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The biochemical and functional heterogeneity of circulating human plasma fibronectin
Vol. 119, No. 3, 1984
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
March 30, 1984
Pages 1174-1180
THE BIOCHEMICAL AND FUNCTIONAL HETEROGENEITY OF CIRCULATING HUMAN PLASMA FIBRONECTIN B. J. Dept.
Boughton
and A. W. Simpson
of Haematology, Birmingham
University B15 2TI-I
of Birmingham U.K.
Received February 15, 1984 Human plasma fibronectin purified by affinity chromatography, consisted of homogeneous 215 kD protein subunits when assessed by On isoelectric focusing SDS polyacrylamide gel electrophoresis. however, 5 separate fractions were present, with isoelectric points ranging from 5.6 to 6.1. Isoelectric focusing and similar but not immunofixation of native plasma produced identical appearances. Only 15% of the total plasma fibronectin cerevisiae opsonically stimulated the ingestion of Saccharomyces and this opsonic fibronectin by human peripheral blood monocytes, was confined to the fraction with an isoelectric point of 6.1.
When
purified
by
fibronectin
appears
examined
to
(1).
proteins
doing
and in
locomotion
(2).
fibrinogen
and for coagulation
bacteria
(3,4).
and are phagocytosed
opsonic
however,
This
presence
same protein
(3).
isoelectric
function
heterogeneity
not
to
0
1984
focusing
demonstrate
previously
by Academic Press, Inc.. in any form reserved.
of reproduction
affinity
to
in
sites
wound
debris
in
functional
and an assay
this
on macrophages
heterogeneity
following
and
lipotechoic
opsonized
a biochemical
1174
roles
bacterial
and
collagen,
of cell
functional
described.
for
to
of different
0006-291X/84 $1.50 Copyright All rights
adhesion
receptor
In the
ultra-
morphology,
opsonization
wide
two-
cytoskeletal
and micro-organisms
(7).
(PAGE),
cellular
its
binds
when
analytical
points
fibronectin
by the
utilized
cell
fibronectin
specific
been explained
with
micro-organisms
A (5,6)
to
the
interacts
plasma
protein,
electrophoresis or
and in the
human
homogeneous
gel
so modifies
Thus,
and Protein
way adhere
It
In addition
healing,
have
be a single
immunoelectrophoresis
centrifugation
within
chromatography,
by SDS polyacrylamide
dimensional
acid
affinity
has
domains
experiments of
the
protein's
and functional
we
BIOCHEMICAL
Vol. 119, No. 3, 1984
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
MATERIALS AND METHODS Human Plaa anticoagulated
was obtained by centrifugation of with l/10 vol. trisodium citrate.
fresh
whole
blood
Fibronectin was purified in the presence of 5mM benzamidine under non-denaturing conditions using gelatin-Sepharose and arginineSepharose as previously described (1). For some experiments fibronectin was purified using a polyclonal antifibronectin antibody linked to Sepharose (8). Fibronectin concentrations were measurer! phoresis as previously described (9).
by
immunoelectro-
SDS polyacryla,mide gel electrophoresis (PAGE) was performed in 6.5% gels using 1 mg/ml protein reduced with 10% B mercaptoethanol -1% SDS. MW markers were obtained from Pharmacia and the protein bands were stained with PAGE Blue 90. Isoelectric focusing of purified protein was performed in 5% polyacrylamide gels containing 2.4 ol (w/v) Ampholine (LKB Instruments) giving a pH range 3.5 to ‘b.5. The gels were prefocused for 20 mins. and 10 ul protein (400 mg l-') was applied 1 cm from the cathode. This was then focused for 1% hrs. at 10 'C using 1.5 kv and 1 watt/cm gel. The gels were then fixed with 10% trichloracetic acid/5% sulphosalicylic acid and stained with PAGE Blue 83. Human and bovine carbonic anhydrase B and R lactoglobulin A were used as markers - pH 6.6, 5.8 and 5.2 respectively. Isoelectric focusing of plasma 1% agarose containing 6.3% Pharmalyte (Pharmacia Ltd.) 12% sorbitol and 3% polyethylene was prefocused for 20 mins., and 20 ~1 samples of plasma glycol, diluted 1:lO in distilled water were applied 1 cm from the cathode and focused for 1% hour at 10 'C using 1.5 Kv and 0.5 watts/cm gel. Gels were immunifixed with an undiluted polyclonal sheep antihuman fibronectin antibody (Immunodiagnostics Research Laboratory, Birmingham University) for 16 hours at 22 'C washed for 24 hours in 0.9 NaCl, dried and stained with Page Blue 83. Opsonic activity of plasma or purified fibronectin was assayed a previously described (10). 0.5 ~1 were used to opsonize 5 x 10 8 Saccharomyces cerevisiae for 2 hr. at 37 OC. The opsonized yeast were washed twgice in Hank's Balanced Salt Solution (HBSS) and added to 5 x 10 human peripheral blood monocytes in 1:l (v/v) RPMI-1640/HBSS. After f hr. at 37 'C. phagocytosed yeast were counted using an electronic particle size analyser. RESULTS Figure
(1)
purified
freshly
t
homogeneous as assessed
300 and 400 mgl-'
ingestion
(Mean
the
fibronectin
containing the
shows
215 kD protein by SDS-PAGE.
