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Ferritin is increased in diethylnitrosamine - altered rat hepatocytes
BIOCHEMICAL
Vol. 99, No. 3,1981 April
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages 879-865
15, 1981
FERRITIN
IS
Carole
INCREASED
IN
Beaumont,
Elisabeth
Marie-France
Unit6
DIETHYLNITROSAMINE
Latinier,
de Recherches
January
Bourel
Hkpatologiques,
RAT
Christiane
Rumeur*,
Michel
35011
Received
Le
- ALTERED
INSERM
and
Guillouzo, Guillouzo
And&
49,
U
HEPATOCYTES
H6pital
de Pontchaillou,
- France
RENNES
14,1981
Summary : Ferritin was localized by immunoperoxidase in rat liver during the early stages of experimental carcinogenesis induced by diethylnitrosamine. Carcinogen - altered hepatocytes, identified by their reduction in membranebound ATPase activity, showed a highly elevated content in ferritin (or ferritin subunits), compared to normal hepatocytes. This could correspond to an accumulation of free subunits in the cytoplasm or to a “non-specific” increase in ferritin synthesis related to the carcinogenic process. Our results suggest that some cytoplasmic proteins other than enzymes can be modified during the early stages of carcinogenesis and that ferritin accumulation detedted by immunolocalization can be used as a valuable marker to identify foci of cellular alterations. Introduction variety
A
of cellular
before
cinogens
hepatocellular
tic
nodules
are
and
several
enzyme
for
the
their
two
has
lesions
are resistant
in
storaye could
the
*
during Supported
Abbreviations
this
by the
(6,
the
“Ligue
normal 9)
which
observations stages
we performed stages
of
neoplas-
heterogeneity all
has
been
shown
FranGaise
diethylnitrosamine ; SDS, PAP, peroxidase - antiperoxidase HEPES, N-2 Hydroxyethylpiperazine
it
sodium
an
in-
iron-
ferritin
synthesis In
order in rat
by diethylnitrosamine. le cancer”. dodecyl
sulfate
-N’-2-ethanesulfonic 0006-291
879
in
cellular
of ferritin
induced
the
with
has been well results
the major
contre
that
hand,
that
in
hepatocellular
is overloaded
immunolocalization
: DENA,
2)
markers
liver
suggest
(1,
valuable
4).
hepatocytes is
and
of hepatocarcinogenesis.
carcinogenesis
Nationale
it the
car-
chemical
described as
identifies
On the other
(8,
early
used
(3,
which
when
7).
foci
phenotypic
procedure,
into
ferritin
different
hypothesis,
the first
this
incorporation
during
cells
accumulation
by
precisely
been
have been
a new marker
With
of
These
modified
to verify liver
synthesis
protein. be
(51,
to iron iron
have
liver
Altered
considerable
display
administration that
that
reactions
developped.
dietary
demonstrated crease
may
properties been
lesions
in rat
develop.
carcinogen-altered
of
lesions by
carcinomas of
cells
these
enzymatic
iron
types
are produced
histochemical
identification
Since
lesions
;
acid
X/81/070879-07$01.00/0
Cop.vrigh/ G I981 by Academic Press, Inc. Ail righ/s of reproduction in any form reserved.
Vol.
99, No.
Material
3,198l
and
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
methods
Material
tial tube,
after trols.
Young adult female Sprague-Dawley hepatectomy, the rats received 24h, 48h and 72h later. Fifteen DENA treatment and 5 female
Immunological
rats were used. After two-third parthree doses of DENA (25 mg/kg) by stomach rats were sacrified at 3 and 6 months rats of the same strain were used as con-
methods.
