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Nitrogen mustard: An “in vitro” inhibitor of erythrocyte sickling
Vol.
48,
No.
BIOCHEMICAL
3, 1972
NITROGEN
MUSTARD:
AN
“IN
AND
VITRO”
BIOPHYSICAL
INHIBITOR
OF
Eugene F. Roth, Jr., Ronald L. Robert M. Bookchin and Arthur I. Department of Medicine. Division Montefiore Hospital and the Albert Einstein The Bronx, N.Y. 10461
Received &!/&WRY inhibited increasing hemoglobin gelation Preliminary erythrocytes intravenous
June
to low
oxygen
amino
acid
which
enables
cell
disease
the
near molecule
macromolecular
in addition
From
substitution
and
that
is characterized
tensions.
mechanism,
in the
ERMHROCYTE
SICKLING
Nagel Grayzel of Hematology College of Medicine
12,1972
sickling
it seems
COMMUNICATIONS
- Sickling of erythrocytes from patients with sickle cell anemia can be completely by exposure to nitrogen mustard (HN2). Reaction of hemoglobin (Hb) S with quantities of HN2 produces a progressive rise in the minimum concentration of required for gelation on deoxygenation. Quantities of HN2 sufficient to alter cause no observable change in oxygen affinity or in heme:heme interaction. studies of osmotic fragility and autohemolysis showed no abnormalities after were treated with HN2. Due to the known toxicity of HN2, no “in viva” therapy with this agent can be considered.
Sickle
the
RESEARCH
such
more
the the
molecular
one
to hydrophobic
protein-protein
pair
location
to inhibit
molecule.
This
preliminary
report
alkylating
agent,
nitrogen
mustard
that
sites
not
and
in sickling.
by altering
describes
sickling beta
chain
the
the in vitro
the
fully
cells
is the
(1).
sites,
is required (3),
result
sickling
binding are
electrostatic
interactions
to attempt
polymer
of binding
of the
of red
deoxygenated
of the
of the
bonds,
reasonable
when
deformation
of view,
residue
to polymerize as the
gross
point
N terminal
structure than
by the
upon
result
of a single
of hemoglobin Many
types
(Hb)
details of bonds
of the involved
understood.
Nevertheless,
and
likely
(2), possibly
it is very
hydrogen
Accordingly, surface
charges
bonds
that
are
blood,
anticoagulated
seem
of the
hemoglobin
inhibition
of sickling
or EDTA,
as indicated,
by an
(HN2).
Copyright 0 19 72 by Academic Press, Inc. All rights of reproduction in any form reserved.
with
either 612
citrate
involved
it would
METHODS Venous
exposure
was
S
Vol.
48,
No.
obtained
from
of Drabkin and
patients
(4) and
agar
gel
amount
all
(K and
cell
were
(5)
the
for
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
anemia.
Hemolysates
examined
by electrophoresis
presence
was
5%,
were
as the
by the
on starch
of Hb A or other
measured
prepared
variants,
gel
The
proportion
the
effect
K Laboratories, (PBS)
washed
three
of HN2
on sickling
Plainview,
N.Y.)
were
added
times
in PBS.
deoxygenated
After
volume glutaraldehyde
counting
300 Minimum
which
pH 7.35,
at 25OC.
The
Solutions
at pH 8.6
maximum
of hemoglobin
equilibria.
These
a Cary
were
model
two
of 95%
and
(2) on solutions with
various
of methemoglobin and were
after
reacted
performed
resistant
the
CO2
buffered
saline
or to red
cells
mixtures
were
or by the
addition
of cells
evaluated
for
discs)
of HN2
was
then
sickling
blood,
of HN2
of red results
a concentration
cells
at pH 7.0 using
HN2 prior
on deoxygenation
of Hb
S in 0.15
amounts
of HN2
M K for
was
determined
as described
above,
to determination
tonometers
spectrophotometer
from
patients
in progressive of at least
two
with
but were
of oxygen integral
optical
(6).
with
inhibition 0.4
by
or deformed.
