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On the structure of the carbohydrate chains of blood group substances
BIOCHEMICAL
Vol. 39, No. 4, 1970
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ON THE STRUCTURE OF THE CARBOHYDRATECHAINS OF BLOOD GROUPSUBSTWJCES N.K. Kochetkov,
V.A. Derevitskaya,
M.D. Martynova,
L.M. Likhosherstov,
S.N. Senchenkova,
G.S. Kikot'
and
L.S, Bogdashova N.D. Zelinsky Institute of Organic USSR Academy of Sciences, Moscow, Received March
24,
Chemistry US SR
1970
A scheme for the general composition of the carbohydrate chains in blood group substances is suggested. The principal peculiarities of this scheme are the high degree of carbohydrate chain branching and the presence in the region close to the peptide backbone of a fragment built up of only N-acetylhexosamines. The biological
specificity
of blood group substances
(BGS)
is known to be determined by the structure of their carbohydrate chains /l/ which are attached to the central peptide backbone '2' . The nature
of the terminal
des and the structure
nonreducing
of the neighbouring
monosacchari-
regions
has been es-
tablished tial
by means of immunochemical methods as well as by pardegradation of BGS /I/ . No data have been available up to
now concerning
the general
BGS. A structural the carbohydrate
scheme for chains
bone has been recently rio
structure
the nonreducing
and the part put forward
chains
in
parts
of
terminal
close to the peptide by Lloyd,
back-
Kabat and Lice-
13/. On the basis of our present
lated
of carbohydrate
from hog stomach lining
bed procedure
'4')
together
according with
oligosaccharides
isolated
neral
the structure
scheme for
studies
earlier
of BGS (A + H) (isoto a previously
data on the composition /1,3,5,W
descriof
9 we suggest a geof BGS carbohydrate chains.
583
Vol. 39, No. 4, 1970
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
The main approaches of the carbohydrate degradation,
chains
methylation
zymatic degradation ducts. tion
to the elucidation
The latter rate
of the structure
were as follows: studies,
consisted
products
During
saccharinic
and second periodate
of N-acetylhexosamine
5 hours,
only traces
of galactose
thus demonstrating nonreducing tions
that
termini
result
high degree
into
on the basis
chains. -tetra-, di-,
only from the Smith degrada-
chains
of a high degree
galac/7/*
in BGS should be
and taking into account /3/. Consequently the oxidation
can only be
of branching
of the
chains. and high degree
Several
of BGS are also in accord with of branching
O-methyl-derivatives
3,4,6-tri-, 2,6-di-,
derivatives,
of N-acetylhexosamine
and hexosamines
The data on methylation complexity
contained
of ca. 7Wh of the original
2 determinants
of galactose
carbohydrate
Two successive
of chains.
60 as deduced from '8g10(
the chain branching
products
proceeded
number of carbohydrate
approximately
explained
the oxidation
and ca. 50% of that
The total
weight
within
2.5 and 1.3 moles
and N-acetylhexosamine
in destruction
tose content
hex-2-enose.
to completion
consumed being
per 1000 g of DGS. The lowmolecular
and ga-
of BGS the first
proceeded
the amount of oxidant
units,
(chromogen),
Smith degradation
oxidations
pro-
of the forma-
acids and 2-substituted
the stepwise
and en-
degradation
in the determination
3-acetamido-5-(1,2-dihydroxyethyl)-fursn units,
Smith
a combined chemical
and a study of alkaline
of degradation
lactose
stepwise
2,4,6-tri-,
of its
carbohydrate
of galactose 2,3,6-tri-,
3,6-di-0-bPle-Gal),hexosamines
(2,3,4,6-
2,3,4-tri-, (3,4,6-tri-,
4,63,6-di-,
and fucose (2,3,4-tri-O3-, 6- 0-Me-GN, 3,4,6-tri-0-Ue-GalN) Me-Fuc) were identified among the products of hydrolysis of 584
the
BIOCHEMICAL
Vol. 39, No. 4,197O
the methylated merit
BGS thus revealing /11,12/ . According
linkages
in part,
galactose,
occupy terminal
The presence
C-4 and C-3 or C-2 follows
very
accumulate
with destruction lactose
Galactose
slowly.
that
well
of
of the second 4 hrs
which give
degradation
products
cau-
rise appear
is accompanied
content of N-acetylof galactose /13/ . Hence ga-
to degradation
does not appear
linkage.
attached
to serine
the reducing
It
under conditions
to enter
These data also give
is N-acetylhexosamine.
