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Identification of collagen α1(I) trimer in embryonic chick tendons and calvaria
Vol. 78, No. 4, 1977
BIOCHEMICAL
IDENTIFICATION
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
OF COLLAGEN a,(I)
TRIMER IN
EMBRYONIC CHICK TENDONS AND CALVARIA
Sergio
A. Jimenez*,
Milton
Benditt
Department
and Ronald
of Medicine,
of Pennsylvania.
School
September
13,
Bashey,
Yankowski
of Medicine,
3700 Hamilton Pennsylvania
Received
Reza I.
Walk,
19174
University
Philadelphia,
U.S.A.
1977
SUMMARY: Collagen with a molecular composition [a (I)], has been identified in acetic acid extracts from lathyritic chic k embryo tendons and calvaria. These molecules characteristically have greater solubility than Type I collagen at neutral pH and contain increased amounts of hydroxylysine residues. It is suggested that these molecules represent a separate gene product of embryonic cells which may be important in the process of maturation and development. INTRODUCTION Although consist
it
has been well
of two CL (1) 1
to indicate a,(I)
that
chains
collagen
were
b,(I)
they
*
of
their
greater
molecules
(1)
evidence
has appeared
In these
have different
in normal should
Copyrighf 0 1977 by Academic Press, Inc. All rights of reproduction in any forrrt reserved.
studies
gingiva
tissues
of these
molecules
culture
in normal
salt
recent
collagen
collagen
amounts
the role
To whom correspondence
collagen
that
fractional
presence
interstitial
in tissue
time
molecules
during
Although
collagen. stration
the first
These
contain
(Z-6).
such as inflamed
I3 can be demonstrated
Type I collagen
conditions
chondrocytes
we show for
and calvaria.
ition,
certain
tissues
that
and one a 2 chain
be detected
either
from pathologic report
chains
under
could
established
(4)
tumors
molecules
with
residues not
tissues
[al(I)]3 obtained In this
a composition chick
tendons
characteristics at neutral
is
of
(3,6).
such as embryonic solubility
of three
fibroblasts
or
of hydroxylysine
embryonic
the sources
(2,5),
precipitation
molecules
composed
pH. than
apparent
as
suggests
that
than In addType I yet,
demon-
they
be addressed.
1354 ISSN
0006-291X
Vol. 78, No. 4, 1977
might
BIOCHEMICAL
be important
in the process
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of differentiation
MATERIALS
and development.
AND METHODS
Seventeen day old embryonated eggs were purchased from Shaw Hatcheries (West Chester, Pa.) and were maintained in a moist atmosphere at 37" until Twenty mg of 6 amino-propionitrlle dissolved in 0.1 ml of sacrificed. sterilized saline was injected into the chorio-allantoic membrane and the Tendons and calvaria were dissected and embryos were sacrificed 48 hr later. The tissues were extracted with they were rinsed in cold distilled water. The extracts were 0.5 N acetic acid at 4" for 72 hr with gentle shaking. The clear aspirated and clarified by centrifugation at 30,000 xg for 30 min. supernatants were dialyzed against 0.5 M acetic acid and after extensive the extracted collagens were precipitated by slow addition of solid dialysis, were collected by NaCl to a final concentration of 0.9 M. The precipitates centrifugation and resuspended in 1.0 M NaCl, 0.05 M Tris-HCI buffer pH 7.4 at 4". Differential NaCl precipitation was performed as described by Trelstad et al (7) and collagen fractions were obtained at increasing NaCl molarities. The Collagens precipitating at 1.71 M and at 2.5 M NaCl were removed. supernatant remaining after removal of the 2.5 M NaCl was brought up to 4.0 M with solid NaCl. The precipitate obtained was collected by centrifugation and it was resuspended in and dialyzed against 0.15 M NaCl 0.05 M Tris-HCl pH 7.4 at 4°C. The suspension was then clarified by centrifugation and collagen was re-precipitated at 2.5 M and 4.0 M NaCl as described above. Sodium dodecyl sulfate disc gel electrophoresis was performed on 5% polyacrylamide gels as described previously (8). Samples were denatured with 1% sodium dodecyl sulfate in the presence and absence of reducing agents by After electrophoresis the gels were stained with heating at 100" for 3 min. Coomassie Blue for 12 hr and subsequently de-stained in a solution of acetic Stained gels were scanned at 560 nm on a Gilford spectrophotoacid-methanol. meter fitted with a linear transporter. Determination of the area under each peak on the recorder tracings was made using a planimeter. For aminoacid analyses, aliquots under nitrogen in 6 N HCl for 18 hr of the hydrolyzate, the individual in a single column of resin eluted viously described (9) in a Beckman
of collagen suspensions were hydrolyzed and after evaporation and re-suspension aminoacids were separated by chromatography following a modification of a method preaminoacid analyzer.
