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Synthesis of interstitial collagens by pig aortic endothelial cells in culture
Vol. 84, No. 3, 1978 October
BIOCHEMICAL
RESEARCH COMMUNICATIONS
16, 1978
SYNTHESIS
OF
Pages
INTERSTITIAL M.J.
Medical
AND BIdPHYSICAL
Research University
Received
Barnes,
14,
BY PIG
L.F.
Council, Cambridge,
of
August
COLLAGENS
Morton
Connective Tennis
AORTIC and
ENDOTHELIAL
C.I.
646-653
CELLS
IN
CULTURE
Levene
Tissue Team, Department Court Road, Cambridge,
of U.K.
Pathology,
1978
SUMMARY: Examination of the collagens synthesized by pig aortic endothelial min culture and precipitated from either the cell layer or medium, following pepsin digestion, demonstrated that the major species was Type I together with some Type III collagen and al (I) trimer. Additional chains in the cell layer chromatographing with Type I al-chains on CM cellulose may be partly derived from basement-membrane-associated collagen but in the medium would appear to be entirely derived from al (I) trimer. These results imply that the endothelial cell may secrete the Type III collagen located in the immediate subendothelial space and, in part at least, the Types I and III occurring in diffusely thickened intima and the atherosclerotic plaque. Endothelial described of
the
offers
cells
as
of
basement
first
synthesize,
permit
collagen
that
endothelial Types
definitive
the has
space I and
diffusely
III
in
primarily
the
this
have
cell
medial
wall been
(authors'
Collagen the
cultured
may
and
detected
by
smooth
muscle
I and
at
has cell
Type
immediate least
data)
sites
can III>.
the
chemical
been
been
derivation
cells
the
(or
has
communication
secrete in
these
the
(Types
unpublished at
with
endothelial
type
(4)
that
This
collagens
vessel
intima
(5).
accord
immunohistochemically
that
human
in
(1,2,3)
endothelium.
that
that
blood
collagens
from
the
interstitial
located
plaque
from
evidence the
been
collagen
(1,2)
inference
thickened
atherosclerotic originate
synthesize
membrane
additionally,
findings
culture
basement-membrane-type
vascular the
in
in
III sub-
part)
analysis and
Gur
in
considered
the in
the to
(6).
MATERIALS AND METHODS: Culture of endothelial cells Endothelial cells were obtained as before (3) from pig aorta by the method of Jaffe et al (7) as modified Endothelial cells so isolated and then subcultured 5-6 by Leake and Bowyer (8). times in 199 medium containing 20% foetal calf serum (FCS), were kindly provided by the latter authors. For the purposes of the present investigation, cells were grown in 60 mm Falcon dishes at an initial density of 50,000 in 4 ml of Dulbecco and Vogt's modification of Eagle's bIEM containing 10% FCS. Medium was exchanged for fresh every three days. After six days, ascorbic acid (50 u,g/ml) was added to the medium. At specified days, indicated later, medium was replaced with fresh containing either L- [G-3H] proline or L- [4,5-3H ]lysine (generally 0.5 mCi/dish) and ascorbic acid (50ug/ml). After 24h, plates were either 0006-291x/78/0843-0646$01.00/0
Copyright 0 1978 by Academic Press, Inc. All rights of reproduction in any form reserved.
646
Vol. 84, No. 3, 1978
BIOCHEMICAL
AND BIdPHYSICAL
RESEARCH COMMUNICATIONS
harvested or a further supplement of ascorbic acid was given. In the latter case dishes were harvested 24h later. Radiolabelled collagens in the cell layer and medium were examined as described below. Examination of cell layer collagens Digestion of cell layers, dispersed in 0.5M acetic acid, with pepsin, precipitation of the digest at 0.9M NaCl and the separation of precipitated collagens by differential salt precipitation, all in the presence of carrier were undertaken as before (9). Fractions precipitating at I, 1.71, 2.1 and 2.56M NaCl were collected and examined by CM cellulose chromatography. Examination of collagens in the medium The medium following dialysis was digested with pepsin as described previously (9). The digest was dialysed against 0.41 Na phosphate buffer, pH 7.6. After addition of carrier collagen (prepared by precipitation of a pepsin digest of pig aorta by dialysis against 0.02M Na2HP04) at approx 3mg/ml, collagens in the digest were precipitated by dialysis against 0.02M phosphate. The precipitate was redissolved in the 0.41 buffer and then incubated overnight at 37O (IO) to effect the thermal gelation of interstitial collagens. The gel was centrifuged for 30 min at 10,000 g at 25O. The residue (containing interstitial collagens) and supernatant were examined by CM cellulose chromatography. A portion of the supernatant was subjected to a second gelation by means of a modification of the above procedure (Dr. J. Rauterberg, unpublished data). The sample after addition of carrier collagen at approx 3 mg/ml was diluted to 0.21 , incubated at 37O for 6h and then dialyzed at 20° against IO vol H 0 overnight. The precipitate was collected by centrifugation as above. CM cellu f ose chromatography was exactly as before (9). Radioactivity in the eluate was measured as before (II) except that PCS (Amersham/Searle Corp.) diluted 2:1 (v/v) with xylene, was used as scintillant. Gel chromatography was undertaken with a column (140 x 1.5cm) of Sepharose CL-6B; conditions were otherwise as before (9). Radioactivity in the eluate was measured as above. Collagenase digestion Samples of the cell layer, after dispersal (IO), or medium or fractions derived therefrom were dialysed against 0.05M tris-HCl, pH7.g (at 25O) containing O.OiM Ca acetate and 0.02% Na azide, denatured at 100 for 5 min, and then redialyzed. Collagenase (Worthington's CLSPA purified and treated as described by Benya et al (12))was added at 20 units/ml. Samples were incubated for 6h at 370, then dialyzed against water and the diffusate in each case lyophilized prior to hydrolysis. Hydrolysis Samples were heated in 6N HCl in sealed tubes at 1080 for 24h. Hydrolysates were dried in vacua in a dessicator over cont. H2S04 in the presence of NaOH pellets. Measurement of lysine and hydroxylysine radioactivity in hydrolysates was as before (II). Measurement of proline and hydroxyproline radioactivity in hydrolysates.proline and hydroxyproline were separated on a Technicon Amino Acid Autoanalyzer at 60° using the standard citrate buffer, pH 2.9. Radioactivity in the eluate was counted as above. RESULTS:
In initial
studies
collagenase-susceptible the period
indicated
the % conversion
material
of lysine
in cultures
labelled
to hydroxylysine [ 3 H] lysine
with
in during
was as follows:-
Expt.