RESULTS Incubation
fixed
experiments. with
at 25OC
blood
at 37oC,
gelation
in samples
gelling
whole
(biconcave for
amounts
phosphate
An aliquot
as normal
reaction
varying
N2-5%
metabisulfite.
described
M K phosphate
14 recording
hours
required
of hemoglobin 0.15
for
M Cacodylate-buffer
after
cells,
to either
concentration
before
against
Na
classified
proportion
spectrophotometrically
dialyzed
were
as previously
buffer,
of 1:l
incubation
a 0.1
hemoglobin
determined
phosphate
with
cells
ratio
of 2%
red
in isotonic
in an atmosphere
of a solution
in 2%
of intact dissolved
in a volume
by equilibration
of equal
amounts
method
denaturation.
solution
and
sickle
samples
at pH 6.4
To test
hours
with
of Hb F in hemolysates
to alkaline
was
BIOCHEMICAL
3, 1972
mg HN2
613
sickle
cell
of sickling per
anemia (Fig.
ml of blood
with 1).
increasing Using
is required
whole to inhibit
cuvettes
Vol.
48,
No.
3, 1972
BIOCHEMICAL
0.0
AND
I 0.2 NITROGEN
Figure
BIOPHYSICAL
I 0.4
I 0.6 MUSTARD
RESEARCH
I
0.8
1 2 3
614
I 1.0
mg/ml
The effect of nitrogen mustard on erythrocyte metabisulfite in vitro. Solid circles: sickling circles: sickling of RBC’s in buffered saline. deformed ccl Is before deoxygenation.
1:
COMMUNICATIONS
sickling in whole Dashed
in 1% sodium blood. Empty line: level of
Vol. 48, No. 3, 1972
sickling; per
however
ml of cell
that
this
33%
of the
with
agent
increases bands
the
cathodal
hemoglobin
between
majority
progressive
these
in the
deoxygenation
(Fig.
ratio
as low
Methemoglobin than
anodal
minimum
as l:l,
10 per
cent
in the
“S”
position.
total
reoxygenated and
51,
after
gelling
within
diffuse
migration ratio
of HN2
for
of
of 20:1,
results
required
in a
gelling
on
at a mustard:heme
gelling
* 5 per
which
electrophoretic
a HN2:heme
is elevated
than
new
some
quantities
point
greater
hemoglobin,
are
of hemoglobin
gelling
at ratios
of samples
of the
increasing
shown
heterogeneity
of Hb S with
usual
have
portion.
There
with
minimum
while
2).
mg HN2
Approximately
electrophoretic
(Fig.
concentration
The
mustard
globin
even
of Hb S with
3).
show
as 0.1
erythrocytes.
isolated
position
as little
nitrogen
Nevertheless,
migrates
content
HN2
to the
bands.
of solutions rise
with
with
in intact
on the
of mustard
of hemoglobin
Reaction
molar
and
to globin
is recovered
concentration
is seen
l4 C-labelled
with
of Hb S incubated
with
inhibition
of binding
amount
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
cells,
Studies
is capable
applied
both
washed
suspension.
Solutions
the
BIOCHEMICAL
is no longer
experiments cent
demonstrable.
were
of the
always
control
(no
sample. Measurements ratio
of 1:l
~50~12.5 of lO:l, curve
of oxygen
demonstrate mm Hg and
there with
normal
Figure
2:
n value
is a small
two
is near
normal
slopes;
of Hb S after
oxygen on Hill
increase one
equilibria
affinity plot
= 2.8).
in oxygen
component
and
affinity
has an n value
reaction
at a HN2:heme
heme-heme However, (p50=10 reduced
interaction with
molar (Fig.
a HN2:heme
mm Hg) to 1.4,
and while
4, ratio
a biphasic the
other
(n=2.37).
Electrophoresis hemoglobin anode is at as 1 treated 4) Same as
on starch gel pH 8.6 of nitrogen S hemolysates. The origin is at the the right. 1) Control:Hb A2 and Hb with HN2:heme 1:l. 3) Same as 2 2 but HN2:heme 1O:l. 5) Same as
615
mustard (HN -treated left, marked 6. The S. 2) Same hemolysate but HN :heme 5:l. 2 but H I4 2:heme 2O:l.
less HN2)
Vol.
48,
No.
BIOCHEMICAL
3, 1972
NO
GELLING 43 -
4
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
GELLING 4 1
2
230 MOLAR
1
RATIO
4I
6I
I
NITROGEN
Fig.
I
aI
10
I
MUSTARD:
HEME
Paz (mm Hqf
3.
Fig.
4.
Figure
3:
Minimum gelling concentrations of nitrogen mustard treated hemoglobin Sol id circles: minimum gel1 ing concentrations. Arrows: concentration at which experiment was stopped without gel formation.