RESULTS AND DISCUSSION When acetic examined the
stained
acid
by sodium
extracts
dodecyl
from
sulfate
electrophoretograms
lathyritic
chick
polyacrylamide quantitated
of a 1 to a chains were not 2:l 2 an excess of al chains was demonstrated.
tropocollagen sent
molecules
in addition
determine
composed
to molecules
the nature
of these
with
entirely
disc
as expected These from a
a composition
molecules
gel
fractional
1355
1
and calvaria
it for
a2.
that
Type I collagen
suggested
polypeptides (al)2
and
was found
pure
results
of
were
electrophoresis
by planimetry,
the ratios but
tendons
were
that also
pre-
To further
NaCl precipitation
was per-
Vol. 78, No. 4, 1977
TABLE I.
BIOCHEMICAL
ratios
Relative
Collagen
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of al to a2 chains
M NaCl precipitate
2.5 M NaCl re-precipitate of 4.0 M NaCl collagen
fraction
4.0 M NaCl re-precipitate of 4.0 M NaCl collagen
fraction
(a)
(b)
Average
of 5 determinations.
(cl
Average
of 3 determinations.
Cd)
Average
of 2 determinations.
As shown previously
molecules extracts ratio
with
result
rived
that
from Type III
When the collagen with
polypeptides molecules precipitated
with
only
3.6:1(')
2.3:lcd)
2.7:Gd)
13.1:dd)
collagen
composed
remaining
of 2:l
were
a greater 1).
1356
and the unchanged.
probably
not
de-
in 0.15
Type I collagen.
was further
precipi-
of a 1 over purification
excess
Further
was accomplished
4 M NaCl was re-suspended
of the
at 2.5 M NaCl contained
at 2.5 M NaCl
I and Fig.
al chains
was essentially
and was therefore
containing
[al(IIl)13
of collagen
precipitated
in solution
(Table
fraction
al polypeptides
Collagen
a fraction
only
a minor
of
Precipitation
in the supernatant
in a ratio
was obtained containing
3.2:lcb)
Type III
the excess
collagen.
4 M NaCl
2.4:1
at low NaCl concentrations.
and a2 polypeptides
tated
(7)
remaining
indicated
2.3:1
of acetic acid extracted lathyritic described by Trelstad (7) and aliquots were dodecyl sulfate-polyacrylamide gels. After the gels were scanned, and the areas under and a2 chains were quantitated with a
1.7 M NaCl removed
of polypeptides
This
5
is precipitated
(a)
fractions
Calvaria
10.8:dd)
Fractional NaCl precipitation collagen was performed as electrophoresed on sodium staining and de-staining, peaks corresponding to al planimeter.
formed.
collagen
Tendon
Fraction
0.9 M NaCl precipitate 4.0
in various
a
2
of
when the collagen M NaCl,
0.05
M Tris
HCl
Vol. 78, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
m
1357
Vol. 78, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
B
Figure
2.