I;
5-7d:
Cell
layer,
19; Medium,
Expt.
2; 6-7d:
Cell
layer,
5; Medium,
Since
basement-membrane
(Type
24. 44.
IV) collagen
647
IO-12d:
Cell
layer,
26; Medium,
23.
12-13d:
Cell
layer,
15; Medium,
52.
exhibits
values
of about
80% (13-17)
BIOCHEMICAL
Vol. 84, No. 3, 1978
the
figures
above
This
was
C3~]
proline-labelled
taken
by
a more
confirmed
Examination
was
in
pro/hyp
that
collagenase was
upon (of
than In
one Expt.
activity as
salt
collagens
2:i
and
the
in
Na2
HP04
there The
obtained
not a ratio
obviously appreciably
material
was
the % distribution collagens
pepsin
collagenous
certainly,was
This
the
(18).
respectively)
(where
of
separate
remainder,
unprecipitated
collagen
lo-lad),
two in
Of
0.02M 4:l
the and,
fractionation
synthesized
In
NaCl.
against
(13-17)).
from
collagens.
hydroxyproline
O.QM
dialysis
anticipated
1 (labelled
following
of
examined
total
precipitated
no
further.
radio-
at
O.QM
NaCl
was
follows:-
II,! ppt,
4; In
1.71~
and
al:a2:
ratio al(I)
known
1)
revealed
al
(I)
and
of
5 in
region,
usually
16;
with
(Fig.
fraction
the
ppt,
accord
cellulose
at
with
to
precipitate
have
been
shown Expt.
M ppt,
the a2
2.56
a higher Type
generally
III
collagen
from
Type
I in
the
2.56M
indicated
presence
either
molarity
than
(24))
or
an of
perhaps
vicinity
of
Q-lld),
the
in
NaCl
of (al) (19-23)
IV
the
1.711 The
chains
in
trimer
(which
collagen a-chains
(I)
chains
% distribution
CM
but
and al
21.
fraction.
I
Type
(25-27)
on
excess
Type
2.56M
2M NaCl the
- soluble,
chromatography
Type
in
from
2.56M
of
around
chromatograph
2 (labelled
I
34;
presence
fraction the
M ppt,
bebaviour,
chains
latter
normal
to
25;
precipitation
suggesting
known
In
2.1
the
precipitates
coprecipitate
as
be
interstitial
layer
["II]
at
IV)
the
cell
total
material (Type
might
the
suggested
under-hydroxylated
basement-membrane-related less
in
approx
treatment
of
below.
precipitated
ratio
of
described
the
RESEARCH COMMUNICATIONS
synthesis
analysis
of
precipitation
following moiety
as
two-thirds
radioactivity
the
collagens
material
negligible
indicate
detailed
radio-labelled approx.
digest
to
cultures
of
experiments,
was
were
AND BidPHYSICAL
can which
from
in is
which
(13).
of
radioactivity
2.56
M-soluble,
was
follows:-
1M PPt,
9;
In
instance
this
cellulose
1.71
M ppt, , most
chromatography
17;
2.1
M ppt,
of
the
radioactivity
again
54;
indicated
2.56
4;
precipitated the
648
M ppt,
presence
at of
Type
2.lM III
part
NaCl. collagen
16. CM:
Vol. 84, No. 3, 1978
BIOCHEMICAL
0
Figure
10
the
1.7iM
located The
M
I 70
60
in
al(I)
elevated
al:a2
suggesting
rather was
a single since
close
be
in
Type
gel a-chain
the
in
was
CM cellulose
of
of
and
the
the
position
The of
precipitated
the 2.561
al
al-peak
revealed
21,
Type
pro/hyp
Type
IV
radioactivity
fraction
revealed (not
I,
a
perhaps to
(I)-chains
after
2).
was
attributable
However peaks.
(Fig.
a2-peak
(Fig.
were
was
I collagen The
greater
al(I)
these
that
Type
However,
size
ppt.
radioactivity
noted,
(14-17,281.
in
material
again again
regionof
all
fraction,
filtration.
I trimer
unity
represents
nature
pro/hyp
trimer. the
on
of
5)
2.lM
I).
is
only
shown)
and
considered
al(I)-trimer. The
The
to
peak this
chains
the
indicative
by
peaks
than
In
(approx. size
with
2.56M
shown).
regions
ratio
excess
collagen
~2
a-chain
pattern
ratio
(not and
of
complex
1.71M ppt.
fraction
essentially
to
M 40 FRACTION NUMBER
RESEARCH COMMUNICATIONS
1. Endothelial cells in culture: CM cellulose chromatography of the precipitates at 1.71 and 2.561 NaCl obtained in the fractionation of radiolabelled cell layer collagens isolated after pepsin treatment (Expt. Badioactivityina 0.5 ml aliquot of each 10 ml fraction of the eluate was counted in 10 ml of scintillant at 30% efficiency. The position of marker chains aa indicated was established by chromatography of appropriate unlabelled collagens. The results relate to the cell layers pooled from three plates, each labelled with 0.3 mCi[L G-3H] proline from lo-12d.
