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Metachromasia: An explanation of the colour change produced in dyes by heparin and other substances
THROMBOSIS Printed
RESEARCH in the United
LETTER
METACHROMASIA: PRODUCED
vo1.2, PP* Pergamon
States
9 1973
Press,
Inc.
TO THE EDITORS-IN-CHIEF
AN EXPLANATION
IN DYES
3’77-382
BY HEPARIN
OF THE COLOUR AND OTHER
CHANGE
SUBSTANCES
A.
Wollin and L. B. Jaques Hemostasis-Thrombosis Research Unit, Department College of Medicine, University of Saskatchewan, Saskatchewan, Canada S7N OWO
(Received
6.12.1.972; Accepted
by
in revised Editor A.L.
of Physiology, Saskatoon,
form 16.3.1973. Copley)
Al 3STRACT Previous explanations given for metachromasia have been the dyestacking model of Bradley and Wolf and the pairing concept of Young, Phillips and Balazs. The special properties of heparin and heparinoids in producing metachromasia are reviewed. To explain these observations, a model combining the dye-stacking and pairing concepts is proposed. The dye-dimer interacts with suitable ionic sites provided by the chromotrope. The loose ionic interaction alters the electron mobility of the dye-dimer, and this results in the colour change. This is illustrated with the absorption spectra recorded as.differences between dye and dye-chromotrope in a double beam recording spectrophotometer. A metachromatic band shift was found with the dye in 3.8 M NaCl so that the chromotrope can be either a polyanion such as heparin or an ion cage formed by a strong electrolyte.
The colour
change in dyes,
well known to readers cells
and Wolf anion,
of Thrombosis
and with mucopolys
for the phenomenon
Supported
accharides
Research, Two
,
by a dye-dye
by a grant-in-aid
interaction interaction
from
explanations
is assumed for
the Medical
377
is a phenomenon
as associated
many
between adjacent
Research
with mast
have been proposed
In the dye-stacking
of metachromasia.
(1) an electrostatic
followed
known as metachromasia
model dye
of Bradley and poly-
dye molecules
Council
of Canada.
378
METACHROMASIA
resulting
in a change in absorption
cept of Young, rise
Phillips
as a result
ion site which changes of the dye.
Phillips
ious experimental heparinoids
ces
mental oids,
of practical and mast
dye with acid-base sorption
spectra
of the dye. The position
concentrations
of heparin
on paper Mass
Law relationship
times
the concentration
tween a series according
an excess
concentration
by inorganic sion from
an increase
(6, 15).
absorption
(lkg/ml)in
concentration
in excess
(8).
strength
Dehydration to the ti -band
suppresses (16).
(6),
a simple
is incr eas ed ten
an interaction
for
but this requires
The reaction
is suppressed
(12, 13, 14) but suppresion in the medium
than with heparin
metachromasiawith obtained
be-
would be suppressed
heparin
and hydrogen
Products
me-
solution
of that required
temperature
with other mucopolysaccharides
producing
there is no change in the
of a thousand-fold
in ionic
wave-length.
gel (11) and shows
by excess
and increasing
characteristic
aqueous
interaction
present
ab-
of heparin-heparin-
which involves
dye molecules,
on
can be seen with very low
for equilibrium,
hypothesis
instudies
those by the same
at a shorter
is suppressed
electrolytes
much greater oids
required
from
in the presence
When heparin
(6, 12).
experi-
and heparin-
reaction
for the substance
(10) and in agarose
The M-band
substan-
(6). As is well-known,
aA-band
and heparinoids
of adjacent
inducing
and B-bands,
The reaction
to the amount of heparin
equilibrium.
shifts
produces
sulfate..
For the stacking
M -band.
and
we have made the follow-
different
showd,-
about 120 nm less
chromatograms
system
Heparins
with heparin
publications,
is characteristic
of heparin
to a-
fail to explain var-
to metachromasia.
change is definitely
95 nm for dermatan
models
to those using this colour
of the dye in solution
8, 9),
in the chromophoric
to other metachromatic
In previous
of the/.+band
tachromasia(7,
symmetry
and oxidation-reduction
Addition
con-
between the dye and the polyan-
on metachromasia
importance cells.
change is assumed
attention has been paid to the numerous
reported
The colour
ing points.
oids,
little
In the pairing
this colour change at very low concentrations
unfavorable
However,
the colour
relating
Vo1.2,No.4
of the dye.
out that both these
observations
observations
heparin
the energetic
are able to produce
(4, 5).