S.
Figure
4:
Log-log plot of oxygen equilibria of hemoglobin S hemolysate (Hill plot). Ordinate: ratio of O2 saturated hemoglobin S to unsaturated portion 1 - S. Abscissa:p02 in mm. Hg. Open circles: native hemoglobin S n=2,87, ~50 = 12.5 mm. Hg. Solid circles: nitrogen mustard-treated hemoglobin S at molar ratio HN2:heme 1 :l. n=2.87 p50=12.5 mm. Hg. Triangles: HN2:heme 1O:l. n value for first phase = 1.4. n value for second phase = 2.37. ~50 =lO mm. Hg. Temperature 25OC., pH 7.04 potassium phosphate buffer 0.15 M.
DISCUSSION Previous that
the
sites
on proteins
of the ring would
studies
rapidly
formed
and
electrophoretic
of the
species
pH,
side (8).
to reduce with
of nitrogen
ethylene
neutral
of histidine.
be expected
reactions
mustard At
(7).
C terminal nitrogens
on the
the slower
immonium alkylation
chains
with
ion reacts occurs
of asportate
Esterification net
mustards
most and
migration
charge towards
616
readily
of the
of the the
readily
glutamate
by alkylation
negative
proteins
protein
anode
than
have
shown
with
several
at the
carboxyl
residues,
and
carboxyl
groups
molecule the
native
and
anionic groups at the
produce protein.
_
Vol.
48,
No.
BIOCHEMICAL
3, 1972
However,
conformational
charges
at the
molar
ratios
higher amount
changes
surface
and
of nitrogen
molar
ratios,
of HN2
is not
mobility
used
yet
in these
clear
on gelation
minimum
also
can
than
gelling
red
that
negative
anode.
At
predominate,
with
alkylation
at
the
largest
S unmodified
various
and
low
while even
hemoglobin
hemoglobin
that
quantities
change
of
in electrophoretic
from
increase
in the oxygen
by reaction
with
persons
(and
amounts red
However,
possibly
with
of HN2
are
red
that sufficient
cell
other
effect
cells. the
sickling
Elevation
concentration
of intact
quantities
smaller
tendency
sickle
inhibitory
100 ml,
much
the sickling with
intact
33 gm per findings
to reduce
a marked
of the
our
suffice
significant
in sickling
with
complete.
the
to have
of Hb S above
inhibited
of washed
neither
of HN2
elevations
to a level
trait.
Since
constituents
of the comparable
nitrogen
mustard
of whole
required
to inhibit
sickling
required
to inhibit
gelling
blood) in whole
it blood
cells.
amounts
of HN2
methemoglobin affinity.
Thus
formation gelation
in hemolysates
and
sickling
must
and
sickling
nor an appreciable be inhibited
by another
Hb S molecules.
It is important of nitrogen cell
new
However,
of the
appears
and
is nearly
larger
produce
mustard
correlates
proteins
It is noteworthy
ml red
cells,
cells
plasma
in suspensions
amounts
most
of the
the
species
observed.
between
solutions
may
by red
with
on the
leaves
concentration
point
surprising
effect
are
expose
towards
moving
species
correlation
be completely
exhibited
is not
fast
faster
of reaction
the
deoxygenation
reacts
migration
experiments
hemoglobin
within
erythrocytes
to that
and
gelling
of hemoglobin
minimum
and
of Hb S by nitrogen of the
when
accelerate
might
COMMUNICATIONS
to be determined.
Alkylation
even
slow
RESEARCH
by alkylation
to heme,
the extent
remains
of the
thereby
both
BIOPHYSICAL
produced
mustard
electrophoretically; HN2
AND
(whole
to consider mustard. blood)
the
effects
P re I iminary suspension
produce
617
on intact studies
red
show
no increase
cells
that
of treatment
with
large
treatment
with
1 mg HN2
in osmotic
fragility
or auto-
per
Vol. 48, No. 3, 1972
hemolysis.