-----------
in
al
AND BIdPHYSICAL
of
derived
collagenous
radioactivity However
front
the
and from
ratio
Cbl cellulose failed
Type
material
to
reveal
V collagen
of
1.4
soluble
was
compatible
chromatography either which
al could
(18,24.29,30).
649
at
with
exhibited (I)
chains
also
in
2.56M
only or
theory
USA! occur
NaCl its
is
uncertain.
identity
a single and in
as peak
~1: Bl this
al at
chains fraction
(I)
Vol. 84, No. 3, 1978
BIOCHEMICAL
2.(A) CR cellulose chromatography of the precipitate at 2.1M NaCl obtained in the fractionation of radiolabelled cell layer collagens isolated after pepsin treatment (Expt. 2). Radioactivity in a 0.5 ml aliquot of each 10 ml fraction of the eluate was counted in 5 ml of scintillant (in polypropylene inserts) at 20% efficiency. The results relate to the cell layers pooled from six plates, each labelled with 0.5 mCi L [G3H] proline from g-lid; one third of the total sample was chromatographed. (B) Gel filtration of al(I) chains: Fractions 22-31 of the above chromatogram were pooled, dialyzed against 0.15M acetic acid, lyophilized and a portion then applied to a column of Sepharose CL-6B. Radioactivity in a 0.5 ml aliquot of each 2.5 ml fraction of the eluate was counted as in Fig. 1. The position of elution of chains as indicated was established by gel filtration of appropriate unlabelled samples.
Examination
of radiolabelled
of interstitial subjected basement
types, to thermal
membrane
dialysis
collagens
gelation derived
against
species
0.02M
Na2HPO4.
to reflect
possibly
degradation
(31,32).
A pro/hyp
radioactivity
appeared
to preclude
appropriate
fraction
0.02M
the
(10)
its
phosphate
ratio
only
of the yielded
in Methods.
collagenous
from
turnover
a residue
650
the
that
front
2) were from 25% of by
failed
to
and was considered of collagen
collagenase
IV collagen.
fraction
Expt
precipitated
(16)
a peak at the
synthesis
Approx.
30% NaCl
of 1.5 following
from Type
(from
75%) of the remainder
arising
the
of interstitial
the fraction
even with
products
derivation
revealed
gelation
(about
carrier)
medium
separation
as described
Most
To confirm
in the
in the medium was in
(with
The initial
collagens
to effect
precipitate
precipitated
in the medium.
radiolabelled
the C3H ] hydroxyproline
against
RESEARCH COMMUNICATIONS
a2 1
T al(l)
Figure
AND BIdPHYSICAL
treatment
The 30% NaClon CM cellulose.
precipitated
represented
by dialysis
approximately
40%
Vol. 84, No. 3, 1978
BIOCHEMICAL
AND BIdPHYSICAL
a2
RESEARCH COMMUNICATIONS
y(m)
3A
Y
a
I
I
II
I
20 1-
I
I
0
LO
Figure
a.2
1
a FRACTICN NlJMI)ER
40
\[:1,,
,
5u
0
M
,
..i m
83
PO
,
,-
\
im 110 120 ELUIAR VOtUNT Imll
lx)
la
3. (A) CM cellulose chromatography of the radiolabelled collagens from the medium (Expt 2) precipitated by gclation at 37O: One quarter of the The eluate was counted as in Fig. I. (B) Fractions total sample was applied. dialyzed and lyophilized and 44-57 of the above chromatogram were pooled, The eluate was counted as in applied to a column of Sepharose CL-6B. The y-chains are presumed to be derived from the Type III peak Fig. 1. and the a-chains from the Type I a2 peak.
of the total
radioactivity
in
revealed
the presence
Type III
peak was of y-chain
as Type III approx
2:l
collagen
(Fig.
chains.
precipitate
only that
about
gelation
of interstitial
collagens)
radioactivity
in the
and a2-chains
with
4 suggested
a major
yielded
supernatantl amount al-chains
their
carrier in the
was found
it
found it
supernatant.
to seemed
Application over
about contained
thought
Type I
in the vicinity
90%
75% of the mostly
The al(I): is
of from
collagen,
(representing
of Type III-chains.
651
derivation
to precipitate
by CM cellulose
and must
identification
in a ratio
was subsequently
a fraction that
were
The
its
peak on C?d cellulose
Type I must remain
excess
with
technique
(which
3).
confirming
of the unlabelled
procedure
chromatography (Fig.
and a2 peaks
consistent
the gelation
a small
collagens
filtration
The al(I)
revealed
some labelled
CM cellulose
I and III
by gel
size
a half
of the modified
of about
size
of a-chain
Since
fraction.
Types
3).
The supernatant
of al(I)
likely
of both
and were
collagen.
this
reflect
U2 ratio the
al(I)
Vol. 84, No. 3, 1978
presence only
of al(I)
about
trimer.
5% of the
chromatography
The final
initial
The cells
not
only
of recognisable
used
in view appearance
as monolayers
at confluence.
character.
cells.
by the
latter
(at
and this
would
It
we observed
muscle
cells.
is not
possible
as opposed
of collagen
arising
through
chondrocytes collagen phase
synthesis later
The synthesis
(34) its
no simple producing
synthesis
arises the rate is
smooth
whether
distinction
(Type
V collagen)
chick
cornea1
epithelium
are
labelled
phase
as well has been
of interstitial
a change
for
in the
character example
a similar
with
pattern
of
"endothelial"
cells
cells
in culture
of epithelial
type
(IV and V) and the fibroblast
interstitial
collagens
shown to synthesize
as Type shown
of contaminating
in the early
between
collagens
have been
cells
collagens
synthesis
by endothelial
can be drawn
cells
by endothelial
(3).
collagens
producing
We find
(33).