that
products
at
absent from the carbohydrate
is subjected
the monosaccharide
residues
in
with substituents
Such a treatment
seems to be practically
rate-peptide
ga-
of ca. 3W/o of the total
used, and consequently that
weight
and of ca. 4% of that
chain region
while
are also located
of N-acetylhexosamines
to chromogen production.
and
and 2-acet-
of BGS with 0.05 M Na2C03 at 70" for
destruction
hexosamine
fucose,
also from the identification
among the lowmolecular Smith degradation of BGS /7/* ses rapid
of intermono-
positions,
of galactose
threitol
Treatment
variety
to these data,
and 2-acetamido-2-deoxy-D-glucose
branch-points.
and
a large
2-acetamido-2-deoxy-D-glucose
amide-2-deoxy-D-galact;ose lactose
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
should
the carbohyd-
en unambigous proof and/or
threonine
be pointed
end of the carbohydrate
out as
chain consists
of several (no less than 3-4) N-acetylhexosamine residues linked with l-3 bonds, this being the backbone of this chain region.
Characterization
degradation
of BGS proved
tion
of carbohydrate
viz.
substituted
responding nes with
of chromogens formed to be of value
chain structure.
and nonsubstituted,
to the presence and without
of l-
substituents 585
upon alkaline
in further
elucida-
Two types of chromogens, were formed,
3 linked
these cor-
N-acetylhexosamiat C-6 /13/o
Vol. 39, No. 4,197O
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Alkaline
degradation
end borohydride
reduction
amounts of nonsubstituted explained is linked treatment
formed
and which is subject
of the terminal
in the side chain of 1 -3 to degradation
linked
that N-
upon
with alkali.
Examination
of the kinetics
chromogen formation
accumulation
of the former
(fig.
of substituted
linkage
and unsubsti-
I)
showed that the curve of had a lag-phase /14/ . It follows,
u.nequivocally,thatN-acetylhexosamine tein
oxidation
residues
the chain fragment
acetylhexosamines
oxidation
in formation of decreased chromogen /14/. This fact can be
N-acetylhexosamine with
periodate
results
as being due to periodate
nonreducing
tuted
of BGS after
at the carbohydrate-pro-
bear no branching.
lg(Dm-D)
1.1
Fig.
1. The kinetics of the substituted and unsubstituted chromogen formation from BGS treated with 0.05 M aqueous Na2C05 at 70". - unsubstituted chromogen - substituted chromogen. 586
Vol.39,No.4,
1970
BIOCHEMICAL
A combination followed
of degradation
by enzymatic
glycosidase
hydrolysis
preparation
molecular
weight
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
'15')
fragment
(6OA) and hexosamines
methods (Smith degradation by a Clostridium perfringens -----a--------e m-w resulted in isolation of a high-
consisting
mainly
(34%), the 2-acetamido-2-deoxy-D-galac-
tose to 2-acetamido-2-deoxy-D-glucose
7.5 : 1 '16'.
Alkaline
degradation
this
revealed
that
fragment
rate-protein
linkage
ratio
being
and periodate
equal to oxidation
in most of 0-glycosidic
a single
do-2-deoxy-D-galactose,was
HexNAc
of amino acids
monosaccharide,
of
carbohyd-
viz.
2-acetami-
present.
I
I R NH : I / Hefl,Ac I-3 HexNAc I-33 HexNAc I-3 GalNAc-OCRCH 6 6 \ f c=o i I .
f3
I Fuc I-4 GNAc
Gal1 6 \
?
peptide chain
I
GNAc 3-I Fuc 4 t I Gal 261 Fuc
3
Fuc I-2
?
t I Gal
3
3
t I
The scheme for presented
here may, of course,
ned in the light details
the carbohydrate
be completed,
of newer experimental
of attachment
cal activity
chain structure
of the part
to the fragment
built 587
of BGS
altered
data,particularly
responsible
for
or refion the
the biologi-
up of R-acetylhexossmines.
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 39, No. 4,197O
We should
like
scheme, viz. -
to emphasize two principal the high degree
and the presence of the fragment
of carbohydrate
in the region built
peculiarities
of this
chain branching
close to the peptide
backbone
up of only N-acetylhexosamines.
References 1. Watkins, W.M., in ltGlycoproteinsl' (Ed. A. Gottschalk) p. 462, Elsevier Publishing Company, Amsterdam, London, New York, 1966.