fibronectin
In
comparison,
purified
fibronectin
identical opsonized
Native
respectively
of 0.35 + 0.07 and 0.52 +_ 0.04 yeasts
1 SEM).
subunits
plasma
stimulated per monocyte
concentrations 0.32
of
+ 0.12
and 0.50
of 2
Vol. 119, No. 3, 1984
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
"=:L*
18
36 60 67
Figure
(1) SDS PAGE of two samples of 1 Gl-1 plasma fibronectin, The left gelatin-Sepharose and arginine-Sepharose. shows markers with molecular weights in kD.
0.02 yeasts
per
different
to
significant
loss
purification
of
of
was not
examine
the
shows purified Saccharomyces opsonic
with
protein's
during opsonic
opsonization, activity
fibronectin
activity
a
the
curing
wide
number of yeast 85% of
with
and after 1176
12-
only
opsonization of adsorbed protein
binding
sites
protein
were
conducted
to
protein.
Table
(1)
4 successive
aliquots
of
The concentration before
that
the
experiments
adsorbed
its
of
range
no
following
percentage
of unadsorbed
cerevisiae.
indicating
activity
was aosorhed
Since
factor.
significantly
(2) shows however
over that
not
plasma,
The relative
fixed
indicating
are
opsonic
Figure
cerevisiae.
a limiting
unadsorbed
the
plasma.
remained
concentrations
obtained
plasma fibronectin
Saccharomyces
protein
its
those
from
15% of native
These results
monocyte.
purified on hand track
each
of
fibronectin
adsorption
was
and stage,
BIOCHEMICAL
Vol. 119, No. 3, 1984
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
-'
0
30
60 MINUTES
Figure
(2)
that
unable
In did
plasma
function
after
b .nd
to
inert.
of
180
150
INCUBATION
Human plasma containing 60-450 mgl-l fibronectln opsonize Saccharomyces cerevisiae (see text). Only fibronectin was adsorbed by yeast during 0-180 min. 37 ‘C regardless of the concentration of protein point is the mean of 2 determinations.
indicate
stages
120
90
45OmglL
to
yeast,
and
contrast,
the
stimulate
ingestion
fibronectin as
measured
83% of
2 adsorptions, that
protein of
this
therefore
is the
The
major
to
have
first
two
proportion no
opsonic
(1) 1
2
3
4
330 330
330 330
FIBRONE-E TIN mgl
BEFORE AFTER
400 350
350 330
OPSONIC ACTIVITY %
BEFORE AFTER
100 48
48 6
6 2
2 1
the opsonic activity of purified consecutive, 0.5 hr. adsorptions The initial opsonic activity (0.5 denoted as 100%. Fibronectin at of yeasts retalned 100% opsonic
1177
is
opsonically
system.
Table
Gbronectin concentration and fibronectin before and after 4 with Saccharomyces cerevisiae. yeasts ingested per monocyte) is 37 ‘C for 2 hrs. in the absence activity.
protein
during
yeasts.
assay
initial
protein
adsorbed
appears by
this
the
was used to 12-15X of the incubation at used. Each
Vol. 119, No. 3, 1984
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
5.2
d
c b
1
03
2
3
Figure
Figure
a
0
6.6
4
4
1
Plasma fibronectin purified on gelatin Sepharose and arginine was isoelectrically focused on polyacrylamide. Sepharose, (1) shows that the purified protein contained 5 major bands with isoelectric points 5.66to 6.1. (2) yfd (3) show 0.5 ml protein adsorbed with 5 x 10 and 5 x 10 Saccharomyces cervisiae respectively. The band at pH 6.1 is selectively adsorbed. The position of marker proteins is indicated by the pH value of each.