with
of C3H]proline
of phenotypic
as can occur
all)
of our cultures
represents
of loss
cells
the cells
of interstitial
chains
collageens
not in
interstitial
the
from
interstitial
a low percentage
whether
as a result
'fibroblastic'
muscle
from
at present
muscle
is
in
remained
much (if
than
that
also
they
of incorporation
much lower
endothelial
but
by contamination
of the cells,
or smooth
forms
in culture
be derived
basement-membrane
differentiated
Similarly
cells
the possibility
to state
contained
on CM cellulose
employed
that
could
gelation
entirely
demonstrate
our hands)
sub-culturing (19)
or the
implies
of isolation
to basement-membrane-related
pattern
considered
Our studies
seem to preclude
levels
were
since
this
second
and revealed
importantly
by these
in
the
3) and most
In any event, least
after
U-chains.
study
method
We do not consider muscle
smooth
(see
synthesized
smooth
at the
in this
of the
morphological
of the collagen
supernatant
c311 lhydroxyproline
an absence
DISCUSSION: nature
BIOCHEMICAL AND BI~PHYSICAL RESEARCH COMMUNICATIONS
I and
III
to synthesize
652
(I,
II
and III).
a[ Aland
collagens interstitial
(24)
and
a[ B] -
whilst collagen
embryonic (35).
Vol. 84, No. 3, 1978
BIOCHEMICAL
AND BIdPHYSICAL
RESEARCH COMMUNICATIONS
References
1. 2. 3. 4. 5. 6. 7. 8. 9. 10. Il. 12. 13. 14. 15. 16. 17. 1%. 19.
20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35.
Howard, B.V., Macarak, E.J., Gunson, D. and Kefalides, N.A. (1976). Proc. Natl. Acad. Sci. U.S.A. 73, 2361-2364. Jaffe, E.A., Minick, C.R., Adelman, B., Becker, C.G. and Nachman, R. (1976). J. Exp. Med. 144, 209-225. Levene, C.I. and Heslop, J. (1977). J. Mol. Med. 2, 145-151. L., Remberger, K., Fietzek, P.P. and Kuhn, K. (1975). Gay, S., Balleisen, Klin. Wschr. 5, 899-902. McCullagh, K.A. and Balian, G. (1975). Nature, Lond. 258, 73-75. Ross, R. and Glomset, J.A. (1976). New Engl. J. Med. 295, 369-377, 420-425. Jaffe, E-A., Nachman, R.L., Becker, C.G. and Minick, C.R. (1973). J. Clin. Invest. 52, 2745-2756. Leake, D.S. and Bowyer, D.E. (1977). Prog. Biochem. Pharmacol. 13, 78-83. Barnes, Y.J., Morton, L.F. and Levene, C.I. (1976). Biochem. Biophys. Res. Commun. z, 339-347. Trelstad, R.L. and Lawley, K.R. (1977). Biocham. Biophys. Res. Commun. E, 376-383. Barnes, M.J., Constable, B.J., Morton, L.F. and Kodicek, E. (1971). Biochem. J. 125, 433-437. hi. and Schneir, hf. (1973). Analyt. Benya, P., Berger, K., Golditch, Biochem. 53, 313-316. Kefalides, N.A. (1973). Int. Rev. Connect. Tiss. Res. 6, 63-104. Trelstad, R.L. (1974). Biochem. Biophys. Res. Commun. 51, 717-725 Daniels, J.R. and Chu, G.H. (1975). J. Biol. Chem. 250, 3531-3537 Dixit, S.N. (1978). FEBS. Lett, 85, 153-157. Timpl, R., Martin, G-R., Bruckner, P., Wick, G. and Wiedemann, H. (1978). Europ. J. Biochem. 84, 43-52. E.J. (1976). Biochem. Biophys . Res. Chung, E., Rhodes, R.K. and Miller, Commun. 7& 1167-1174. Mayne, R., Vail, M.S. and Miller, E.J. (1975). Proc. Natl. Acad. Sci. U.S.A. 72, 4511-4515. Narayanan, A.S. and Page, R.C. (1976). J. Biol. Chem. 251, 5464-5471. Jimenez, S.A., Bashey, R.I., Benditt, M. and Yankowski, R. (1977). Biochgm. Biophys. Res. Commun. 78, 1354-1361. Moro, L. and Smith, B.D. (1977). Arch. Biochem Biophys. 182, 33-41. Munksgaard, E.C., Rhodes, M., Mayne, R. and Butter, W.T. (1978). Europ. J. Biochem. E, 609-617. Mayne, R., Vail, M.S. and Miller, E.J. (1978). Biochemistry E, 446-452. Bailey, A.J., Duance, V.C., Sims, T.J. and Beard, H. (1978). Front. Matrix. Biology 1, (in press). Glanville, R.W. and Kuhn, K. (1978). Front. Matrix Biology 1, (in press). Miller, E.J., Rhodes, R.K., Gay, S. and Kresina, T.F. (1978)Front.Mntr.Biol. 7 (in press). Schwartz, D. and Veis, A. (1978). FEBS Lett. 85, 326-332. Burgeson, R.E., Adli, F.A.E., Kaitila, 1.X. and Hollister, D. N. (1976). Proc. Natl. Acad. Sci. U.S.A. 73, 2579-2583. Duance, V.C., Restall, D.J., Beard, H., Bourne, F.J. and Bailey, A.J. (1977). FEBS Lett. 2, 248-252. Bates, C.J., Bailey, A.J., Prynne, C.J. and Levene, C.I. (1972). Biochim. Biophys. Acta 278, 372-390. Steinberg, J. (1973). J. Cell. Sci. 12, 217-234. Mayne, R., Vail, M.S., Miller, E.J., Blose, S.H. and Chacko, S. (1977). Arch. Biochem. Biophys. 181, 462-469. Ham, A.W. (1969). Histology 6th Edn. pp. 169-190, Pitman Medical Pub. Co. Ltd. London. Linsenmayer, T.F., Smith, G.N. and Hay, E.D. (1976). Proc. Natl. Acad. Sci. U.S.A. 74, 39-43.