(2),
interaction
(3) points
and under conditions
spectrum
and Balazs
of electrostatic
BY HEPARIN
is
and heparin-
a shift of light
from heparin
by enzy-
METACHROMASIA BY HEPARIN
vo1.2,No.b
matic
degradation
disaccharide
(17) examined
fragments
Full metachromatic arin hexasaccharide.
solution.
tion or moderate tration
slightly
occurs,
depends
of electrolytes
cepts by suggesting
thatmetachromasia
combining
by being interposed
posed by them.
Due to the resonance
with the negatively
charged
group in the thiazine
dyes from
and thus reduces
electron
causes
the dye-‘dimer.
The strength
Polyanions
reported
The dye-dimer
with the negatively
the new absorption
band.
and the charge density metachromatic
activity
the metachroma-
via the amino groups which partially
charged
associated of heparin
blocks system
delocalization.
of anionic
sites
coils
of the structural
observed,
for the extent of the band shift.
with
to reduce has been
on each end coil can induce arrangement
with the coil are responsible and heparinoids
of hep-
for interaction
charge
in
at a short-
activity
groups of the heparin
features
of the
is reflected
coils with heparin positive
the N-
The loss
light energy
metachromatic
with a partial
Special
of the bonding is responsible
one would expect
We believe
to absorb
for loose
as pro-
and allow looseinteraction
have a tendency to form loose Evidence
reacting
and Geddes (18), although
of the binding to the N-group
arrangement
repulsion.
interacting
d-electron
con-
of water molecules
This interaction
We explain the exceptional
intermolecular (20).
molecule.
the dye molecule
arin as due to the suitable
by a dye-dimer
being part of the conjugation
dye chromophore
in the band shift.
and pairing
in the dye molecules,
of this interaction
chromophore.
(19).
concen-
consistentwith
between the two dye molecules
heparin
are part of the dye’s
er wave-length
bysheppard
on each end of the dimer
tic band shift to be the result
mobility
the dye-stacking
The presence
unit as suggested
charge to form
dehydra-
The limiting
in a manner
is produced
manner.
not necessarily
a partial
(6,12).
phenomenon
we propose
the dimer
by ethanol,
com-
on the nature of the polyanion.
these observations,
stabilizes
of dye-polyanion
is not destroyed
To explain the metachromatic
with the polyanion in a loose
was given by the hep-
between dye and polyanion which does not
This interaction
of electrolyte
to heparin,
in the precipitation
concentrations
and
with the dye with no metachromasia.
as compared
Interaction
lead to metachromasia plex from
by us showed that the monosaccharide
reacted
activity
379
for the high The strength Interaction
METACHROMASIA BY HEPARIN
380
without development an ion-pairing Fig. between Three those
of a metachromatic
of dye and polyanion
1 illustrates
some
the absorption
types
spectra
named these d, B and ,q -bands dimer
and metachromatic
ute azure A solution creased
transmission)
an increase
Addition
tion for both band.
with appearance
the change in in the first
4.7,qg/ml
shoulder
dye
of 0.5
(Curve
due to reduction
the*-
2) reduced
fortt and
of dimer,
Increasing
of the dye-
light absorp-
now occurring
at theA B -bands,
not to changes heparin concentrac
and p -bands, FIG.
(in-
at the 6-band,i.e.
at the expense
was the same
further
M NaCl to a dil-
of the #-band
of light absorption
of the monomer.
(Curve 3) decreased
dyes.
to
them to the dye monomer,
with light absorption
b -band was mainly
substance.