(3)
(4)
Isoelectric
focusing
of
native
plasma
on
15
agarose.
fibronectin free plasma (2) and (3) plasma from The position of marker proteins is shown individuals. 8.15 (b) 7.35 (c) 6.05 (d) 6.55 and (e) 5.85.
Figure after
(3)
isoelectric
purified very
shows
appearances
focusing
similar
points
from
5.6 to 6.1.
by Saccharomyces adsorbed
this
preferentially. of
fibronectin
Five
procedure, Figure
cerevisiae,
freshly
at
purified
(a)
gel.
separate with
Proteins
(3) also the Figure
can also 1178
of
shows that
fraction (4)
gave
fractions
a range
shows
are
isoelectric when adsorbed
with
a p1 of that
be distinguished
pH
protein
and antifibronectin-Sepharose,
appearances. by
of
on polyacrylapl3e
on gelatin-Sepharose
distinguished
fractions
the
(1)
2 normal
6.1 is
separate in
native
BIOCHEMICAL
Vol. 119, No. 3, 1984
plasma. than
The pH of
those
of
the
the
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
isoelectric
purified
points
protein.
showed no immuno-reactivity
in this
were
however
Fibronectin
free
higher plasma
preparation.
DISCUSSION Cell
membrane
their
solubility
towards
is
molecular
purification
of
proteolysis
(13).
presence
of proteolytic
fragments
have not
correspond
to
detected
in
for
molecular
the
different
this
study
charge
isoelectric
unknown
and
the
purified
protein
using
of circulating
protein
weight,
raises
a number
of
produced
by a wide
in
possible
that
different
tissues.
may have VIII
different
specific
and Clq
plasma
Secondly,
and may thus
variety
fibronectins
with have 1179
capable
and do not
The reasons
separate actin,
separate
for
the
presently
plasma
and
separate
distinction of
of
proteolytic
are
of
or
subfractions
the
forms
between
similar
questions.
these
interactions
also
fractions
fractions
important
molecular
plasma
native
the
stimulate
weight
and the
and non-opsonic
plasma
responsible
these
fibronectin
low
Such
The finding
unclear.
in-vitro
in
focusing.
between
opsonic
fibronectin
(15).
differences
differences
plasma
and are
isoelectric
of
chemical
when
fibronectin
molecular
migration
are also
seen
in circulating
homogeneous
by to
Various
division
been detected
the
(1).
(8,14)
cell
and the
chromatography
plasma
phagocytosis
fibroblast
not
affinity
of
protein,
attributed is
inhibitors
fragments
monocyte
stimulating
by
fibronectin
obtained
been
picture
purified
proteolytic
inhibit
has
This
is
as a homogeneous
by
reactivity
Plasma
fibronectins
plasma
fibronectin
and by their
(11,12).
regarded weight
can be distinguished
weights
antibodies
generally
of
weight
fibronectins
and molecular
monoclonal
however range
and plasma
molecular
First,
since
of cell
types,
it
are
derived
plasma
functions.
from
fibronectins
fibrinogen,
is
factor Thirdly,
Vol.
119,
No.
there
is
3, 1984
good
BIOCHEMICAL
evidence
fixed
macrophage
clear
circulating
vascular
the
humans
however,
fibronectin syndrome
there
levels (18).
proportion
of
fibronectins
(16).
and Since
the
total
may now
pathophysiology
of
a poor
the opsonic
consumptive
direct
correlation of
a more
patients
effects
on
loss
and
(17).
In
new
total
with
comprises
detailed
to
lung
hctween
protein,
failure
fluid as the
fibronectin
plasma permit
such
survival
produces
subsequent
possible
organs
COMMUNICATIONS
depletion
transvascular
vital
is
The
or
increases of
RESEARCH
f'ibronectin
microemboli,
function
BIOPHYSICAL
plasma
dysfunction
endothelium
impairs
that
AND
assays
plasma
shock only of
examination
lung
a minor separate of
the
opsoninopathy.
ACKNOWLEDGEMENT B. J.