The
Fourteen and
red
others
cell
group
observed
that
present
sickling
data
in properties
required
to inhibit
possibility
suggest
sickling
explored
of the that
oxygen
treated
has not
unchanged
vivo”red
been
examined.
exposure
after
survival
of Hb S by nitrogen of the The
its direct
after
properties
cell
yet
data
to HN2,
treatment
with
would
be
inhibit
gelling
cells.
equilibrium.
treatment
cells
its storage
polymerization
preclude
in our
retains
alkylation
the
red
qualitatively
However,‘Fn
with
of extra-corporeal
actively
blood
integrity
of the
were
bank (9).
by interfering
change
being
the
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
on enzyme-deficient
antigens
of HN2
to determine The
the
of mustard
blood
amounts
required
and
effect
have
comparable
BIOCHEMICAL
deoxyhemoglobin,
very
use in patients or the
mustard
high
with
concentrations with
use of less toxic
li+tle
of mustard
sickle
cell
alkylating
anemia, agents
but are
laboratory.
ACKNOWLEDGEMENT - This work was supported by PHS grants AM15053, AM12597, AM05082 and AM13430. We thank Dr. Joseph Kochen for the red cell hemolysis studies and Dr. Parviz Lalezari for the blood group antigen determinations. Drs. Nagel, Bookchin and Grayzel are Career Scientists of the Health Research Council of the City of New York. Requests for reprints should be sent to: Dr. Eugene Roth, Jr., c/o Dr. Ronald L. Nagel, Albert Einstein College of Medicine, 1300 Morris Park Avenue, Bronx, New York 10461, U.S.A. REFERENCES 1. 2. 3. 4. 5. 6. 7. 8.
Ingram, V., Nature. 180, 326, 1957. Bookchin, R.M. and RI Nagel, J. Mol. Biol. 60, 263, 1971. Bookchin, R.M. and R.L. Nagel, Clin. Res. 19,Tl, 1971. Drabkin, D.L., J. Biol. Chem. 164, 703, 19x. Smithies, 0. Biochem. J. 71, 58r1946. Nagel, R.L., Q.H. Gibsonnd T. Jenkins, J. Mol. Biol. 58, Ross, W.C.J., in Biological Alkylating Agents, Butterworths,‘ondon, Burnap, V.C.E., G.E. Francis, D. E. Richards and A. Wormall,
9.
Hartman,
504, 1957. F.W., G.H. Biol. and Med.,
643,
1971. 1962: Biochem. J.,
66,
Mangun, 70, 248,
N. Feeley 1949.
618
and
E. Jackson,
Proc.
Sot.
Exp.
48,
No.
BIOCHEMICAL
3, 1972
NITROGEN
MUSTARD:
AN
“IN
AND
VITRO”
BIOPHYSICAL
INHIBITOR
OF
Eugene F. Roth, Jr., Ronald L. Robert M. Bookchin and Arthur I. Department of Medicine. Division Montefiore Hospital and the Albert Einstein The Bronx, N.Y. 10461
Received &!/&WRY inhibited increasing hemoglobin gelation Preliminary erythrocytes intravenous
June
to low
oxygen
amino
acid
which
enables
cell
disease
the
near molecule
macromolecular
in addition
From
substitution
and
that
is characterized
tensions.
mechanism,
in the
ERMHROCYTE
SICKLING
Nagel Grayzel of Hematology College of Medicine
12,1972
sickling
it seems
COMMUNICATIONS
- Sickling of erythrocytes from patients with sickle cell anemia can be completely by exposure to nitrogen mustard (HN2). Reaction of hemoglobin (Hb) S with quantities of HN2 produces a progressive rise in the minimum concentration of required for gelation on deoxygenation. Quantities of HN2 sufficient to alter cause no observable change in oxygen affinity or in heme:heme interaction. studies of osmotic fragility and autohemolysis showed no abnormalities after were treated with HN2. Due to the known toxicity of HN2, no “in viva” therapy with this agent can be considered.
Sickle
the
RESEARCH
such
more
the the
molecular
one
to hydrophobic
protein-protein
pair
location
to inhibit
molecule.
This
preliminary
report
alkylating
agent,
nitrogen
mustard
that
sites
not
and
in sickling.
by altering
describes
sickling beta
chain
the
the in vitro
the
fully
cells
is the
(1).
sites,
is required (3),
result
sickling
binding are
electrostatic
interactions
to attempt
polymer
of binding
of the
of red
deoxygenated
of the
of the
bonds,
reasonable
when
deformation
of view,
residue
to polymerize as the
gross
point
N terminal
structure than
by the
upon
result
of a single
of hemoglobin Many
types
(Hb)
details of bonds
of the involved
understood.