653
BIOCHEMICAL
RESEARCH COMMUNICATIONS
16, 1978
SYNTHESIS
OF
Pages
INTERSTITIAL M.J.
Medical
AND BIdPHYSICAL
Research University
Received
Barnes,
14,
BY PIG
L.F.
Council, Cambridge,
of
August
COLLAGENS
Morton
Connective Tennis
AORTIC and
ENDOTHELIAL
C.I.
646-653
CELLS
IN
CULTURE
Levene
Tissue Team, Department Court Road, Cambridge,
of U.K.
Pathology,
1978
SUMMARY: Examination of the collagens synthesized by pig aortic endothelial min culture and precipitated from either the cell layer or medium, following pepsin digestion, demonstrated that the major species was Type I together with some Type III collagen and al (I) trimer. Additional chains in the cell layer chromatographing with Type I al-chains on CM cellulose may be partly derived from basement-membrane-associated collagen but in the medium would appear to be entirely derived from al (I) trimer. These results imply that the endothelial cell may secrete the Type III collagen located in the immediate subendothelial space and, in part at least, the Types I and III occurring in diffusely thickened intima and the atherosclerotic plaque. Endothelial described of
the
offers
cells
as
of
basement
first
synthesize,
permit
collagen
that
endothelial Types
definitive
the has
space I and
diffusely
III
in
primarily
the
this
have
cell
medial
wall been
(authors'
Collagen the
cultured
may
and
detected
by
smooth
muscle
I and
at
has cell
Type
immediate least
data)
sites
can III>.
the
chemical
been
been
derivation
cells
the
(or
has
communication
secrete in
these
the
(Types
unpublished at
with
endothelial
type
(4)
that
This
collagens
vessel
intima
(5).
accord
immunohistochemically
that
human
in
(1,2,3)
endothelium.
that
that
blood
collagens
from
the
interstitial
located
plaque
from
evidence the
been
collagen
(1,2)
inference
thickened
atherosclerotic originate
synthesize
membrane
additionally,
findings
culture
basement-membrane-type
vascular the
in
in
III sub-
part)
analysis and
Gur
in
considered
the in
the to
(6).
MATERIALS AND METHODS: Culture of endothelial cells Endothelial cells were obtained as before (3) from pig aorta by the method of Jaffe et al (7) as modified Endothelial cells so isolated and then subcultured 5-6 by Leake and Bowyer (8). times in 199 medium containing 20% foetal calf serum (FCS), were kindly provided by the latter authors. For the purposes of the present investigation, cells were grown in 60 mm Falcon dishes at an initial density of 50,000 in 4 ml of Dulbecco and Vogt's modification of Eagle's bIEM containing 10% FCS. Medium was exchanged for fresh every three days. After six days, ascorbic acid (50 u,g/ml) was added to the medium. At specified days, indicated later, medium was replaced with fresh containing either L- [G-3H] proline or L- [4,5-3H ]lysine (generally 0.5 mCi/dish) and ascorbic acid (50ug/ml). After 24h, plates were either 0006-291x/78/0843-0646$01.00/0
Copyright 0 1978 by Academic Press, Inc. All rights of reproduction in any form reserved.
646
Vol. 84, No. 3, 1978
BIOCHEMICAL
AND BIdPHYSICAL
RESEARCH COMMUNICATIONS
harvested or a further supplement of ascorbic acid was given. In the latter case dishes were harvested 24h later. Radiolabelled collagens in the cell layer and medium were examined as described below. Examination of cell layer collagens Digestion of cell layers, dispersed in 0.5M acetic acid, with pepsin, precipitation of the digest at 0.9M NaCl and the separation of precipitated collagens by differential salt precipitation, all in the presence of carrier were undertaken as before (9). Fractions precipitating at I, 1.71, 2.1 and 2.56M NaCl were collected and examined by CM cellulose chromatography. Examination of collagens in the medium The medium following dialysis was digested with pepsin as described previously (9). The digest was dialysed against 0.41 Na phosphate buffer, pH 7.6. After addition of carrier collagen (prepared by precipitation of a pepsin digest of pig aorta by dialysis against 0.02M Na2HP04) at approx 3mg/ml, collagens in the digest were precipitated by dialysis against 0.02M phosphate. The precipitate was redissolved in the 0.41 buffer and then incubated overnight at 37O (IO) to effect the thermal gelation of interstitial collagens. The gel was centrifuged for 30 min at 10,000 g at 25O. The residue (containing interstitial collagens) and supernatant were examined by CM cellulose chromatography. A portion of the supernatant was subjected to a second gelation by means of a modification of the above procedure (Dr. J. Rauterberg, unpublished data). The sample after addition of carrier collagen at approx 3 mg/ml was diluted to 0.21 , incubated at 37O for 6h and then dialyzed at 20° against IO vol H 0 overnight. The precipitate was collected by centrifugation as above. CM cellu f ose chromatography was exactly as before (9). Radioactivity in the eluate was measured as before (II) except that PCS (Amersham/Searle Corp.) diluted 2:1 (v/v) with xylene, was used as scintillant. Gel chromatography was undertaken with a column (140 x 1.5cm) of Sepharose CL-6B; conditions were otherwise as before (9). Radioactivity in the eluate was measured as above. Collagenase digestion Samples of the cell layer, after dispersal (IO), or medium or fractions derived therefrom were dialysed against 0.05M tris-HCl, pH7.g (at 25O) containing O.OiM Ca acetate and 0.02% Na azide, denatured at 100 for 5 min, and then redialyzed. Collagenase (Worthington's CLSPA purified and treated as described by Benya et al (12))was added at 20 units/ml. Samples were incubated for 6h at 370, then dialyzed against water and the diffusate in each case lyophilized prior to hydrolysis. Hydrolysis Samples were heated in 6N HCl in sealed tubes at 1080 for 24h. Hydrolysates were dried in vacua in a dessicator over cont. H2S04 in the presence of NaOH pellets. Measurement of lysine and hydroxylysine radioactivity in hydrolysates was as before (II). Measurement of proline and hydroxyproline radioactivity in hydrolysates.proline and hydroxyproline were separated on a Technicon Amino Acid Autoanalyzer at 60° using the standard citrate buffer, pH 2.9. Radioactivity in the eluate was counted as above. RESULTS:
In initial
studies
collagenase-susceptible the period
indicated
the % conversion
material
of lysine
in cultures
labelled
to hydroxylysine [ 3 H] lysine
with
in during
was as follows:-
Expt.