pH 7.4,
Photograph of Coomassie Blue stained gels of p urified [al( collagen from tendon and calvaria. (A) 2.5 M NaCl preciplta ed tendon collagen containing predominantly Type I collagen; (B) tendon and (C) calvaria [a (I)] before reduction of disulfide bonds; (D) tendon and (E)lcalvzria [al(I)]3 after reduction of disulfide bonds.
and solid
NaCl was added
in precipitation 2.3:1
which
to that
this
and a highly a
at least
1O:l
chains
close
after
entirely
a2
of a collagen is
in solution tration
1
chains
step was then
I),
fraction
collagen,
we examined
as described
a
precipitated
and a
1
again
above represented of disulfide (7,10,11).
1358
chains
resulted
in a ratio
was not that
remaining
at 4 M NaCl concen-
which
to a2 ratios it
2
This
The collagen
of collagen
the possibility
molecules
of 2.5 M.
Type I collagen.
The al
the effects
of these
both
and in some cases
To exclude
2).
purified
behavior
of pure
was obtained.
(Table
(Fig.
to a concentration
containing
purified
molecules
phoretic
C
contained
almost
in these
fractions
was
possible
to detect
any
the tropocollagen
either
Type III
bond reduction Comparison
or Type IV
on the of electro-
electro-
Vol. 78, No. 4, 1977
TABLE II.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Aminoacid composition of collagen fractions re-precipitated 4 M NaCl compared to other collagen polypeptides(a)
Aminoacid
3-Hydroxyproline 4-Hydroxyproline
Tendon
Calvaria
1.5
ra,(I)lp
al(T)(c)
1.8
2.3
i.0
with
u,(rI)(d)
2.2
110
104
108
102
103
46
45
45
42
42
Threonine
19
19
20
19
26
Serine
31
30
39
29
26
70
76
77
78
a7
Aspartic
Glutamic
acid
acid
Proline
119
117
109
118
115
Glycine
331
330
334
330
329
Alanine
113
119
111
129
104
Valine
13
14
18
14
16
Methionine
7.1
Isoleucine
10
Leucine
24
Tyrosine
2.4
6.0
7.5
8.2
9.0
a.7
6.1
22
23
3.5
2.2
20 2.0
11 7.8 26 2.2
Phenylalanine
13
13
12
14
15
Lysine
27
25
24
30
13
Hydroxylysine
11
13
11
Histidine Arginine Hydroxylysine Lysine
(a) (b) (c) (d)
2.8 49
0.41
Residues per 1000 residues. Pepsin treated TSD4 collagen Chick bone collagen (15). Chick sternal cartilage (15).
5.0
2.5
48
46
0.52
0.46
(3).
1359
5.1 2.0 51
0.17
23 2.0 50
1.77
Vol. 78, No. 4, 1977
phoretograms ences
BlOCHEMlCAL
of reduced
in collagen
of reducing
agent.
held
and urn-educed
in the distribution
no increase
The migration authentic
migrating
bonds
were
derived
as shown previously
similar
to those
collagens chains present here
of Type II
II).
in hyaline contained
collagens by other
these
The presence
peculiar
feature
clear number
hydroxylase al(I)
systems
as well
has not
been previously
molecules.
but
it
of lysine than chains
that
residues
capable
shown to our
but
their
knowledge.
1360
residues.
to be a constant
This
may result
content
primary of being
Tropocollagen
have been demonstrated (2-6)
of lysine
residues structure
in these con-
hydroxylated
in several
Since
The mech-
molecules
presence
in
of hydroxy-
of lysine their
Type I collagen.
as in some tumors
similarity
carbohydrate.
hydroxylation
is likely
isolated fractional
striking
appears
such as increased
increased
exclusively
during
another
or hydroxylysine-linked
of al(II)
molecules
in hydroxylation
collagen
that
These
behaviour
of lysine
of these
cartilage.
to similar
hydroxylation
the
than
are
employed
collagen
the increase
here
some
the tissues
[a,(I)],
electrophoresis
which
composition
of contaminating
the
characteristics
for
of three
gel
of these
responsible
posed
amounts
that
these
Although
obtained
the aminoacid
of
that
(11-14).