Boughton
is
a Leukaemia
Research
Fund
Senior
Lecturer.
REFERENCES
(1) Vuento, Yamada, Mosesson, 13’; (41 Kuusela, i5j (6) (7) (8) (9) (10) (11) (12) (13) (14) (15) (16) (17) (18)
M., Vaheri, A. (1979) Bioch. J. 183 331-337. X. M., Olden, K. (1979) Nature 275, 179-184. M. W., Amrani, D. L. (1980) Blood 56(2) 145-158. P. (1978) Nature 276, 718-720. Courtney, H. S., Simpson, W. A., Beachey, E. H. (1982) J. Bact. 153(2) 763-770. Doran, J. E., Raynor, R. H. (1981) Infect. Imm. 33(3) 683689. Bevilacqua, M. P., Amrani, D., Mosesson, M.W., Bianco, L. (1981) J. Exp. Med. 153, 42-60. Czop, J. Ii., Austen, K. F. (1982) J. Imm. 129(6) 2678-2681. Boughton, B. J., Simpson, A. W., Chandler, S. (1983) Lancet (1) 121-122. Simpson, A. W., Boughton, B. J. (1983) Imm. Methods 63, 321-327. Proctor, R. A., Mosher, D. F., Olbrantz, P. J. (1982) J. Biol. Chem. 257(24) 14788-14794. Atherton, B. T., Hynes, R. 0. (1981) Cell 25(l) 133-141. Mosesson, M. W. (1978) Ann. N.Y. Acad. Sci. 312, 11-30. Ehrlich, M, I., Krushell, J. S., Blumenstock, F. A., Kaplan, J. (1981) J. Lab. Clin. Med. 98(2), 263-271. Humphries, M. J., Sobhy, R. A. (1983) Nature 305; 811-813. Saba, T. M.Blumenstock, F. A., Weber, P., Kaplan, J. E. (1978) Ann. N.Y. Acad. Sci. 312, 43-55. Niehaus, G. D., Schumaker, P. T., Saba T. M.,(1980) J. Appl. Physiol. 49(4) 693-699. Rubli, E., Bussard, S., Frei, E. Lundgerard Hansen P., Pappova, E. (1983) Ann. Surg. 197, 310-317.
1180
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
March 30, 1984
Pages 1174-1180
THE BIOCHEMICAL AND FUNCTIONAL HETEROGENEITY OF CIRCULATING HUMAN PLASMA FIBRONECTIN B. J. Dept.
Boughton
and A. W. Simpson
of Haematology, Birmingham
University B15 2TI-I
of Birmingham U.K.
Received February 15, 1984 Human plasma fibronectin purified by affinity chromatography, consisted of homogeneous 215 kD protein subunits when assessed by On isoelectric focusing SDS polyacrylamide gel electrophoresis. however, 5 separate fractions were present, with isoelectric points ranging from 5.6 to 6.1. Isoelectric focusing and similar but not immunofixation of native plasma produced identical appearances. Only 15% of the total plasma fibronectin cerevisiae opsonically stimulated the ingestion of Saccharomyces and this opsonic fibronectin by human peripheral blood monocytes, was confined to the fraction with an isoelectric point of 6.1.
When
purified
by
fibronectin
appears
examined
to
(1).
proteins
doing
and in
locomotion
(2).
fibrinogen
and for coagulation
bacteria
(3,4).
and are phagocytosed
opsonic
however,
This
presence
same protein
(3).
isoelectric
function
heterogeneity
not
to
0
1984
focusing
demonstrate
previously
by Academic Press, Inc.. in any form reserved.
of reproduction
affinity
to
in
sites
wound
debris
in
functional
and an assay
this
on macrophages
heterogeneity
following
and
lipotechoic
opsonized
a biochemical
1174
roles
bacterial
and
collagen,
of cell
functional
described.
for
to
of different
0006-291X/84 $1.50 Copyright All rights
adhesion
receptor
In the
ultra-
morphology,
opsonization
wide
two-
cytoskeletal
and micro-organisms
(7).