2. Koch&k&, N.K., Derevitskaya, V.A., and Kara-Murza, S.G., Carbohydrate Res., 2, 403 (1967). 3. Lloyd, K.O., Rabat, E.A. and Licerio, E., Biochemistry, 2, 2976 (1968). 4. Likhosherstov, L.M., Derevitskaya, V.A. and Fedorova, V.I., Biokhimiya, 4, 45 (1969). 5. Rege, V.P., Pain% er, T.J. Watkins, W.M. and Morgan, W.T.J., Nature, 200, 532 (1963j. 6. Lloyd, K., mat, E.A. Lagug, E. and Gruezo, F., Biochemistry, fz, 1489 (1966). 7. Likhosherstov, L.M., Bogdanova, L.S., Derevitskaya, V.A. and Kochetkov N.K., Iav. Akad. Nauk SSSR, Ser. Khim. (in press). 8. Zarnite, M.L. and Kabat, &:.A., J. Am. Chem. SOC., 82, 3953 (1960). 9. Marcus, D.M., Kabat, E.A. and Schiffman, G., Biochemistry, 2, 443 (19fJQ). 10. Tuppy, H. and Standcnlsher, W.L., Biochemistry, 2, 1742 N K Kikot' 11 . Ko:i%% G.S., Bogdanova, L.S., Likhosherstov, LfM.*&i Dereviiska a, V.A., Izv. Akad. Nauk SSSR, Ser. Khim., 2, 2085 (1968 3 . 12. Likhosherstov, L.M., Kikot', G.S., Derevitskaya, V.A., Arbatsky, N.P., Fedorova, V.I. and Kochetkov, N.K., Dokl. Akad. Nauk SSSR (in press, 1970). 13. Kochetkov, N.K., Derevitskaya, V.A., Likhosherstov, L.M., Martynova, M.D. and Senchenkova, S.M., Carbohydrate Res., (in press, 1970). 14. Likhosherstov, L.M., Senchenkova, S.N., Derevitskaya, V.I., and Kochetkov, N.K., Dokl. Akad. Nauk SSSR (in press). 15. Likhosherstov, L.M., Martynova, M.D., and Derevitskaya, V.A. Biokhimiya, 2, 1135 (1968). 16. Kochetkov, N.K., Derevitskaya, V.A., Likhosherstov, L.M. and Martynova, M.D., Dokl. Akad. Nauk SSSR, 186, 1195 (1969).
588
Vol. 39, No. 4, 1970
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ON THE STRUCTURE OF THE CARBOHYDRATECHAINS OF BLOOD GROUPSUBSTWJCES N.K. Kochetkov,
V.A. Derevitskaya,
M.D. Martynova,
L.M. Likhosherstov,
S.N. Senchenkova,
G.S. Kikot'
and
L.S, Bogdashova N.D. Zelinsky Institute of Organic USSR Academy of Sciences, Moscow, Received March
24,
Chemistry US SR
1970
A scheme for the general composition of the carbohydrate chains in blood group substances is suggested. The principal peculiarities of this scheme are the high degree of carbohydrate chain branching and the presence in the region close to the peptide backbone of a fragment built up of only N-acetylhexosamines. The biological
specificity
of blood group substances
(BGS)
is known to be determined by the structure of their carbohydrate chains /l/ which are attached to the central peptide backbone '2' . The nature
of the terminal
des and the structure
nonreducing
of the neighbouring
monosacchari-
regions
has been es-
tablished tial
by means of immunochemical methods as well as by pardegradation of BGS /I/ . No data have been available up to
now concerning
the general
BGS. A structural the carbohydrate
scheme for chains
bone has been recently rio
structure
the nonreducing
and the part put forward
chains
in
parts
of
terminal
close to the peptide by Lloyd,
back-
Kabat and Lice-
13/. On the basis of our present
lated
of carbohydrate
from hog stomach lining
bed procedure
'4')
together
according with
oligosaccharides
isolated
neral
the structure
scheme for
studies
earlier
of BGS (A + H) (isoto a previously
data on the composition /1,3,5,W
descriof
9 we suggest a geof BGS carbohydrate chains.
583
Vol. 39, No. 4, 1970
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
The main approaches of the carbohydrate degradation,
chains
methylation
zymatic degradation ducts. tion
to the elucidation
The latter rate
of the structure
were as follows: studies,
consisted
products
During
saccharinic
and second periodate
of N-acetylhexosamine
5 hours,
only traces
of galactose
thus demonstrating nonreducing tions
that
termini
result
high degree
into
on the basis
chains. -tetra-, di-,
only from the Smith degrada-
chains
of a high degree
galac/7/*
in BGS should be
and taking into account /3/. Consequently the oxidation
can only be
of branching
of the
chains. and high degree
Several
of BGS are also in accord with of branching
O-methyl-derivatives
3,4,6-tri-, 2,6-di-,
derivatives,
of N-acetylhexosamine
and hexosamines
The data on methylation complexity
contained
of ca. 7Wh of the original
2 determinants
of galactose
carbohydrate
Two successive
of chains.