fractions
unlikely
is
resemble
is
anism
lysyl
collagen
In addition
cross-links
the
and it
of increased
a greater
mobility
not
[al(IV)]3.
procollagen
or
is almost
derived
tains
the possibilities
Type IV collagen
Type II
or
were
the same as that
collagen
collagens
is not
[ol(III)]3
In addition,
lysine
molecules
not
was
in the absence molecules
chains
and disc
structural
and there
of al(I)
(3,4).
and distinctive
chains
collagen
was about
(15),
any differ-
more the composition
closely
NaCl precipitation
were
electrophoretic
any significant
authors
between
either
reveal
of y-chains
the
excluded
collagen
cartilage
however,
that
they
of the c11 -rich
resembled (Table
from
have less
of the characteristics
showed
result
not
polypeptide
polypeptides
This
did
the position
and therefore
chains.
polypeptides
in
results
of the reduced al(I)
molecules
of the individual
These
by disulfide
AND BIOPHYSICAL RESEARCH COMMUNlCATlONS
&
com-
vitro
in normal
embryonic
by
tissues
tissues
appear
BIOCHEMICAL
Vol. 78, No. 4, 1977
to contain
greater
that
presence
their
capability
which
and maturation. u,(I)
trimer
amounts
of these
in diseased is normally If
this
molecules
tissues lost
suggestion
may be indicative
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
during is
of cell
than
adult
and tumors
it
is
possible
may be due to expression
the process confirmed,
tissues,
of tissue
demonstration
of a
differentiation of collagen
de-differentiation.
ACKNOWLEDGEMENTS We acknowledge the assistance of Ms. Esther Lobb. NO 1 HV 4 2982 and USPH Grant HL-19128. NIH Contract 1. 2. 3.
Supported
in part
by
REFERENCES PIEZ, K.A. (1967) In Treatise on Collagen (Ramachandran, G.N., editor) Vol. I, pp. 207-252, Academic Press, New York. MAYNE, R., VAIL, M.S., AND MILLER, E.J. (1975) Proc. Nat. Acad. Sci. U.S.A. 72, 4511-4515. LITTLE, CH.D., CHURCH, R.L., MILLER, R.A., AND RUDDLE, F.H. (1977) Cell lo, 287-295.
4. 5. 6. 7. 8. 9.
10. 11. 12. 13. 14. 15.
Chem. 251, 5464-5471. NARAYANAN, A.S., AND PAGE, R.C. (1976) J. Biol. 16, 865. BENYA, R.D., PADILLA, R., AND NIMNI, M.E. (1977) Biochemistry MORO, L., AND SMITH, B.D. (1977) Arch. Biochem. Biophys. 182, 33-41. TRELSTAD, R.L., CATANESE, V.M., AND RUBIN, D.F. (1976) Analytical Biochem. 2, 114-118. JIMENEZ, S.A., AND ROSENBLOOM, J. (1974) Arch. Biochem. Biophys. 163, 459-465 Biophys UITTO, J., JIMENEZ, S.A., DEHM, P., AND PROCKOP, D.J. (1972) Biochim. Acta 278, 198-205. 13, 3459-3467. CHUNG, E., KEELE, E.M., AND MILLER, E.J. (1974) Biochemistry KEFALIDES, N.A. (1971) Biochem. Biophys. Res. Comm. g, 226-234. LAYMAN, D.L., MCGOODWIN, E.B., AND MARTIN, G.R. (1971) Proc. Nat. Acad. Sci. U.S.A. 68, 454. BELLAMY, G., AND BORNSTEIN, P. (1971) Proc. Nat. Acad. Sci. U.S.A. 68, 1138. .JIMENEZ, S.A., DEHM, P., AND PROCKOP, D.J. (1971) Fed. Eur. Biochem. Sot. Lett. 17, 245. MILLER, E.J. (1971) Biochemistry lo, 1652-1659.