(PAGE),
cellular
its
binds
when
analytical
points
fibronectin
by the
utilized
cell
fibronectin
specific
been explained
with
micro-organisms
A (5,6)
to
the
interacts
plasma
protein,
electrophoresis or
and in the
human
homogeneous
gel
so modifies
Thus,
and Protein
way adhere
It
In addition
healing,
have
be a single
immunoelectrophoresis
centrifugation
within
chromatography,
by SDS polyacrylamide
dimensional
acid
affinity
has
domains
experiments of
the
protein's
and functional
we
BIOCHEMICAL
Vol. 119, No. 3, 1984
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
MATERIALS AND METHODS Human Plaa anticoagulated
was obtained by centrifugation of with l/10 vol. trisodium citrate.
fresh
whole
blood
Fibronectin was purified in the presence of 5mM benzamidine under non-denaturing conditions using gelatin-Sepharose and arginineSepharose as previously described (1). For some experiments fibronectin was purified using a polyclonal antifibronectin antibody linked to Sepharose (8). Fibronectin concentrations were measurer! phoresis as previously described (9).
by
immunoelectro-
SDS polyacryla,mide gel electrophoresis (PAGE) was performed in 6.5% gels using 1 mg/ml protein reduced with 10% B mercaptoethanol -1% SDS. MW markers were obtained from Pharmacia and the protein bands were stained with PAGE Blue 90. Isoelectric focusing of purified protein was performed in 5% polyacrylamide gels containing 2.4 ol (w/v) Ampholine (LKB Instruments) giving a pH range 3.5 to ‘b.5. The gels were prefocused for 20 mins. and 10 ul protein (400 mg l-') was applied 1 cm from the cathode. This was then focused for 1% hrs. at 10 'C using 1.5 kv and 1 watt/cm gel. The gels were then fixed with 10% trichloracetic acid/5% sulphosalicylic acid and stained with PAGE Blue 83. Human and bovine carbonic anhydrase B and R lactoglobulin A were used as markers - pH 6.6, 5.8 and 5.2 respectively. Isoelectric focusing of plasma 1% agarose containing 6.3% Pharmalyte (Pharmacia Ltd.) 12% sorbitol and 3% polyethylene was prefocused for 20 mins., and 20 ~1 samples of plasma glycol, diluted 1:lO in distilled water were applied 1 cm from the cathode and focused for 1% hour at 10 'C using 1.5 Kv and 0.5 watts/cm gel. Gels were immunifixed with an undiluted polyclonal sheep antihuman fibronectin antibody (Immunodiagnostics Research Laboratory, Birmingham University) for 16 hours at 22 'C washed for 24 hours in 0.9 NaCl, dried and stained with Page Blue 83. Opsonic activity of plasma or purified fibronectin was assayed a previously described (10). 0.5 ~1 were used to opsonize 5 x 10 8 Saccharomyces cerevisiae for 2 hr. at 37 OC. The opsonized yeast were washed twgice in Hank's Balanced Salt Solution (HBSS) and added to 5 x 10 human peripheral blood monocytes in 1:l (v/v) RPMI-1640/HBSS. After f hr. at 37 'C. phagocytosed yeast were counted using an electronic particle size analyser. RESULTS Figure
(1)
purified
freshly
t
homogeneous as assessed
300 and 400 mgl-'
ingestion
(Mean
the
fibronectin
containing the
shows
215 kD protein by SDS-PAGE.
fibronectin
In
comparison,
purified
fibronectin
identical opsonized
Native
respectively
of 0.35 + 0.07 and 0.52 +_ 0.04 yeasts
1 SEM).
subunits
plasma
stimulated per monocyte
concentrations 0.32
of
+ 0.12
and 0.50
of 2
Vol. 119, No. 3, 1984
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
"=:L*
18
36 60 67
Figure
(1) SDS PAGE of two samples of 1 Gl-1 plasma fibronectin, The left gelatin-Sepharose and arginine-Sepharose. shows markers with molecular weights in kD.
0.02 yeasts
per
different
to
significant
loss
purification
of
of
was not
examine
the
shows purified Saccharomyces opsonic
with
protein's
during opsonic
opsonization, activity
fibronectin
activity
a
the
curing
wide
number of yeast 85% of
with
and after 1176
12-
only
opsonization of adsorbed protein
binding
sites
protein
were
conducted
to
protein.