60 as deduced from '8g10(
the chain branching
products
proceeded
number of carbohydrate
approximately
explained
the oxidation
and ca. 50% of that
The total
weight
within
2.5 and 1.3 moles
and N-acetylhexosamine
in destruction
tose content
hex-2-enose.
to completion
consumed being
per 1000 g of DGS. The lowmolecular
and ga-
of BGS the first
proceeded
the amount of oxidant
units,
(chromogen),
Smith degradation
oxidations
pro-
of the forma-
acids and 2-substituted
the stepwise
and en-
degradation
in the determination
3-acetamido-5-(1,2-dihydroxyethyl)-fursn units,
Smith
a combined chemical
and a study of alkaline
of degradation
lactose
stepwise
2,4,6-tri-,
of its
carbohydrate
of galactose 2,3,6-tri-,
3,6-di-0-bPle-Gal),hexosamines
(2,3,4,6-
2,3,4-tri-, (3,4,6-tri-,
4,63,6-di-,
and fucose (2,3,4-tri-O3-, 6- 0-Me-GN, 3,4,6-tri-0-Ue-GalN) Me-Fuc) were identified among the products of hydrolysis of 584
the
BIOCHEMICAL
Vol. 39, No. 4,197O
the methylated merit
BGS thus revealing /11,12/ . According
linkages
in part,
galactose,
occupy terminal
The presence
C-4 and C-3 or C-2 follows
very
accumulate
with destruction lactose
Galactose
slowly.
that
well
of
of the second 4 hrs
which give
degradation
products
cau-
rise appear
is accompanied
content of N-acetylof galactose /13/ . Hence ga-
to degradation
does not appear
linkage.
attached
to serine
the reducing
It
under conditions
to enter
These data also give
is N-acetylhexosamine.
that
products
at
absent from the carbohydrate
is subjected
the monosaccharide
residues
in
with substituents
Such a treatment
seems to be practically
rate-peptide
ga-
of ca. 3W/o of the total
used, and consequently that
weight
and of ca. 4% of that
chain region
while
are also located
of N-acetylhexosamines
to chromogen production.
and
and 2-acet-
of BGS with 0.05 M Na2C03 at 70" for
destruction
hexosamine
fucose,
also from the identification
among the lowmolecular Smith degradation of BGS /7/* ses rapid
of intermono-
positions,
of galactose
threitol
Treatment
variety
to these data,
and 2-acetamido-2-deoxy-D-glucose
branch-points.
and
a large
2-acetamido-2-deoxy-D-glucose
amide-2-deoxy-D-galact;ose lactose
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
should
the carbohyd-
en unambigous proof and/or
threonine
be pointed
end of the carbohydrate
out as
chain consists
of several (no less than 3-4) N-acetylhexosamine residues linked with l-3 bonds, this being the backbone of this chain region.
Characterization
degradation
of BGS proved
tion
of carbohydrate
viz.
substituted
responding nes with
of chromogens formed to be of value
chain structure.
and nonsubstituted,
to the presence and without
of l-
substituents 585
upon alkaline
in further
elucida-
Two types of chromogens, were formed,
3 linked
these cor-
N-acetylhexosamiat C-6 /13/o
Vol. 39, No. 4,197O
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Alkaline
degradation
end borohydride
reduction
amounts of nonsubstituted explained is linked treatment
formed
and which is subject
of the terminal
in the side chain of 1 -3 to degradation
linked
that N-
upon
with alkali.
Examination
of the kinetics
chromogen formation
accumulation
of the former
(fig.
of substituted
linkage
and unsubsti-
I)
showed that the curve of had a lag-phase /14/ . It follows,
u.nequivocally,thatN-acetylhexosamine tein
oxidation
residues
the chain fragment
acetylhexosamines
oxidation
in formation of decreased chromogen /14/. This fact can be
N-acetylhexosamine with
periodate
results
as being due to periodate
nonreducing
tuted
of BGS after
at the carbohydrate-pro-
bear no branching.
lg(Dm-D)
1.1
Fig.