1361
BIOCHEMICAL
IDENTIFICATION
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
OF COLLAGEN a,(I)
TRIMER IN
EMBRYONIC CHICK TENDONS AND CALVARIA
Sergio
A. Jimenez*,
Milton
Benditt
Department
and Ronald
of Medicine,
of Pennsylvania.
School
September
13,
Bashey,
Yankowski
of Medicine,
3700 Hamilton Pennsylvania
Received
Reza I.
Walk,
19174
University
Philadelphia,
U.S.A.
1977
SUMMARY: Collagen with a molecular composition [a (I)], has been identified in acetic acid extracts from lathyritic chic k embryo tendons and calvaria. These molecules characteristically have greater solubility than Type I collagen at neutral pH and contain increased amounts of hydroxylysine residues. It is suggested that these molecules represent a separate gene product of embryonic cells which may be important in the process of maturation and development. INTRODUCTION Although consist
it
has been well
of two CL (1) 1
to indicate a,(I)
that
chains
collagen
were
b,(I)
they
*
of
their
greater
molecules
(1)
evidence
has appeared
In these
have different
in normal should
Copyrighf 0 1977 by Academic Press, Inc. All rights of reproduction in any forrrt reserved.
studies
gingiva
tissues
of these
molecules
culture
in normal
salt
recent
collagen
collagen
amounts
the role
To whom correspondence
collagen
that
fractional
presence
interstitial
in tissue
time
molecules
during
Although
collagen. stration
the first
These
contain
(Z-6).
such as inflamed
I3 can be demonstrated
Type I collagen
conditions
chondrocytes
we show for
and calvaria.
ition,
certain
tissues
that
and one a 2 chain
be detected
either
from pathologic report
chains
under
could
established
(4)
tumors
molecules
with
residues not
tissues
[al(I)]3 obtained In this
a composition chick
tendons
characteristics at neutral
is
of
(3,6).
such as embryonic solubility
of three
fibroblasts
or
of hydroxylysine
embryonic
the sources
(2,5),
precipitation
molecules
composed
pH. than
apparent
as
suggests
that
than In addType I yet,
demon-
they
be addressed.
1354 ISSN
0006-291X
Vol. 78, No. 4, 1977
might
BIOCHEMICAL
be important
in the process
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of differentiation
MATERIALS
and development.
AND METHODS
Seventeen day old embryonated eggs were purchased from Shaw Hatcheries (West Chester, Pa.) and were maintained in a moist atmosphere at 37" until Twenty mg of 6 amino-propionitrlle dissolved in 0.1 ml of sacrificed. sterilized saline was injected into the chorio-allantoic membrane and the Tendons and calvaria were dissected and embryos were sacrificed 48 hr later. The tissues were extracted with they were rinsed in cold distilled water. The extracts were 0.5 N acetic acid at 4" for 72 hr with gentle shaking. The clear aspirated and clarified by centrifugation at 30,000 xg for 30 min. supernatants were dialyzed against 0.5 M acetic acid and after extensive the extracted collagens were precipitated by slow addition of solid dialysis, were collected by NaCl to a final concentration of 0.9 M. The precipitates centrifugation and resuspended in 1.0 M NaCl, 0.05 M Tris-HCI buffer pH 7.4 at 4". Differential NaCl precipitation was performed as described by Trelstad et al (7) and collagen fractions were obtained at increasing NaCl molarities. The Collagens precipitating at 1.71 M and at 2.5 M NaCl were removed. supernatant remaining after removal of the 2.5 M NaCl was brought up to 4.0 M with solid NaCl. The precipitate obtained was collected by centrifugation and it was resuspended in and dialyzed against 0.15 M NaCl 0.05 M Tris-HCl pH 7.4 at 4°C. The suspension was then clarified by centrifugation and collagen was re-precipitated at 2.5 M and 4.0 M NaCl as described above. Sodium dodecyl sulfate disc gel electrophoresis was performed on 5% polyacrylamide gels as described previously (8). Samples were denatured with 1% sodium dodecyl sulfate in the presence and absence of reducing agents by After electrophoresis the gels were stained with heating at 100" for 3 min. Coomassie Blue for 12 hr and subsequently de-stained in a solution of acetic Stained gels were scanned at 560 nm on a Gilford spectrophotoacid-methanol. meter fitted with a linear transporter. Determination of the area under each peak on the recorder tracings was made using a planimeter. For aminoacid analyses, aliquots under nitrogen in 6 N HCl for 18 hr of the hydrolyzate, the individual in a single column of resin eluted viously described (9) in a Beckman
of collagen suspensions were hydrolyzed and after evaporation and re-suspension aminoacids were separated by chromatography following a modification of a method preaminoacid analyzer.