Nevertheless,
and
likely
(2), possibly
it is very
hydrogen
Accordingly, surface
charges
bonds
that
are
blood,
anticoagulated
seem
of the
hemoglobin
inhibition
of sickling
or EDTA,
as indicated,
by an
(HN2).
Copyright 0 19 72 by Academic Press, Inc. All rights of reproduction in any form reserved.
with
either 612
citrate
involved
it would
METHODS Venous
exposure
was
S
Vol.
48,
No.
obtained
from
of Drabkin and
patients
(4) and
agar
gel
amount
all
(K and
cell
were
(5)
the
for
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
anemia.
Hemolysates
examined
by electrophoresis
presence
was
5%,
were
as the
by the
on starch
of Hb A or other
measured
prepared
variants,
gel
The
proportion
the
effect
K Laboratories, (PBS)
washed
three
of HN2
on sickling
Plainview,
N.Y.)
were
added
times
in PBS.
deoxygenated
After
volume glutaraldehyde
counting
300 Minimum
which
pH 7.35,
at 25OC.
The
Solutions
at pH 8.6
maximum
of hemoglobin
equilibria.
These
a Cary
were
model
two
of 95%
and
(2) on solutions with
various
of methemoglobin and were
after
reacted
performed
resistant
the
CO2
buffered
saline
or to red
cells
mixtures
were
or by the
addition
of cells
evaluated
for
discs)
of HN2
was
then
sickling
blood,
of HN2
of red results
a concentration
cells
at pH 7.0 using
HN2 prior
on deoxygenation
of Hb
S in 0.15
amounts
of HN2
M K for
was
determined
as described
above,
to determination
tonometers
spectrophotometer
from
patients
in progressive of at least
two
with
but were
of oxygen integral
optical
(6).
with
inhibition 0.4
by
or deformed.
RESULTS Incubation
fixed
experiments. with
at 25OC
blood
at 37oC,
gelation
in samples
gelling
whole
(biconcave for
amounts
phosphate
An aliquot
as normal
reaction
varying
N2-5%
metabisulfite.
described
M K phosphate
14 recording
hours
required
of hemoglobin 0.15
for
M Cacodylate-buffer
after
cells,
to either
concentration
before
against
Na
classified
proportion
spectrophotometrically
dialyzed
were
as previously
buffer,
of 1:l
incubation
a 0.1
hemoglobin
determined
phosphate
with
cells
ratio
of 2%
red
in isotonic
in an atmosphere
of a solution
in 2%
of intact dissolved
in a volume
by equilibration
of equal
amounts
method
denaturation.
solution
and
sickle
samples
at pH 6.4
To test
hours
with
of Hb F in hemolysates
to alkaline
was
BIOCHEMICAL
3, 1972
mg HN2
613
sickle
cell
of sickling per
anemia (Fig.
ml of blood
with 1).
increasing Using
is required
whole to inhibit
cuvettes
Vol.
48,
No.
3, 1972
BIOCHEMICAL
0.0
AND
I 0.2 NITROGEN
Figure
BIOPHYSICAL
I 0.4
I 0.6 MUSTARD
RESEARCH
I
0.8
1 2 3
614
I 1.0
mg/ml
The effect of nitrogen mustard on erythrocyte metabisulfite in vitro. Solid circles: sickling circles: sickling of RBC’s in buffered saline. deformed ccl Is before deoxygenation.
1:
COMMUNICATIONS
sickling in whole Dashed
in 1% sodium blood. Empty line: level of
Vol. 48, No. 3, 1972
sickling; per
however
ml of cell
that
this
33%
of the
with
agent
increases bands
the
cathodal
hemoglobin
between
majority
progressive
these
in the
deoxygenation
(Fig.
ratio
as low
Methemoglobin than
anodal
minimum
as l:l,
10 per
cent
in the
“S”
position.
total
reoxygenated and
51,
after
gelling
within
diffuse
migration ratio
of HN2
for
of
of 20:1,
results
required
in a
gelling
on
at a mustard:heme
gelling
* 5 per
which
electrophoretic
a HN2:heme
is elevated
than
new
some
quantities
point
greater
hemoglobin,
are
of hemoglobin
gelling
at ratios
of samples
of the
increasing
shown
heterogeneity
of Hb S with
usual
have
portion.