1. The kinetics of the substituted and unsubstituted chromogen formation from BGS treated with 0.05 M aqueous Na2C05 at 70". - unsubstituted chromogen - substituted chromogen. 586
Vol.39,No.4,
1970
BIOCHEMICAL
A combination followed
of degradation
by enzymatic
glycosidase
hydrolysis
preparation
molecular
weight
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
'15')
fragment
(6OA) and hexosamines
methods (Smith degradation by a Clostridium perfringens -----a--------e m-w resulted in isolation of a high-
consisting
mainly
(34%), the 2-acetamido-2-deoxy-D-galac-
tose to 2-acetamido-2-deoxy-D-glucose
7.5 : 1 '16'.
Alkaline
degradation
this
revealed
that
fragment
rate-protein
linkage
ratio
being
and periodate
equal to oxidation
in most of 0-glycosidic
a single
do-2-deoxy-D-galactose,was
HexNAc
of amino acids
monosaccharide,
of
carbohyd-
viz.
2-acetami-
present.
I
I R NH : I / Hefl,Ac I-3 HexNAc I-33 HexNAc I-3 GalNAc-OCRCH 6 6 \ f c=o i I .
f3
I Fuc I-4 GNAc
Gal1 6 \
?
peptide chain
I
GNAc 3-I Fuc 4 t I Gal 261 Fuc
3
Fuc I-2
?
t I Gal
3
3
t I
The scheme for presented
here may, of course,
ned in the light details
the carbohydrate
be completed,
of newer experimental
of attachment
cal activity
chain structure
of the part
to the fragment
built 587
of BGS
altered
data,particularly
responsible
for
or refion the
the biologi-
up of R-acetylhexossmines.
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 39, No. 4,197O
We should
like
scheme, viz. -
to emphasize two principal the high degree
and the presence of the fragment
of carbohydrate
in the region built
peculiarities
of this
chain branching
close to the peptide
backbone
up of only N-acetylhexosamines.
References 1. Watkins, W.M., in ltGlycoproteinsl' (Ed. A. Gottschalk) p. 462, Elsevier Publishing Company, Amsterdam, London, New York, 1966.
2. Koch&k&, N.K., Derevitskaya, V.A., and Kara-Murza, S.G., Carbohydrate Res., 2, 403 (1967). 3. Lloyd, K.O., Rabat, E.A. and Licerio, E., Biochemistry, 2, 2976 (1968). 4. Likhosherstov, L.M., Derevitskaya, V.A. and Fedorova, V.I., Biokhimiya, 4, 45 (1969). 5. Rege, V.P., Pain% er, T.J. Watkins, W.M. and Morgan, W.T.J., Nature, 200, 532 (1963j. 6. Lloyd, K., mat, E.A. Lagug, E. and Gruezo, F., Biochemistry, fz, 1489 (1966). 7. Likhosherstov, L.M., Bogdanova, L.S., Derevitskaya, V.A. and Kochetkov N.K., Iav. Akad. Nauk SSSR, Ser. Khim. (in press). 8. Zarnite, M.L. and Kabat, &:.A., J. Am. Chem. SOC., 82, 3953 (1960). 9. Marcus, D.M., Kabat, E.A. and Schiffman, G., Biochemistry, 2, 443 (19fJQ). 10. Tuppy, H. and Standcnlsher, W.L., Biochemistry, 2, 1742 N K Kikot' 11 . Ko:i%% G.S., Bogdanova, L.S., Likhosherstov, LfM.*&i Dereviiska a, V.A., Izv. Akad. Nauk SSSR, Ser. Khim., 2, 2085 (1968 3 . 12. Likhosherstov, L.M., Kikot', G.S., Derevitskaya, V.A., Arbatsky, N.P., Fedorova, V.I. and Kochetkov, N.K., Dokl. Akad. Nauk SSSR (in press, 1970). 13. Kochetkov, N.K., Derevitskaya, V.A., Likhosherstov, L.M., Martynova, M.D. and Senchenkova, S.M., Carbohydrate Res., (in press, 1970). 14. Likhosherstov, L.M., Senchenkova, S.N., Derevitskaya, V.I., and Kochetkov, N.K., Dokl. Akad. Nauk SSSR (in press). 15. Likhosherstov, L.M., Martynova, M.D., and Derevitskaya, V.A. Biokhimiya, 2, 1135 (1968). 16. Kochetkov, N.K., Derevitskaya, V.A., Likhosherstov, L.M. and Martynova, M.D., Dokl. Akad. Nauk SSSR, 186, 1195 (1969).
588