(21)
Addition
of heparin
recorded
which corresponded
light absorption
in light absorption
vibrational
were
Michaelis
of the dye-dimer
of 0.7Aglml
As thedecrease
tionto
1) reduced
U - and b-bands
Differences
and related
of the dye.
of
interaction.
isolated,
and attributed
in the concentration
monomer.
clearly
of thiazine
form
(Curve
the result
of dye and of dye-metachromatic
bands were
of the absorption
is conceivably
without dye-dye
of these points.
spectra
of spectral
colour
Vo1.2,~0.4
andincreased
1
Spectral Differences in Light Absorption Between Azure A andAzureAWith NaCl or Heparin.
01.
450
.
.
500
*
*‘**a.’
550 WO”.I.npth
600 (ml
700
Spectra recorded with a double beam spectrophotometer (Beckman DK-2). A deflection below 100% transmission indicates increased light absorption in the sample cell; above 100% transmission, decreased absorption. Reference cell: azure A solution 10 Mg/m.l. Sample cell: R - azure A solution 10 fig/ml; 1- plus 3.1 x 104,c(g/ml (0.5 M) NaCl; 2 - plus 0.7Ag/ml heparin; 3 - plus 4.7 &g/ml heparin; 4 - plus 2.2 x lo5 ,qg/ml NaCl (3.8 M). Azure A (National Aniline, certificate NAz 19) purified by the method of Pal and Schubert (22). A series of heparin preparations were studied. Results reported for Heparin Lederle Lot 1804.
MBTACHROMASIA BY HEPARIN
vo1.2,~0.4
the light absorption The formation
475 nm (Curve not essential
4) with the dye in 3 M NaCl.
band shift results charge
system
similar
from
of the dye-dimer, to that produced
were
utilized
and
in sequence;
only and the dye-
equilibrium.
in the recording
of a r~(-band
It is evident that polyanions
as is usually
a great number
band.
of both dye-dimer
the dye-dimer
to maintain
a new observation
for metachromasia,
partial
removed
was reduced
1 also reports
at the expense
that the dye species
of the M-band
concentration
Fig.
occurred
It is probable
i. e. the formation monomer
in the /rc-band with no shift in the metachromatic
of the ~-band
dye-monomer.
38 1
thought.
of ions forming
thus inducing
an effect
We suggest
at are
this
a cage around the on the conjugation
by the polyanion. REFERENCES
1.
BRADLEY, D. F. and WOLF, M. K. Aggregation of dyes bound to polyProc. Natl.Acad.Sci., U.S.A. 45, 944, 1959. anions. -
Polyanions and their 2. YOUNG, M.D. a PHILLIPS, G. 0. and BALAZS, E. A. complexes. I. Thermodynamic studies of heparin-azure A complexes in Biochim. Biophys. Acta: 141, 374, 1967. solution. 3. PHILLIPS, G. 0. Interaction between glycosaminoglycans and organic cations. In: Chemistry and Molecular Biology of the Intercellular Mat* E.A. Balazs (Ed.), Vol. II, p. 1033. London: Academic Press, 1970. 4.
JAQUES, L. B. Anticoagulant Therapy: Pharmacological Chapter 3, Springfield, Ill: C.C. Thomas, 1965.
Principles.
5.
JAQUES, L. B. The pharmacology of heparin and heparinoids. gress in Medicinal Chemistry, G.P. Ellis and G. B. West (Ed.) 146. London: Butterworths, 1967.
6.
The metaJAQUES, L. B., BRUCE-MITFORD, M. and RICKER, A. G. chromatic activity of heparin. Rev. Canad. de Biol. : 5, 740, 1947.
7.
JAQUES, L. B. and WOLLIN, A. A modified method for the calorimetric determination of heparin. Can. J. Physiol. Pharmacol. : 45, 787, 1967.
8.
JARRETT, C. L. and JAQUES, L. B. The anticoagulant and metachromatic properties of the heparinoid G31150 in dogs. Can. J.Physiol. Pharmacol. : 42, 93, 1964.
In: ProVol. 5,
MEI’ACHROMASIA BY HEPARIN
382
9.
10.
11.
JARRETT, C. L. and JAQUES, L. B. Effect of i.v. and oral administration of heparinoids G31150, G31150-A and of nitrilotriacetic acid on blood coagulation. Thromb. Diath. Haem. : 25, 187, 1971. JAQUES, L. B. and BELL, H. J. The determination of Biochem. Anal.: 1, 253, 1959. JAQUES,
L. B.,
BALLIEUX,
A microelectrophoresis L.W. 46, 351, 1968. Pharmacol.: 12.
