produce
free
triplet
may
radicals
or
interact radical
with
a
anions.
can produce univalent reduction of molecufurther
dismutate to H202 and react with H202 to form the hydroxyl
radical
with
Alternatively,
molecular
energy
generate
sensitizer
can
(OH').
to
tissues
it has a much longer lifetime than the excited
substrate
These product
other
various potential sources
or photooxidative
oxidations
because
oxygen
(11),
visible
state
reducing
of molecular
action
photosensitized
in many
(8-10).
species
photodynamic
anion
(OH.), depoly-
The major biological
02~ , OH., or H202 remain unknownr
Active
superoxide
can also be caused by another molecular species
have been reviewed
lar
enzymatically
oxygen,
superoxide
the
anion
sensitizer
and more
02?,
triplet
commonly
which
interacts
it involves
directly
transfer of
from the triplet sensitizer to ground state oxygen to pro-
duce singlet oxygen
(102).
In the present study, we have Used a dye-sensitized photooxidation
system
oxygen
on HA.
oxygen
is also effective in bringing about changes in HA structure
manifested
to
study
Our
the
results
effect show
for
of
photogenerated
the
first
time
species that
of
singlet
in viscosity and circular dichroism measurements.
MATERIALS AND METHODS Purified hyaluronic acid (Grade I), prepared from human umbilical cord, was obtained from Sigma Chemical Co. HA solutions were prepared by dialysis at 4"C against 0 . 1 M NaCI solution, con895
Vol. 115, No. 3, 1983
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
t a i n i n g the desired solvent c o m p o s i t i o n and h y d r o g e n ion concentration (2). HA c o n c e n t r a t i o n was d e t e r m i n e d by the carbazole reaction method (12). As p h o t o s e n s i t i z e r s we used m e t h y l e n e blue or riboflavin. The photosensitizer was added to the HA s o l u t i o n (0.1 to 0.3 mg/ml) prior to i l l u m i n a t i o n at 37°C with 300 foot candles of w h i t e light from a 15 W D a y l i g h t f l u o r e s c e n t bulb. Controls inc l u d e d HA plus light w i t h o u t p h o t o s e n s i t i z e r , HA plus p h o t o s e n s i t i z e r kept in the dark, and HA plus light and p h o t o s e n s i t i z e r under deaerated conditions. The samples were irradiated for v a r i o u s time periods and used for v i s c o s i t y and c i r c u l a r d i c h r o i s m measurements. V i s c o s i t y was m e a s u r e d in an O s t w a l d - t y p e Cannon v i s e o m e t e r at 25.0 ° ± 0. I°C, and intrinsic v i s c o s i t y values were c a l c u l a t e d as r e p o r t e d p r e v i o u s l y (2). To study the effect of D20 on the c h a n g e in intrinsic v i s c o s i t y of HA, the water in the p h o s p h a t e b u f f e r used for the p r e p a r a t i o n of the HA samples was replaced by D20. Circular dichroism (CD) was recorded in an Aviv s p e c t r o p o l a r i m e t e r model #100 m o d i f i e d from a Cary 60 s p e c t r o p o l a r i m e t e r w i t h a CD a t t a c h m e n t at room temperature using 0.1 to I cm quartz cells.
RESULTS
The blue
is
relative tion.0 in
effect shown
state
of o x y g e n The
superoxide to
droxyl
radical
crease
in
Mcdord 6 and
cher
which
Singlet relative
in
also
is present
and
the
oxygen-mediated because
prevented
processes of the
longer
896
not
generated in large the
irra-
neither quanti-
a known
hy-
inhibit
the
027,
used
by
quantity
to
as
enough
singlet
oxygen
dimethylfuran
of
de-
quen-
and
1,3-
in viscosity.
to be enhanced
lifetime
active
to
that
the d e c r e a s e
are known
involved
be p r e v e n t e d
Mannitol,
scavengers
was
in sufficient
did
However,
102
(5) completely
to H20,
process.
irradia-
prior
not
The
of
each
indicating
is g e n e r a t e d
the
for
HA could
catalase,
in viscosity.
azide
of o x y g e n
mixture
methylene
change.
duration
specific
of
with
viscosity
species
Enzymatically study,
the
reaction
scavenger,
viscosity.
cyclohexadiene
to the
or
solution
increasing
in v i s c o s i t y
change
in this
of
HA
inhibitors
02 - nor H202
(OH')
a decrease sodium
added
dismutase
any
an
terms with
HA,
decrease
of
molecular
of
were
radical
produce
I in
decreased
degradation
superoxide
cause
Fig.
viscosity
diation.
ty
in
illumination
To i d e n t i f y
the
by
of
in D20
iO 2 in D20.