RESULTS AND DISCUSSION When acetic examined the
stained
acid
by sodium
extracts
dodecyl
from
sulfate
electrophoretograms
lathyritic
chick
polyacrylamide quantitated
of a 1 to a chains were not 2:l 2 an excess of al chains was demonstrated.
tropocollagen sent
molecules
in addition
determine
composed
to molecules
the nature
of these
with
entirely
disc
as expected These from a
a composition
molecules
gel
fractional
1355
1
and calvaria
it for
a2.
that
Type I collagen
suggested
polypeptides (al)2
and
was found
pure
results
of
were
electrophoresis
by planimetry,
the ratios but
tendons
were
that also
pre-
To further
NaCl precipitation
was per-
Vol. 78, No. 4, 1977
TABLE I.
BIOCHEMICAL
ratios
Relative
Collagen
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of al to a2 chains
M NaCl precipitate
2.5 M NaCl re-precipitate of 4.0 M NaCl collagen
fraction
4.0 M NaCl re-precipitate of 4.0 M NaCl collagen
fraction
(a)
(b)
Average
of 5 determinations.
(cl
Average
of 3 determinations.
Cd)
Average
of 2 determinations.
As shown previously
molecules extracts ratio
with
result
rived
that
from Type III
When the collagen with
polypeptides molecules precipitated
with
only
3.6:1(')
2.3:lcd)
2.7:Gd)
13.1:dd)
collagen
composed
remaining
of 2:l
were
a greater 1).
1356
and the unchanged.
probably
not
de-
in 0.15
Type I collagen.
was further
precipi-
of a 1 over purification
excess
Further
was accomplished
4 M NaCl was re-suspended
of the
at 2.5 M NaCl contained
at 2.5 M NaCl
I and Fig.
al chains
was essentially
and was therefore
containing
[al(IIl)13
of collagen
precipitated
in solution
(Table
fraction
al polypeptides
Collagen
a fraction
only
a minor
of
Precipitation
in the supernatant
in a ratio
was obtained containing
3.2:lcb)
Type III
the excess
collagen.
4 M NaCl
2.4:1
at low NaCl concentrations.
and a2 polypeptides
tated
(7)
remaining
indicated
2.3:1
of acetic acid extracted lathyritic described by Trelstad (7) and aliquots were dodecyl sulfate-polyacrylamide gels. After the gels were scanned, and the areas under and a2 chains were quantitated with a
1.7 M NaCl removed
of polypeptides
This
5
is precipitated
(a)
fractions
Calvaria
10.8:dd)
Fractional NaCl precipitation collagen was performed as electrophoresed on sodium staining and de-staining, peaks corresponding to al planimeter.
formed.
collagen
Tendon
Fraction
0.9 M NaCl precipitate 4.0
in various
a
2
of
when the collagen M NaCl,
0.05
M Tris
HCl
Vol. 78, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
m
1357
Vol. 78, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
B
Figure
2.
pH 7.4,
Photograph of Coomassie Blue stained gels of p urified [al( collagen from tendon and calvaria. (A) 2.5 M NaCl preciplta ed tendon collagen containing predominantly Type I collagen; (B) tendon and (C) calvaria [a (I)] before reduction of disulfide bonds; (D) tendon and (E)lcalvzria [al(I)]3 after reduction of disulfide bonds.
and solid
NaCl was added
in precipitation 2.3:1
which
to that
this
and a highly a
at least
1O:l
chains
close
after
entirely
a2
of a collagen is
in solution tration
1
chains
step was then
I),
fraction
collagen,
we examined
as described
a
precipitated
and a
1
again
above represented of disulfide (7,10,11).