Table
(1)
4 successive
aliquots
of
The concentration before
that
the
experiments
adsorbed
its
of
range
no
following
percentage
of unadsorbed
cerevisiae.
indicating
activity
was aosorhed
Since
factor.
significantly
(2) shows however
over that
not
plasma,
The relative
fixed
indicating
are
opsonic
Figure
cerevisiae.
a limiting
unadsorbed
the
plasma.
remained
concentrations
obtained
plasma fibronectin
Saccharomyces
protein
its
those
from
15% of native
These results
monocyte.
purified on hand track
each
of
fibronectin
adsorption
was
and stage,
BIOCHEMICAL
Vol. 119, No. 3, 1984
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
-'
0
30
60 MINUTES
Figure
(2)
that
unable
In did
plasma
function
after
b .nd
to
inert.
of
180
150
INCUBATION
Human plasma containing 60-450 mgl-l fibronectln opsonize Saccharomyces cerevisiae (see text). Only fibronectin was adsorbed by yeast during 0-180 min. 37 ‘C regardless of the concentration of protein point is the mean of 2 determinations.
indicate
stages
120
90
45OmglL
to
yeast,
and
contrast,
the
stimulate
ingestion
fibronectin as
measured
83% of
2 adsorptions, that
protein of
this
therefore
is the
The
major
to
have
first
two
proportion no
opsonic
(1) 1
2
3
4
330 330
330 330
FIBRONE-E TIN mgl
BEFORE AFTER
400 350
350 330
OPSONIC ACTIVITY %
BEFORE AFTER
100 48
48 6
6 2
2 1
the opsonic activity of purified consecutive, 0.5 hr. adsorptions The initial opsonic activity (0.5 denoted as 100%. Fibronectin at of yeasts retalned 100% opsonic
1177
is
opsonically
system.
Table
Gbronectin concentration and fibronectin before and after 4 with Saccharomyces cerevisiae. yeasts ingested per monocyte) is 37 ‘C for 2 hrs. in the absence activity.
protein
during
yeasts.
assay
initial
protein
adsorbed
appears by
this
the
was used to 12-15X of the incubation at used. Each
Vol. 119, No. 3, 1984
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
5.2
d
c b
1
03
2
3
Figure
Figure
a
0
6.6
4
4
1
Plasma fibronectin purified on gelatin Sepharose and arginine was isoelectrically focused on polyacrylamide. Sepharose, (1) shows that the purified protein contained 5 major bands with isoelectric points 5.66to 6.1. (2) yfd (3) show 0.5 ml protein adsorbed with 5 x 10 and 5 x 10 Saccharomyces cervisiae respectively. The band at pH 6.1 is selectively adsorbed. The position of marker proteins is indicated by the pH value of each.
(3)
(4)
Isoelectric
focusing
of
native
plasma
on
15
agarose.
fibronectin free plasma (2) and (3) plasma from The position of marker proteins is shown individuals. 8.15 (b) 7.35 (c) 6.05 (d) 6.55 and (e) 5.85.
Figure after
(3)
isoelectric
purified very
shows
appearances
focusing
similar
points
from
5.6 to 6.1.
by Saccharomyces adsorbed
this
preferentially. of
fibronectin
Five
procedure, Figure
cerevisiae,
freshly
at
purified
(a)
gel.
separate with
Proteins
(3) also the Figure
can also 1178
of
shows that
fraction (4)
gave
fractions
a range
shows
are
isoelectric when adsorbed
with
a p1 of that
be distinguished
pH
protein
and antifibronectin-Sepharose,
appearances. by
of
on polyacrylapl3e
on gelatin-Sepharose
distinguished
fractions
the
(1)
2 normal
6.1 is
separate in
native
BIOCHEMICAL
Vol. 119, No. 3, 1984
plasma. than
The pH of
those
of
the
the
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
isoelectric
purified
points
protein.
showed no immuno-reactivity
in this
were
however
Fibronectin
free
higher plasma
preparation.
DISCUSSION Cell
membrane
their
solubility
towards
is
molecular
purification
of
proteolysis
(13).
presence
of proteolytic
fragments
have not
correspond
to
detected
in
for
molecular
the
different
this
study
charge
isoelectric
unknown
and
the
purified
protein
using
of circulating
protein
weight,
raises
a number
of
produced
by a wide
in
possible
that
different
tissues.
may have VIII
different
specific
and Clq
plasma
Secondly,
and may thus
variety
fibronectins
with have 1179
capable
and do not
The reasons
separate actin,
separate
for
the
presently
plasma
and
separate
distinction of
of
proteolytic
are
of
or
subfractions
the
forms
between
similar
questions.
these
interactions
also
fractions
fractions
important
molecular
plasma
native
the
stimulate
weight
and the
and non-opsonic
plasma
responsible
these
fibronectin
low
Such
The finding
unclear.
in-vitro
in
focusing.
between
opsonic
fibronectin
(15).
differences
differences
plasma
and are
isoelectric
of
chemical
when
fibronectin
molecular
migration
are also
seen
in circulating
homogeneous
by to
Various
division
been detected
the
(1).