I;
5-7d:
Cell
layer,
19; Medium,
Expt.
2; 6-7d:
Cell
layer,
5; Medium,
Since
basement-membrane
(Type
24. 44.
IV) collagen
647
IO-12d:
Cell
layer,
26; Medium,
23.
12-13d:
Cell
layer,
15; Medium,
52.
exhibits
values
of about
80% (13-17)
BIOCHEMICAL
Vol. 84, No. 3, 1978
the
figures
above
This
was
C3~]
proline-labelled
taken
by
a more
confirmed
Examination
was
in
pro/hyp
that
collagenase was
upon (of
than In
one Expt.
activity as
salt
collagens
2:i
and
the
in
Na2
HP04
there The
obtained
not a ratio
obviously appreciably
material
was
the % distribution collagens
pepsin
collagenous
certainly,was
This
the
(18).
respectively)
(where
of
separate
remainder,
unprecipitated
collagen
lo-lad),
two in
Of
0.02M 4:l
the and,
fractionation
synthesized
In
NaCl.
against
(13-17)).
from
collagens.
hydroxyproline
O.QM
dialysis
anticipated
1 (labelled
following
of
examined
total
precipitated
no
further.
radio-
at
O.QM
NaCl
was
follows:-
II,! ppt,
4; In
1.71~
and
al:a2:
ratio al(I)
known
1)
revealed
al
(I)
and
of
5 in
region,
usually
16;
with
(Fig.
fraction
the
ppt,
accord
cellulose
at
with
to
precipitate
have
been
shown Expt.
M ppt,
the a2
2.56
a higher Type
generally
III
collagen
from
Type
I in
the
2.56M
indicated
presence
either
molarity
than
(24))
or
an of
perhaps
vicinity
of
Q-lld),
the
in
NaCl
of (al) (19-23)
IV
the
1.711 The
chains
in
trimer
(which
collagen a-chains
(I)
chains
% distribution
CM
but
and al
21.
fraction.
I
Type
(25-27)
on
excess
Type
2.56M
2M NaCl the
- soluble,
chromatography
Type
in
from
2.56M
of
around
chromatograph
2 (labelled
I
34;
presence
fraction the
M ppt,
bebaviour,
chains
latter
normal
to
25;
precipitation
suggesting
known
In
2.1
the
precipitates
coprecipitate
as
be
interstitial
layer
["II]
at
IV)
the
cell
total
material (Type
might
the
suggested
under-hydroxylated
basement-membrane-related less
in
approx
treatment
of
below.
precipitated
ratio
of
described
the
RESEARCH COMMUNICATIONS
synthesis
analysis
of
precipitation
following moiety
as
two-thirds
radioactivity
the
collagens
material
negligible
indicate
detailed
radio-labelled approx.
digest
to
cultures
of
experiments,
was
were
AND BidPHYSICAL
can which
from
in is
which
(13).
of
radioactivity
2.56
M-soluble,
was
follows:-
1M PPt,
9;
In
instance
this
cellulose
1.71
M ppt, , most
chromatography
17;
2.1
M ppt,
of
the
radioactivity
again
54;
indicated
2.56
4;
precipitated the
648
M ppt,
presence
at of
Type
2.lM III
part
NaCl. collagen
16. CM:
Vol. 84, No. 3, 1978
BIOCHEMICAL
0
Figure
10
the
1.7iM
located The
M
I 70
60
in
al(I)
elevated
al:a2
suggesting
rather was
a single since
close
be
in
Type
gel a-chain
the
in
was
CM cellulose
of
of
and
the
the
position
The of
precipitated
the 2.561
al
al-peak
revealed
21,
Type
pro/hyp
Type
IV
radioactivity
fraction
revealed (not
I,
a
perhaps to
(I)-chains
after
2).
was
attributable
However peaks.
(Fig.
a2-peak
(Fig.
were
was
I collagen The
greater
al(I)
these
that
Type
However,
size
ppt.
radioactivity
noted,
(14-17,281.
in
material
again again
regionof
all
fraction,
filtration.
I trimer
unity
represents
nature
pro/hyp
trimer. the
on
of
5)
2.lM
I).
is
only
shown)
and
considered
al(I)-trimer. The
The
to
peak this
chains
the
indicative
by
peaks
than
In
(approx. size
with
2.56M
shown).
regions
ratio
excess
collagen
~2
a-chain
pattern
ratio
(not and
of
complex
1.71M ppt.
fraction
essentially
to
M 40 FRACTION NUMBER
RESEARCH COMMUNICATIONS
1. Endothelial cells in culture: CM cellulose chromatography of the precipitates at 1.71 and 2.561 NaCl obtained in the fractionation of radiolabelled cell layer collagens isolated after pepsin treatment (Expt. Badioactivityina 0.5 ml aliquot of each 10 ml fraction of the eluate was counted in 10 ml of scintillant at 30% efficiency. The position of marker chains aa indicated was established by chromatography of appropriate unlabelled collagens. The results relate to the cell layers pooled from three plates, each labelled with 0.3 mCi[L G-3H] proline from lo-12d.