An
Vol. 115, No. 3, 1983
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
361
/",
24
o\
4°', ' \~'\%'N %
20
I
I
,
I
60
,
"~
120
180
Time of irradiation, mill
Fig. I. Viscosity change of purified HA in the presence of methylene blue (--). The samples contained 0.3 m g / m l HA, 10 -4 M methylene blue, and 0.1 M phosphate buffer, pH 7.8, in a total volume of 3 ml. The effect of addition of the following inhibitors and scavengers on the viscosity change is also shown: 15 mM sodium azide (o---l); 2 mM c y c l o h e x a d i e n e (x---x); 0.5 mM dimethylfuran (A--A); 10 u g / m l superoxide dismutase (V--V); 20 p g / m l catalase (o---~); 10 mM m a n n i t o l (*--*). The viscosity change in the p r e s e n c e of D20 (- - -) was measured by preparing the sample buffer in D20 instead of H20.
increased H20
rate
of
in the buffer Table
presence ation H20 hr.
was
I shows
in b u f f e r s
was
about
With
after This
glet
oxygen
in
When
one-third
3
with
the
result
hr, of
its
the
viscosity
before
buffer,
the
decrease
of with
intrinsic value
was
confirms HA
by
viscosity
897
in
about
the
I).
HA
irradi-
of
[n] with
In]
26%
of
with and
for
was
involvement
oxidase of
in the
irradiation
irradiation
xanthine
(Table
and after
The value
after
value
when
of HA solutions
value
the
observed
I).
H20 and D20.
further
treated
control
(Fig.
HA. was
control
degradation
HA was
by D20
of
and r i b o f l a v i n
irradiation;
value.
for
blue
D20-containing
trol
blue.
of
viscosity
intrinsic
prepared
62%
of
replaced
the
of m e t h y l e n e
pronounced
(7)
decrease
16
more
the
con-
of
sin-
methylene
hypoxanthine
decreased
to
about
Vol. 115, No. 3, 1983 Table
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Intrinsic viscosity conditions
I.
[q] of HA solutions
Sample
under various
[q], ml g-i
HA + riboflavin in H20 buffer
(control)
1,380
HA + riboflavin in H20 buffer (irradiated 16 hr) HA + MB in H20 buffer
811
(control)
1,430
HA + MB in H20 buffer (irradiated 16 hr) HA + MB in D20 buffer
890
(control)
1,250
HA + MB in D20 buffer (irradiated 16 hr) HA + hypoxanthine
(0.12 mM)
HA + hypoxanthine
(0.12 mM) + xanthine
oxidase
330 1,553 510
(0.04 units/ml) treated for 3 hr
HA concentration was varied between 0.1 and 0.28 mg/ml for intrinsic viscosity measurements. Dilutions were made with the appropriate buffer. Riboflavin 0oncentration was 10 -5 M. MB concentration was 10 -4 M. Irradiations were done in white light as described in Materials and Methods. The xanthine oxidase reaction was carried out in 0 . 1 M phosphate buffer, pH 6.8. HA, hyaluronic acid; MB, methylene blue
To
see
whether
a
accompanies
the
change
we
CD
spectra
measured
two
characteristic
other was
around
190
observed
studies
in
at
ethanol/80% and
a strong
225
nm
in the with
nm
low
pH.
to pH
These
blue
spectroscopic
CD
change
(2)
with have
band
below
CD
changes (2).
undergoes
near
the
shown
of
negative
an 210
200 nm and represent
To d e t e r m i n e such
898
210
of
a change,
displays and
nm b a n d
an
solution
a positive
7
Previous
unusual
nm b a n d
the
at pH
solvent/water HA
HA
system,
nm
blue.
that
in o r g a n i c
HA
210
methylene
acidification the
solution,
one in
properties
photooxidation
aqueous
bands,
No
2.5,
of H A
in o u r
In
is o b s e r v e d
Upon
conformation
methylene
HA.
irradiation
negative
appear.
of
(1,2).
of H A
water
in
viscosity
laboratory
in the CD s p e c t r a solvent
in
negative
upon
this
change
change mixed in
20%
disappears band
around
a dramatic
alteration
whether
irradiated
the
CD
HA
spectra
at pH
VoI. 115, No. 3, 1 9 8 3
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
% -6 E
0
%
/
-2 -4 -6 I
I
210
2;0
Wavelength
'
2~0
nm
Fig. 2. CD spectra of HA before ( ) and after (---) 4 hr of ~i-at ion with methylene blue. The samples were dialyzed against aqueous (20%, v/v) ethanol, pH 2.5.
2.5
in
20%
ethanol/80%
measured. reduced
After
water
of
irradiation,
to about
one-third
control
the
its
and
positive
intensity
irradiated
CD
band
(Fig.
at
HA
225
were
nm was
2).
DISCUSSION The gen,
decrease
apparently
polymer.
in
viscosity
indicates
However,
a
change
macromolecule.