1358
chains
resulted
in a ratio
was not that
remaining
at 4 M NaCl concen-
which
to a2 ratios it
2
This
The collagen
of collagen
the possibility
molecules
of 2.5 M.
Type I collagen.
The al
the effects
of these
both
and in some cases
To exclude
2).
purified
behavior
of pure
was obtained.
(Table
(Fig.
to a concentration
containing
purified
molecules
phoretic
C
contained
almost
in these
fractions
was
possible
to detect
any
the tropocollagen
either
Type III
bond reduction Comparison
or Type IV
on the of electro-
electro-
Vol. 78, No. 4, 1977
TABLE II.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Aminoacid composition of collagen fractions re-precipitated 4 M NaCl compared to other collagen polypeptides(a)
Aminoacid
3-Hydroxyproline 4-Hydroxyproline
Tendon
Calvaria
1.5
ra,(I)lp
al(T)(c)
1.8
2.3
i.0
with
u,(rI)(d)
2.2
110
104
108
102
103
46
45
45
42
42
Threonine
19
19
20
19
26
Serine
31
30
39
29
26
70
76
77
78
a7
Aspartic
Glutamic
acid
acid
Proline
119
117
109
118
115
Glycine
331
330
334
330
329
Alanine
113
119
111
129
104
Valine
13
14
18
14
16
Methionine
7.1
Isoleucine
10
Leucine
24
Tyrosine
2.4
6.0
7.5
8.2
9.0
a.7
6.1
22
23
3.5
2.2
20 2.0
11 7.8 26 2.2
Phenylalanine
13
13
12
14
15
Lysine
27
25
24
30
13
Hydroxylysine
11
13
11
Histidine Arginine Hydroxylysine Lysine
(a) (b) (c) (d)
2.8 49
0.41
Residues per 1000 residues. Pepsin treated TSD4 collagen Chick bone collagen (15). Chick sternal cartilage (15).
5.0
2.5
48
46
0.52
0.46
(3).
1359
5.1 2.0 51
0.17
23 2.0 50
1.77
Vol. 78, No. 4, 1977
phoretograms ences
BlOCHEMlCAL
of reduced
in collagen
of reducing
agent.
held
and urn-educed
in the distribution
no increase
The migration authentic
migrating
bonds
were
derived
as shown previously
similar
to those
collagens chains present here
of Type II
II).
in hyaline contained
collagens by other
these
The presence
peculiar
feature
clear number
hydroxylase al(I)
systems
as well
has not
been previously
molecules.
but
it
of lysine than chains
that
residues
capable
shown to our
but
their
knowledge.
1360
residues.
to be a constant
This
may result
content
primary of being
Tropocollagen
have been demonstrated (2-6)
of lysine
residues structure
in these con-
hydroxylated
in several
Since
The mech-
molecules
presence
in
of hydroxy-
of lysine their
Type I collagen.
as in some tumors
similarity
carbohydrate.
hydroxylation
is likely
isolated fractional
striking
appears
such as increased
increased
exclusively
during
another
or hydroxylysine-linked
of al(II)
molecules
in hydroxylation
collagen
that
These
behaviour
of lysine
of these
cartilage.
to similar
hydroxylation
the
than
are
employed
collagen
the increase
here
some
the tissues
[a,(I)],
electrophoresis
which
composition
of contaminating
the
characteristics
for
of three
gel
of these
responsible
posed
amounts
that
these
Although
obtained
the aminoacid
of
that
(11-14).