-----------
in
al
AND BIdPHYSICAL
of
derived
collagenous
radioactivity However
front
the
and from
ratio
Cbl cellulose failed
Type
material
to
reveal
V collagen
of
1.4
soluble
was
compatible
chromatography either which
al could
(18,24.29,30).
649
at
with
exhibited (I)
chains
also
in
2.56M
only or
theory
USA! occur
NaCl its
is
uncertain.
identity
a single and in
as peak
~1: Bl this
al at
chains fraction
(I)
Vol. 84, No. 3, 1978
BIOCHEMICAL
2.(A) CR cellulose chromatography of the precipitate at 2.1M NaCl obtained in the fractionation of radiolabelled cell layer collagens isolated after pepsin treatment (Expt. 2). Radioactivity in a 0.5 ml aliquot of each 10 ml fraction of the eluate was counted in 5 ml of scintillant (in polypropylene inserts) at 20% efficiency. The results relate to the cell layers pooled from six plates, each labelled with 0.5 mCi L [G3H] proline from g-lid; one third of the total sample was chromatographed. (B) Gel filtration of al(I) chains: Fractions 22-31 of the above chromatogram were pooled, dialyzed against 0.15M acetic acid, lyophilized and a portion then applied to a column of Sepharose CL-6B. Radioactivity in a 0.5 ml aliquot of each 2.5 ml fraction of the eluate was counted as in Fig. 1. The position of elution of chains as indicated was established by gel filtration of appropriate unlabelled samples.
Examination
of radiolabelled
of interstitial subjected basement
types, to thermal
membrane
dialysis
collagens
gelation derived
against
species
0.02M
Na2HPO4.
to reflect
possibly
degradation
(31,32).
A pro/hyp
radioactivity
appeared
to preclude
appropriate
fraction
0.02M
the
(10)
its
phosphate
ratio
only
of the yielded
in Methods.
collagenous
from
turnover
a residue
650
the
that
front
2) were from 25% of by
failed
to
and was considered of collagen
collagenase
IV collagen.
fraction
Expt
precipitated
(16)
a peak at the
synthesis
Approx.
30% NaCl
of 1.5 following
from Type
(from
75%) of the remainder
arising
the
of interstitial
the fraction
even with
products
derivation
revealed
gelation
(about
carrier)
medium
separation
as described
Most
To confirm
in the
in the medium was in
(with
The initial
collagens
to effect
precipitate
precipitated
in the medium.
radiolabelled
the C3H ] hydroxyproline
against
RESEARCH COMMUNICATIONS
a2 1
T al(l)
Figure
AND BIdPHYSICAL
treatment
The 30% NaClon CM cellulose.
precipitated
represented
by dialysis
approximately
40%
Vol. 84, No. 3, 1978
BIOCHEMICAL
AND BIdPHYSICAL
a2
RESEARCH COMMUNICATIONS
y(m)
3A
Y
a
I
I
II
I
20 1-
I
I
0
LO
Figure
a.2
1
a FRACTICN NlJMI)ER
40
\[:1,,
,
5u
0
M
,
..i m
83
PO
,
,-
\
im 110 120 ELUIAR VOtUNT Imll
lx)
la
3. (A) CM cellulose chromatography of the radiolabelled collagens from the medium (Expt 2) precipitated by gclation at 37O: One quarter of the The eluate was counted as in Fig. I. (B) Fractions total sample was applied. dialyzed and lyophilized and 44-57 of the above chromatogram were pooled, The eluate was counted as in applied to a column of Sepharose CL-6B. The y-chains are presumed to be derived from the Type III peak Fig. 1. and the a-chains from the Type I a2 peak.
of the total
radioactivity
in
revealed
the presence
Type III
peak was of y-chain
as Type III approx
2:l
collagen
(Fig.
chains.
precipitate
only that
about
gelation
of interstitial
collagens)
radioactivity
in the
and a2-chains
with
4 suggested
a major
yielded
supernatantl amount al-chains
their
carrier in the
was found
it
found it
supernatant.
to seemed
Application over
about contained
thought
Type I
in the vicinity
90%
75% of the mostly
The al(I): is
of from
collagen,
(representing
of Type III-chains.
651
derivation
to precipitate
by CM cellulose
and must
identification
in a ratio
was subsequently
a fraction that
were
The
its
peak on C?d cellulose
Type I must remain
excess
with
technique
(which
3).
confirming
of the unlabelled
procedure
chromatography (Fig.
and a2 peaks
consistent
the gelation
a small
collagens
filtration
The al(I)
revealed
some labelled
CM cellulose
I and III
by gel
size
a half
of the modified
of about
size
of a-chain
Since
fraction.
Types
3).
The supernatant
of al(I)
likely
of both
and were
collagen.
this
reflect
U2 ratio the
al(I)
Vol. 84, No. 3, 1978
presence only
of al(I)
about
trimer.
5% of the
chromatography
The final
initial
The cells
not
only
of recognisable
used
in view appearance
as monolayers
at confluence.
character.
cells.
by the
latter
(at
and this
would
It
we observed
muscle
cells.
is not
possible
as opposed
of collagen
arising
through
chondrocytes collagen phase
synthesis later
The synthesis
(34) its
no simple producing
synthesis
arises the rate is
smooth
whether
distinction
(Type
V collagen)
chick
cornea1
epithelium
are
labelled
phase
as well has been
of interstitial
a change
for
in the
character example
a similar
with
pattern
of
"endothelial"
cells
cells
in culture
of epithelial
type
(IV and V) and the fibroblast
interstitial
collagens
shown to synthesize
as Type shown
of contaminating
in the early
between
collagens
have been
cells
collagens
synthesis
by endothelial
can be drawn
cells
by endothelial
(3).
collagens
producing
We find
(33).