A drastic
due
to
ascorbic generally tion
of
assumed free
radicals
of
suggested
that
stage,
drastic in
the
ever,
(secondary
the
change
secondary
in
or
during
metal
oxygen.
the
free
structure,
a prolonged
off
tertiary
(13)
radicals, HA
of
related
the
to of
presence
reducing
a a
produc-
reductants CD
studies
least
at
groups,
ini-
causing
a
change
viscosity. occurred.
and (14)
the
a subsequent the
of
It was
through of
at
and
the
of HA, p r e s u m a b -
of
side
oxy-
structure)
occurred
depolymerization
899
weight
also
in
results
the
singlet
ions Fe 3+ and Cu 2+.
structure
thereby
time,
is
autooxidation The
by
molecular
tertiary
noted
the
cleaved
induced
in the v i s c o s i t y
was
generated
randomly
in
depolymerization
molecular
change
after
that
as
viscosity
and the t r a n s i t i o n
reduction
tial
in
depolymerization,
acid
HA,
decrease
change
conformational
ly
a
of
HowIn
the
Vol. 115, No. 3, 1983
current
study,
significant molecule, ly
singlet
indicating
of
HA
(2)
that
to
a
the
the
weight do
not
disappearance)
of a change absence
between
the
of
suffered
225
molecule,
similar
to the change
(14),
structure
major
that
the
research
of
cannot of on
be
the
singlet
the
effect
of
decrease that the
the pos-
be considered. structure
it is likely
that
structure
of the
of Cu 2+ and
ascor-
secondary
tertiary
may occur. show
that
In the
present vessels
in the
only
properties role.
enough on
can
normal
of eye
the
of HA,
The eye
presence
singlet
evidence
species
not
in diabetic of
strong
900
The
of
and
both
body.
cules.
samples
in
the
this
the
On prolonged
some positive
is
provided
depolymerization.
Moreover,
oxygen
probably
must
in t e r t i a r y
photogeneration
ignored.
change,
indicate
samples,
has
blood
as a test
in s e c o n d a r y
in the m o l e c u l a r
riboflavin
from ruptured
possibility
generation
as
such
of
virtual-
reported
change. may
the
was
enough;
structure
is to
changes oxygen
It
in the presence
report
here
solvent,
band
of
depolymerization;
changes
by a minor
organ
used
difference
alteration
cause
photoreceptor
vitreous
some
this
singlet
products
CD
by d e p o l y m e r i z a t i o n of
anion
tosensitizer heme
drastic
purpose
superoxide also
a
followed
The
but
followed
been
large
and u n i r r a d i a t e d
caused
irradiation
nm
of a significant
102 has
acid
is
nm)
by a
conformational
structure.
significant
generated
bic
the
organic
in the tertiary
irradiated
of
conformational
the
(210
remains
a conformational
polymer
this
band
structure
has
HA
acidic
the
in
sibility the
not
(2)
was not followed
CD
phenomenon
solvent
show
has
the
in
of
molecule
In
the s e c o n d a r y
undergoes
helix,
change
intrinsic
integrity
molecule
4-fold
<10,000
the
that
in o r g a n i c
determining
molecular
in
Howeverr
for
(not
oxygen-induced
alteration
unchanged.
change
MW
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
is a
a pho(5)
or
retinopathy, oxygen
(8-10)
for
to warrant
biological
in
the
in vivo further
macromole-
Vol. 115, No. 3, 1 9 8 3 ACKNOWLEDGMENTS: pr0ject EY04342,
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS Supported by NIH grant EY01760, and Charles A. King Trust Fellowship.
NIH
pilot
REFERENCES 1 •
2. 3. 4. 5.
6. 7o
8. 9t 10. 11.
12 13. 14
Chakrabarti, B., and Park, J.W. (1980) CRC Crit. Rev. Biochem. 8, 225-313 (and references therein). Park, J.W., and Chakrabarti, B. (1978) Biopolymers 17, 13231333. Figueroa, N., and Chakrabarti, B. (1978) Biopolymers 17:24152426. Chakrabarti, B, (1981) In Solution Properties of Polysaccharides, Brant DA (ed.). ACS Symposium Series, No. 150. American Chemical Society, Washington, D.C.F pp. 275-292. Berman, E.R. and Voaden, M. (1970) In Biochemistry of the Eye, Graymore CN (ed.). Academic Press, New York, 1970, pp. 373-471. Furthmayr, H. and Timpl, R. (1976) In International Review of Connective Tissue Research, Hall, D.A.. and Jackson, D.S. (eds.), Academic Press, New York, vol. 7, pp. 61-99. McCord, J.M• (1974) Science 185, 529-531. Fridovich, I. (1976) In Free Radicals in Biology, vol. II, Pryor, W.A. (ed.). Aca-demic Press, New York, pp. 239-287. Fridovich, I. (1978) Science 201, 875. Halliwell, B. (1978) Cell Biol. Int. Rep. 2, 113. Foote, C.S. (1976) In Free Radicals in Biology, vol. II, Pryor, W.A. (ed.). Academic Press, New York, pp. 85-133. Bitter, T., and Muir, H.M. (1962) Anal. Biochem. 4, 330-334. Harris, M.J., Herp, A., and Pigman, W. (1971) Arch. Biochem. Biophys. 142, 615-622. Figueroa, N., and Chakrabarti, B. (1977) Invest. Ophthalmol. Vis. Sci. 16(ARVO Suppl.), 67.
901