fractions
unlikely
is
resemble
is
anism
lysyl
collagen
In addition
cross-links
the
and it
of increased
a greater
mobility
not
[al(IV)]3.
procollagen
or
is almost
derived
tains
the possibilities
Type IV collagen
Type II
or
were
the same as that
collagen
collagens
is not
[ol(III)]3
In addition,
lysine
molecules
not
was
in the absence molecules
chains
and disc
structural
and there
of al(I)
(3,4).
and distinctive
chains
collagen
was about
(15),
any differ-
more the composition
closely
NaCl precipitation
were
electrophoretic
any significant
authors
between
either
reveal
of y-chains
the
excluded
collagen
cartilage
however,
that
they
of the c11 -rich
resembled (Table
from
have less
of the characteristics
showed
result
not
polypeptide
polypeptides
This
did
the position
and therefore
chains.
polypeptides
in
results
of the reduced al(I)
molecules
of the individual
These
by disulfide
AND BIOPHYSICAL RESEARCH COMMUNlCATlONS
&
com-
vitro
in normal
embryonic
by
tissues
tissues
appear
BIOCHEMICAL
Vol. 78, No. 4, 1977
to contain
greater
that
presence
their
capability
which
and maturation. u,(I)
trimer
amounts
of these
in diseased is normally If
this
molecules
tissues lost
suggestion
may be indicative
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
during is
of cell
than
adult
and tumors
it
is
possible
may be due to expression
the process confirmed,
tissues,
of tissue
demonstration
of a
differentiation of collagen
de-differentiation.
ACKNOWLEDGEMENTS We acknowledge the assistance of Ms. Esther Lobb. NO 1 HV 4 2982 and USPH Grant HL-19128. NIH Contract 1. 2. 3.
Supported
in part
by
REFERENCES PIEZ, K.A. (1967) In Treatise on Collagen (Ramachandran, G.N., editor) Vol. I, pp. 207-252, Academic Press, New York. MAYNE, R., VAIL, M.S., AND MILLER, E.J. (1975) Proc. Nat. Acad. Sci. U.S.A. 72, 4511-4515. LITTLE, CH.D., CHURCH, R.L., MILLER, R.A., AND RUDDLE, F.H. (1977) Cell lo, 287-295.
4. 5. 6. 7. 8. 9.
10. 11. 12. 13. 14. 15.
Chem. 251, 5464-5471. NARAYANAN, A.S., AND PAGE, R.C. (1976) J. Biol. 16, 865. BENYA, R.D., PADILLA, R., AND NIMNI, M.E. (1977) Biochemistry MORO, L., AND SMITH, B.D. (1977) Arch. Biochem. Biophys. 182, 33-41. TRELSTAD, R.L., CATANESE, V.M., AND RUBIN, D.F. (1976) Analytical Biochem. 2, 114-118. JIMENEZ, S.A., AND ROSENBLOOM, J. (1974) Arch. Biochem. Biophys. 163, 459-465 Biophys UITTO, J., JIMENEZ, S.A., DEHM, P., AND PROCKOP, D.J. (1972) Biochim. Acta 278, 198-205. 13, 3459-3467. CHUNG, E., KEELE, E.M., AND MILLER, E.J. (1974) Biochemistry KEFALIDES, N.A. (1971) Biochem. Biophys. Res. Comm. g, 226-234. LAYMAN, D.L., MCGOODWIN, E.B., AND MARTIN, G.R. (1971) Proc. Nat. Acad. Sci. U.S.A. 68, 454. BELLAMY, G., AND BORNSTEIN, P. (1971) Proc. Nat. Acad. Sci. U.S.A. 68, 1138. .JIMENEZ, S.A., DEHM, P., AND PROCKOP, D.J. (1971) Fed. Eur. Biochem. Sot. Lett. 17, 245. MILLER, E.J. (1971) Biochemistry lo, 1652-1659.
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