JAQUES, Biochem.
13.
Vo1.2,~0.4
L. B. J. : 37,
The reaction 189,
WOLLIN, A. Color Thesis, University able from
of heparin.
R. E., DIETRICH, C. P. method for heparin.
of heparin
with proteins
Methods
and KAVANAGH, Can. J. Physiol.
and complex
bases.
1943.
changes in thiazine dyes induced by heparin. of Saskatchewan, Saskatoon, Canada, 1970.
the University
of Saskatchewan
M. SC. Avail-
Library.
14.
WOLLIN, A. and JAQUES, L. B. Analysis of heparin-azure A metachro: 50, 65, 1972. Can. J. Physiol. Pharmacol. masy in agarose gel.
15.
JAQUES, 2, 643,
16.
JAQUES, L. B. and WOLLIN, A. heparins by microelectrophoresis istry, in press, 1972.
17.
DIETRICH, C. P. Novel heparin degradation products. Isolation and characterization of novel disaccharides and oligosaccharides produced from heparin by bacterial degradation. Biochem. J. : 108, 647, 1958.
18.
Effect of solvents upon the abSHEPPARD, S. E. and GEDDES, A. L. Water as a solvent: a .common pattern. sorption spectra of dyes. IV. J. Am. Chem.Soc.: 66, 1995, 1944.
19.
Application of Absorption Spectroscopy DYER, J.R. pounds. p. 11, Englewood Cliffs, N. J. : Prentice-Hall,
20.
STONE, A. L. and MOSS, H. Anomalous rotatory dispersion of metachromatic mucopolysaccharide-dye complex. II. Heparin-methylene 136, 56, 1967. blue complexes at acidic pH. Biochim. Biophys.Acta:
21.
MICHAELIS, L. Reversible polymerization J. Phys. Colloid Chem.: 54, 1, 1950.
22.
Measurement PAL, M. K. and SCHUBERT, M. J.Am. Chem.Soc.: 84, chromatic compounds.
L. B. 1961.
Heparin
and the mast
cell.
Can. J. Biochem.
Identification on agarose
Physiol.
:
and measurement of gel. Analytical Biochem-
of Organic ComInc. 1965.
and molecular
aggregation.
of the stability 4384, 1962.
of meta-
RESEARCH in the United
LETTER
METACHROMASIA: PRODUCED
vo1.2, PP* Pergamon
States
9 1973
Press,
Inc.
TO THE EDITORS-IN-CHIEF
AN EXPLANATION
IN DYES
3’77-382
BY HEPARIN
OF THE COLOUR AND OTHER
CHANGE
SUBSTANCES
A.
Wollin and L. B. Jaques Hemostasis-Thrombosis Research Unit, Department College of Medicine, University of Saskatchewan, Saskatchewan, Canada S7N OWO
(Received
6.12.1.972; Accepted
by
in revised Editor A.L.
of Physiology, Saskatoon,
form 16.3.1973. Copley)
Al 3STRACT Previous explanations given for metachromasia have been the dyestacking model of Bradley and Wolf and the pairing concept of Young, Phillips and Balazs. The special properties of heparin and heparinoids in producing metachromasia are reviewed. To explain these observations, a model combining the dye-stacking and pairing concepts is proposed. The dye-dimer interacts with suitable ionic sites provided by the chromotrope. The loose ionic interaction alters the electron mobility of the dye-dimer, and this results in the colour change. This is illustrated with the absorption spectra recorded as.differences between dye and dye-chromotrope in a double beam recording spectrophotometer. A metachromatic band shift was found with the dye in 3.8 M NaCl so that the chromotrope can be either a polyanion such as heparin or an ion cage formed by a strong electrolyte.
The colour
change in dyes,
well known to readers cells
and Wolf anion,
of Thrombosis
and with mucopolys
for the phenomenon
Supported
accharides
Research, Two
,
by a dye-dye
by a grant-in-aid
interaction interaction
from
explanations
is assumed for
the Medical
377
is a phenomenon
as associated
many
between adjacent
Research
with mast
have been proposed
In the dye-stacking
of metachromasia.