There
with
minimum
while
2).
mg HN2
Approximately
electrophoretic
(Fig.
concentration
The
mustard
globin
even
of Hb S with
3).
show
as 0.1
erythrocytes.
isolated
position
as little
nitrogen
Nevertheless,
migrates
content
HN2
to the
bands.
of solutions rise
with
with
in intact
on the
of mustard
of hemoglobin
Reaction
molar
and
to globin
is recovered
concentration
is seen
l4 C-labelled
with
of Hb S incubated
with
inhibition
of binding
amount
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
cells,
Studies
is capable
applied
both
washed
suspension.
Solutions
the
BIOCHEMICAL
is no longer
experiments cent
demonstrable.
were
of the
always
control
(no
sample. Measurements ratio
of 1:l
~50~12.5 of lO:l, curve
of oxygen
demonstrate mm Hg and
there with
normal
Figure
2:
n value
is a small
two
is near
normal
slopes;
of Hb S after
oxygen on Hill
increase one
equilibria
affinity plot
= 2.8).
in oxygen
component
and
affinity
has an n value
reaction
at a HN2:heme
heme-heme However, (p50=10 reduced
interaction with
molar (Fig.
a HN2:heme
mm Hg) to 1.4,
and while
4, ratio
a biphasic the
other
(n=2.37).
Electrophoresis hemoglobin anode is at as 1 treated 4) Same as
on starch gel pH 8.6 of nitrogen S hemolysates. The origin is at the the right. 1) Control:Hb A2 and Hb with HN2:heme 1:l. 3) Same as 2 2 but HN2:heme 1O:l. 5) Same as
615
mustard (HN -treated left, marked 6. The S. 2) Same hemolysate but HN :heme 5:l. 2 but H I4 2:heme 2O:l.
less HN2)
Vol.
48,
No.
BIOCHEMICAL
3, 1972
NO
GELLING 43 -
4
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
GELLING 4 1
2
230 MOLAR
1
RATIO
4I
6I
I
NITROGEN
Fig.
I
aI
10
I
MUSTARD:
HEME
Paz (mm Hqf
3.
Fig.
4.
Figure
3:
Minimum gelling concentrations of nitrogen mustard treated hemoglobin Sol id circles: minimum gel1 ing concentrations. Arrows: concentration at which experiment was stopped without gel formation.
S.
Figure
4:
Log-log plot of oxygen equilibria of hemoglobin S hemolysate (Hill plot). Ordinate: ratio of O2 saturated hemoglobin S to unsaturated portion 1 - S. Abscissa:p02 in mm. Hg. Open circles: native hemoglobin S n=2,87, ~50 = 12.5 mm. Hg. Solid circles: nitrogen mustard-treated hemoglobin S at molar ratio HN2:heme 1 :l. n=2.87 p50=12.5 mm. Hg. Triangles: HN2:heme 1O:l. n value for first phase = 1.4. n value for second phase = 2.37. ~50 =lO mm. Hg. Temperature 25OC., pH 7.04 potassium phosphate buffer 0.15 M.
DISCUSSION Previous that
the
sites
on proteins
of the ring would
studies
rapidly
formed
and
electrophoretic
of the
species
pH,
side (8).
to reduce with
of nitrogen
ethylene
neutral
of histidine.
be expected
reactions
mustard At
(7).
C terminal nitrogens
on the
the slower
immonium alkylation
chains
with
ion reacts occurs
of asportate
Esterification net
mustards
most and
migration
charge towards
616
readily
of the
of the the
readily
glutamate
by alkylation
negative
proteins
protein
anode
than
have
shown
with
several
at the
carboxyl
residues,
and
carboxyl
groups
molecule the
native
and
anionic groups at the
produce protein.
_
Vol.
48,
No.
BIOCHEMICAL
3, 1972
However,
conformational
charges
at the
molar
ratios
higher amount
changes
surface
and
of nitrogen
molar
ratios,
of HN2
is not
mobility
used
yet
in these
clear
on gelation
minimum
also
can
than
gelling
red
that
negative
anode.
At
predominate,
with
alkylation
at
the
largest
S unmodified
various
and
low
while even
hemoglobin
hemoglobin
that
quantities
change
of
in electrophoretic
from
increase
in the oxygen
by reaction
with
persons
(and
amounts red
However,
possibly
with
of HN2
are
red
that sufficient
cell
other
effect
cells. the
sickling
Elevation
concentration
of intact
quantities
smaller
tendency
sickle
inhibitory
100 ml,
much
the sickling with
intact
33 gm per findings
to reduce
a marked
of the
our
suffice
significant
in sickling
with
complete.
the
to have
of Hb S above
inhibited
of washed
neither
of HN2
elevations
to a level
trait.