with
of C3H]proline
of phenotypic
as can occur
all)
of our cultures
represents
of loss
cells
the cells
of interstitial
chains
collageens
not in
interstitial
the
from
interstitial
a low percentage
whether
as a result
'fibroblastic'
muscle
from
at present
muscle
is
in
remained
much (if
than
that
also
they
of incorporation
much lower
endothelial
but
by contamination
of the cells,
or smooth
forms
in culture
be derived
basement-membrane
differentiated
Similarly
cells
the possibility
to state
contained
on CM cellulose
employed
that
could
gelation
entirely
demonstrate
our hands)
sub-culturing (19)
or the
implies
of isolation
to basement-membrane-related
pattern
considered
Our studies
seem to preclude
levels
were
since
this
second
and revealed
importantly
by these
in
the
3) and most
In any event, least
after
U-chains.
study
method
We do not consider muscle
smooth
(see
synthesized
smooth
at the
in this
of the
morphological
of the collagen
supernatant
c311 lhydroxyproline
an absence
DISCUSSION: nature
BIOCHEMICAL AND BI~PHYSICAL RESEARCH COMMUNICATIONS
I and
III
to synthesize
652
(I,
II
and III).
a[ Aland
collagens interstitial
(24)
and
a[ B] -
whilst collagen
embryonic (35).
Vol. 84, No. 3, 1978
BIOCHEMICAL
AND BIdPHYSICAL
RESEARCH COMMUNICATIONS
References
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20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35.
Howard, B.V., Macarak, E.J., Gunson, D. and Kefalides, N.A. (1976). Proc. Natl. Acad. Sci. U.S.A. 73, 2361-2364. Jaffe, E.A., Minick, C.R., Adelman, B., Becker, C.G. and Nachman, R. (1976). J. Exp. Med. 144, 209-225. Levene, C.I. and Heslop, J. (1977). J. Mol. Med. 2, 145-151. L., Remberger, K., Fietzek, P.P. and Kuhn, K. (1975). Gay, S., Balleisen, Klin. Wschr. 5, 899-902. McCullagh, K.A. and Balian, G. (1975). Nature, Lond. 258, 73-75. Ross, R. and Glomset, J.A. (1976). New Engl. J. Med. 295, 369-377, 420-425. Jaffe, E-A., Nachman, R.L., Becker, C.G. and Minick, C.R. (1973). J. Clin. Invest. 52, 2745-2756. Leake, D.S. and Bowyer, D.E. (1977). Prog. Biochem. Pharmacol. 13, 78-83. Barnes, Y.J., Morton, L.F. and Levene, C.I. (1976). Biochem. Biophys. Res. Commun. z, 339-347. Trelstad, R.L. and Lawley, K.R. (1977). Biocham. Biophys. Res. Commun. E, 376-383. Barnes, M.J., Constable, B.J., Morton, L.F. and Kodicek, E. (1971). Biochem. J. 125, 433-437. hi. and Schneir, hf. (1973). Analyt. Benya, P., Berger, K., Golditch, Biochem. 53, 313-316. Kefalides, N.A. (1973). Int. Rev. Connect. Tiss. Res. 6, 63-104. Trelstad, R.L. (1974). Biochem. Biophys. Res. Commun. 51, 717-725 Daniels, J.R. and Chu, G.H. (1975). J. Biol. Chem. 250, 3531-3537 Dixit, S.N. (1978). FEBS. Lett, 85, 153-157. Timpl, R., Martin, G-R., Bruckner, P., Wick, G. and Wiedemann, H. (1978). Europ. J. Biochem. 84, 43-52. E.J. (1976). Biochem. Biophys . Res. Chung, E., Rhodes, R.K. and Miller, Commun. 7& 1167-1174. Mayne, R., Vail, M.S. and Miller, E.J. (1975). Proc. Natl. Acad. Sci. U.S.A. 72, 4511-4515. Narayanan, A.S. and Page, R.C. (1976). J. Biol. Chem. 251, 5464-5471. Jimenez, S.A., Bashey, R.I., Benditt, M. and Yankowski, R. (1977). Biochgm. Biophys. Res. Commun. 78, 1354-1361. Moro, L. and Smith, B.D. (1977). Arch. Biochem Biophys. 182, 33-41. Munksgaard, E.C., Rhodes, M., Mayne, R. and Butter, W.T. (1978). Europ. J. Biochem. E, 609-617. Mayne, R., Vail, M.S. and Miller, E.J. (1978). Biochemistry E, 446-452. Bailey, A.J., Duance, V.C., Sims, T.J. and Beard, H. (1978). Front. Matrix. Biology 1, (in press). Glanville, R.W. and Kuhn, K. (1978). Front. Matrix Biology 1, (in press). Miller, E.J., Rhodes, R.K., Gay, S. and Kresina, T.F. (1978)Front.Mntr.Biol. 7 (in press). Schwartz, D. and Veis, A. (1978). FEBS Lett. 85, 326-332. Burgeson, R.E., Adli, F.A.E., Kaitila, 1.X. and Hollister, D. N. (1976). Proc. Natl. Acad. Sci. U.S.A. 73, 2579-2583. Duance, V.C., Restall, D.J., Beard, H., Bourne, F.J. and Bailey, A.J. (1977). FEBS Lett. 2, 248-252. Bates, C.J., Bailey, A.J., Prynne, C.J. and Levene, C.I. (1972). Biochim. Biophys. Acta 278, 372-390. Steinberg, J. (1973). J. Cell. Sci. 12, 217-234. Mayne, R., Vail, M.S., Miller, E.J., Blose, S.H. and Chacko, S. (1977). Arch. Biochem. Biophys. 181, 462-469. Ham, A.W. (1969). Histology 6th Edn. pp. 169-190, Pitman Medical Pub. Co. Ltd. London. Linsenmayer, T.F., Smith, G.N. and Hay, E.D. (1976). Proc. Natl. Acad. Sci. U.S.A. 74, 39-43.
653