(1) an electrostatic
followed
known as metachromasia
model dye
of Bradley and poly-
dye molecules
Council
of Canada.
378
METACHROMASIA
resulting
in a change in absorption
cept of Young, rise
Phillips
as a result
ion site which changes of the dye.
Phillips
ious experimental heparinoids
ces
mental oids,
of practical and mast
dye with acid-base sorption
spectra
of the dye. The position
concentrations
of heparin
on paper Mass
Law relationship
times
the concentration
tween a series according
an excess
concentration
by inorganic sion from
an increase
(6, 15).
absorption
(lkg/ml)in
concentration
in excess
(8).
strength
Dehydration to the ti -band
suppresses (16).
(6),
a simple
is incr eas ed ten
an interaction
for
but this requires
The reaction
is suppressed
(12, 13, 14) but suppresion in the medium
than with heparin
metachromasiawith obtained
be-
would be suppressed
heparin
and hydrogen
Products
me-
solution
of that required
temperature
with other mucopolysaccharides
producing
there is no change in the
of a thousand-fold
in ionic
wave-length.
gel (11) and shows
by excess
and increasing
characteristic
aqueous
interaction
present
ab-
of heparin-heparin-
which involves
dye molecules,
on
can be seen with very low
for equilibrium,
hypothesis
instudies
those by the same
at a shorter
is suppressed
electrolytes
much greater oids
required
from
in the presence
When heparin
(6, 12).
experi-
and heparin-
reaction
for the substance
(10) and in agarose
The M-band
substan-
(6). As is well-known,
aA-band
and heparinoids
of adjacent
inducing
and B-bands,
The reaction
to the amount of heparin
equilibrium.
shifts
produces
sulfate..
For the stacking
M -band.
and
we have made the follow-
different
showd,-
about 120 nm less
chromatograms
system
Heparins
with heparin
publications,
is characteristic
of heparin
to a-
fail to explain var-
to metachromasia.
change is definitely
95 nm for dermatan
models
to those using this colour
of the dye in solution
8, 9),
in the chromophoric
to other metachromatic
In previous
of the/.+band
tachromasia(7,
symmetry
and oxidation-reduction
Addition
con-
between the dye and the polyan-
on metachromasia
importance cells.
change is assumed
attention has been paid to the numerous
reported
The colour
ing points.
oids,
little
In the pairing
this colour change at very low concentrations
unfavorable
However,
the colour
relating
Vo1.2,No.4
of the dye.
out that both these
observations
observations
heparin
the energetic
are able to produce
(4, 5).
(2),
interaction
(3) points
and under conditions
spectrum
and Balazs
of electrostatic
BY HEPARIN
is
and heparin-
a shift of light
from heparin
by enzy-
METACHROMASIA BY HEPARIN
vo1.2,No.b
matic
degradation
disaccharide
(17) examined
fragments
Full metachromatic arin hexasaccharide.
solution.
tion or moderate tration
slightly
occurs,
depends
of electrolytes
cepts by suggesting
thatmetachromasia
combining
by being interposed
posed by them.
Due to the resonance
with the negatively
charged
group in the thiazine
dyes from
and thus reduces
electron
causes
the dye-‘dimer.
The strength
Polyanions
reported
The dye-dimer
with the negatively
the new absorption
band.
and the charge density metachromatic
activity
the metachroma-
via the amino groups which partially
charged
associated of heparin
blocks system
delocalization.
of anionic
sites
coils
of the structural
observed,
for the extent of the band shift.
with
to reduce has been
on each end coil can induce arrangement
with the coil are responsible and heparinoids
of hep-
for interaction
charge
in
at a short-
activity
groups of the heparin
features
of the
is reflected
coils with heparin positive
the N-
The loss
light energy
metachromatic
with a partial
Special
of the bonding is responsible
one would expect
We believe
to absorb
for loose
as pro-
and allow looseinteraction
have a tendency to form loose Evidence
reacting
and Geddes (18), although
of the binding to the N-group
arrangement
repulsion.
interacting
d-electron
con-
of water molecules
This interaction
We explain the exceptional
intermolecular (20).
molecule.
the dye molecule
arin as due to the suitable
by a dye-dimer
being part of the conjugation
dye chromophore
in the band shift.
and pairing
in the dye molecules,
of this interaction
chromophore.