(8,14)
cell
and the
chromatography
plasma
phagocytosis
fibroblast
not
affinity
of
protein,
attributed is
inhibitors
fragments
monocyte
stimulating
by
fibronectin
obtained
been
picture
purified
proteolytic
inhibit
has
This
is
as a homogeneous
by
reactivity
Plasma
fibronectins
plasma
fibronectin
and by their
(11,12).
regarded weight
can be distinguished
weights
antibodies
generally
of
weight
fibronectins
and molecular
monoclonal
however range
and plasma
molecular
First,
since
of cell
types,
it
are
derived
plasma
functions.
from
fibronectins
fibrinogen,
is
factor Thirdly,
Vol.
119,
No.
there
is
3, 1984
good
BIOCHEMICAL
evidence
fixed
macrophage
clear
circulating
vascular
the
humans
however,
fibronectin syndrome
there
levels (18).
proportion
of
fibronectins
(16).
and Since
the
total
may now
pathophysiology
of
a poor
the opsonic
consumptive
direct
correlation of
a more
patients
effects
on
loss
and
(17).
In
new
total
with
comprises
detailed
to
lung
hctween
protein,
failure
fluid as the
fibronectin
plasma permit
such
survival
produces
subsequent
possible
organs
COMMUNICATIONS
depletion
transvascular
vital
is
The
or
increases of
RESEARCH
f'ibronectin
microemboli,
function
BIOPHYSICAL
plasma
dysfunction
endothelium
impairs
that
AND
assays
plasma
shock only of
examination
lung
a minor separate of
the
opsoninopathy.
ACKNOWLEDGEMENT B. J.
Boughton
is
a Leukaemia
Research
Fund
Senior
Lecturer.
REFERENCES
(1) Vuento, Yamada, Mosesson, 13’; (41 Kuusela, i5j (6) (7) (8) (9) (10) (11) (12) (13) (14) (15) (16) (17) (18)
M., Vaheri, A. (1979) Bioch. J. 183 331-337. X. M., Olden, K. (1979) Nature 275, 179-184. M. W., Amrani, D. L. (1980) Blood 56(2) 145-158. P. (1978) Nature 276, 718-720. Courtney, H. S., Simpson, W. A., Beachey, E. H. (1982) J. Bact. 153(2) 763-770. Doran, J. E., Raynor, R. H. (1981) Infect. Imm. 33(3) 683689. Bevilacqua, M. P., Amrani, D., Mosesson, M.W., Bianco, L. (1981) J. Exp. Med. 153, 42-60. Czop, J. Ii., Austen, K. F. (1982) J. Imm. 129(6) 2678-2681. Boughton, B. J., Simpson, A. W., Chandler, S. (1983) Lancet (1) 121-122. Simpson, A. W., Boughton, B. J. (1983) Imm. Methods 63, 321-327. Proctor, R. A., Mosher, D. F., Olbrantz, P. J. (1982) J. Biol. Chem. 257(24) 14788-14794. Atherton, B. T., Hynes, R. 0. (1981) Cell 25(l) 133-141. Mosesson, M. W. (1978) Ann. N.Y. Acad. Sci. 312, 11-30. Ehrlich, M, I., Krushell, J. S., Blumenstock, F. A., Kaplan, J. (1981) J. Lab. Clin. Med. 98(2), 263-271. Humphries, M. J., Sobhy, R. A. (1983) Nature 305; 811-813. Saba, T. M.Blumenstock, F. A., Weber, P., Kaplan, J. E. (1978) Ann. N.Y. Acad. Sci. 312, 43-55. Niehaus, G. D., Schumaker, P. T., Saba T. M.,(1980) J. Appl. Physiol. 49(4) 693-699. Rubli, E., Bussard, S., Frei, E. Lundgerard Hansen P., Pappova, E. (1983) Ann. Surg. 197, 310-317.
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