Since
constituents
of the comparable
nitrogen
mustard
of whole
required
to inhibit
sickling
required
to inhibit
gelling
blood) in whole
it blood
cells.
amounts
of HN2
methemoglobin affinity.
Thus
formation gelation
in hemolysates
and
sickling
must
and
sickling
nor an appreciable be inhibited
by another
Hb S molecules.
It is important of nitrogen cell
new
However,
of the
appears
and
is nearly
larger
produce
mustard
correlates
proteins
It is noteworthy
ml red
cells,
cells
plasma
in suspensions
amounts
most
of the
the
species
observed.
between
solutions
may
by red
with
on the
leaves
concentration
point
surprising
effect
are
expose
towards
moving
species
correlation
be completely
exhibited
is not
fast
faster
of reaction
the
deoxygenation
reacts
migration
experiments
hemoglobin
within
erythrocytes
to that
and
gelling
of hemoglobin
minimum
and
of Hb S by nitrogen of the
when
accelerate
might
COMMUNICATIONS
to be determined.
Alkylation
even
slow
RESEARCH
by alkylation
to heme,
the extent
remains
of the
thereby
both
BIOPHYSICAL
produced
mustard
electrophoretically; HN2
AND
(whole
to consider mustard. blood)
the
effects
P re I iminary suspension
produce
617
on intact studies
red
show
no increase
cells
that
of treatment
with
large
treatment
with
1 mg HN2
in osmotic
fragility
or auto-
per
Vol. 48, No. 3, 1972
hemolysis.
The
Fourteen and
red
others
cell
group
observed
that
present
sickling
data
in properties
required
to inhibit
possibility
suggest
sickling
explored
of the that
oxygen
treated
has not
unchanged
vivo”red
been
examined.
exposure
after
survival
of Hb S by nitrogen of the The
its direct
after
properties
cell
yet
data
to HN2,
treatment
with
would
be
inhibit
gelling
cells.
equilibrium.
treatment
cells
its storage
polymerization
preclude
in our
retains
alkylation
the
red
qualitatively
However,‘Fn
with
of extra-corporeal
actively
blood
integrity
of the
were
bank (9).
by interfering
change
being
the
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
on enzyme-deficient
antigens
of HN2
to determine The
the
of mustard
blood
amounts
required
and
effect
have
comparable
BIOCHEMICAL
deoxyhemoglobin,
very
use in patients or the
mustard
high
with
concentrations with
use of less toxic
li+tle
of mustard
sickle
cell
alkylating
anemia, agents
but are
laboratory.
ACKNOWLEDGEMENT - This work was supported by PHS grants AM15053, AM12597, AM05082 and AM13430. We thank Dr. Joseph Kochen for the red cell hemolysis studies and Dr. Parviz Lalezari for the blood group antigen determinations. Drs. Nagel, Bookchin and Grayzel are Career Scientists of the Health Research Council of the City of New York. Requests for reprints should be sent to: Dr. Eugene Roth, Jr., c/o Dr. Ronald L. Nagel, Albert Einstein College of Medicine, 1300 Morris Park Avenue, Bronx, New York 10461, U.S.A. REFERENCES 1. 2. 3. 4. 5. 6. 7. 8.
Ingram, V., Nature. 180, 326, 1957. Bookchin, R.M. and RI Nagel, J. Mol. Biol. 60, 263, 1971. Bookchin, R.M. and R.L. Nagel, Clin. Res. 19,Tl, 1971. Drabkin, D.L., J. Biol. Chem. 164, 703, 19x. Smithies, 0. Biochem. J. 71, 58r1946. Nagel, R.L., Q.H. Gibsonnd T. Jenkins, J. Mol. Biol. 58, Ross, W.C.J., in Biological Alkylating Agents, Butterworths,‘ondon, Burnap, V.C.E., G.E. Francis, D. E. Richards and A. Wormall,
9.
Hartman,
504, 1957. F.W., G.H. Biol. and Med.,
643,
1971. 1962: Biochem. J.,
66,
Mangun, 70, 248,
N. Feeley 1949.
618
and
E. Jackson,
Proc.
Sot.
Exp.