(19).
concen-
consistentwith
between the two dye molecules
heparin
are part of the dye’s
er wave-length
bysheppard
on each end of the dimer
tic band shift to be the result
mobility
the dye-stacking
The presence
unit as suggested
charge to form
dehydra-
The limiting
in a manner
is produced
manner.
not necessarily
a partial
(6,12).
phenomenon
we propose
the dimer
by ethanol,
com-
on the nature of the polyanion.
these observations,
stabilizes
of dye-polyanion
is not destroyed
To explain the metachromatic
with the polyanion in a loose
was given by the hep-
between dye and polyanion which does not
This interaction
of electrolyte
to heparin,
in the precipitation
concentrations
and
with the dye with no metachromasia.
as compared
Interaction
lead to metachromasia plex from
by us showed that the monosaccharide
reacted
activity
379
for the high The strength Interaction
METACHROMASIA BY HEPARIN
380
without development an ion-pairing Fig. between Three those
of a metachromatic
of dye and polyanion
1 illustrates
some
the absorption
types
spectra
named these d, B and ,q -bands dimer
and metachromatic
ute azure A solution creased
transmission)
an increase
Addition
tion for both band.
with appearance
the change in in the first
4.7,qg/ml
shoulder
dye
of 0.5
(Curve
due to reduction
the*-
2) reduced
fortt and
of dimer,
Increasing
of the dye-
light absorp-
now occurring
at theA B -bands,
not to changes heparin concentrac
and p -bands, FIG.
(in-
at the 6-band,i.e.
at the expense
was the same
further
M NaCl to a dil-
of the #-band
of light absorption
of the monomer.
(Curve 3) decreased
dyes.
to
them to the dye monomer,
with light absorption
b -band was mainly
substance.
(21)
Addition
of heparin
recorded
which corresponded
light absorption
in light absorption
vibrational
were
Michaelis
of the dye-dimer
of 0.7Aglml
As thedecrease
tionto
1) reduced
U - and b-bands
Differences
and related
of the dye.
of
interaction.
isolated,
and attributed
in the concentration
monomer.
clearly
of thiazine
form
(Curve
the result
of dye and of dye-metachromatic
bands were
of the absorption
is conceivably
without dye-dye
of these points.
spectra
of spectral
colour
Vo1.2,~0.4
andincreased
1
Spectral Differences in Light Absorption Between Azure A andAzureAWith NaCl or Heparin.
01.
450
.
.
500
*
*‘**a.’
550 WO”.I.npth
600 (ml
700
Spectra recorded with a double beam spectrophotometer (Beckman DK-2). A deflection below 100% transmission indicates increased light absorption in the sample cell; above 100% transmission, decreased absorption. Reference cell: azure A solution 10 Mg/m.l. Sample cell: R - azure A solution 10 fig/ml; 1- plus 3.1 x 104,c(g/ml (0.5 M) NaCl; 2 - plus 0.7Ag/ml heparin; 3 - plus 4.7 &g/ml heparin; 4 - plus 2.2 x lo5 ,qg/ml NaCl (3.8 M). Azure A (National Aniline, certificate NAz 19) purified by the method of Pal and Schubert (22). A series of heparin preparations were studied. Results reported for Heparin Lederle Lot 1804.
MBTACHROMASIA BY HEPARIN
vo1.2,~0.4
the light absorption The formation
475 nm (Curve not essential
4) with the dye in 3 M NaCl.
band shift results charge
system
similar
from
of the dye-dimer, to that produced
were
utilized
and
in sequence;
only and the dye-
equilibrium.
in the recording
of a r~(-band
It is evident that polyanions
as is usually
a great number
band.
of both dye-dimer
the dye-dimer
to maintain
a new observation
for metachromasia,
partial
removed
was reduced
1 also reports
at the expense
that the dye species
of the M-band
concentration
Fig.
occurred
It is probable
i. e. the formation monomer
in the /rc-band with no shift in the metachromatic
of the ~-band
dye-monomer.
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