Ferritin was prepared from normal rat liver using the method of Drysdale et al. (10). The purity of the preparation was checked by SDS-polyacrylamide gel electrophoresis. Specific antiserum was raised in rabbits and purified by affinity chromatography on ferritin-CNDr Sepharose (Pharmacia, Uppsala, Sseden) column. Purified antibodies and normal rabbit immunoglobulins were coupled to peroxidase according to the two step procedure described by Avrameas and Ternynck (11). Sheep anti-rabbit y-globulin antiserum was obtained from>lTInstitut Pasteur, Paris and peroxidase-anti-peroxidase complexes from Miles Yeda Ltd, Rehovot, Israel. fixation-
Tissue
Fixation of liver was performed as previously described (12) with the following modifications: before fixation, rat livers were washed by perfusion via the portal vein with Hepes buffer for 30 sec. then cut into fragments and immersed in 10 % paraformaldehyde buffered with 0.1 M phosphate for 6-8h at 4OC. The samples were washed several times in phosphate buffer and soaked in 10% glycerol in phosphate buffer before freezing in liquid nitrogen-cooled isopentane. Eight-micron thick serial sections were performed for histochemical and immunoperoxidase reactions.
Histochemical
Bile Wachstein
staining
of
canaliculi-membrane and Meisel method
were performed or ATP in the inhibitor.
(13)
for lh at 37’C. incubation medium
Immunolocalization
of
ATPase
activity
bound ATPase activity was revealed by the using sodium ATP as a substrate. Incuba$$ons Controls were obtained with omission of Mg or with 10 mM p-chloromercuric benzoate as an
ferritin
Liver two different
cryostat sections were processed for immunoperoxidase staining by methods a) by the PAP method first using anti-ferritin antibodies then anti-rabbit y-globulin and finally peroxidase anti-peroxidase complexes according to Stenberger et al. (14) ; bl by the direct technique using peroxidase-labelled rabbit anti-ferritin antibodies. Peroxidase activity was demonstrated by the technique of Graham and Karnovsky (15). Control reactions included : a) incubation peroxidase labelled normal antiserum ; b) with c) with normal rabbit serum then with anti-rabbit peroxidase-anti-peroxidase complexes.
with ferritin-absorbed rabbit rabbit immunoglobulins ; y-globulin and finally with
BIOCHEMICAL
Vol. 99, No. 3,198l
The early similar
morpholoqical
to those
vealed
foci
after
wing
nodules.
nique
yielded
At
the
hepatocytes
6 months,
results:
contained
by
both
(4):
PAP
Altered
appeared
and
and
small as gro-
direct
the
in DENA-treated
and
re-
formed
staining
was observed
hepatocytes,
ferritin
no
were
hepatocytes
activity
method
normal
and
COMMUNICATIONS
diethylnitrosamine
by
persisted
the
in
ferritin
RESEARCH
ATPase
lesions
the
ferritin
of
same
by others
in membrane-bound
Immunolocalization all
induced
uescribed
deficiency
3 months.
BIOPHYSICAL
alterations
previousiy
their
by
AND
tech-
rat in
livers,
Kupffer
cells.
However,
in the
consistently
higher
on serial (Fig,
carcinogen-altered than
in the surrounding
all
sections,
normal
ATPase-deficient
1) or in
nodules
(Fig.
Ferritin
and
subunits
hepatocytes.
a strong
staining
been
localized
was
As shown
located
hepatocytes
21 displayed
content either for
foci
in
ferritin.
Discussion
in cultured
and
a diffuse some
rat
A
very
munoperoxidase ment with
cells
(171
fluorescence similar
is
biochemical
if
data
any,
in our in
in
that
showed
“granules”
in
with
the Kupffer
cells
sug-
is
in agree-
cells.
This
the
iron
nodules
in
of
(16)
conditions
these
most
liver
rat
they
fluorescent
of staining ferritin
showing
(18)
with
was observed
The absence
little,
in
by immunofluorescence:
together
pattern
technique. there
that
already
have
hepatoma
cytoplasmic
cells.
gests
its
is
the im-
deposited
as
hemosiderin. The
rat
enhanced
liver
into
the
to store
iron
contrary
an early
observed. the
should
results.
shown).
ferritin thesis.
Secondly
has
into been
could the shown
occur.
completed
shell the
881
these
to
turnover
mechanism a defect
by in
the
the
content
apparently
con-
or an increa-
The latter seems excluded vesicles were seen (results
control
either
induce
in ferritin
On
ferritin
for
in-
hepatocytes content.
in intracellular
endocytotic
lead
to
to iron
reponse
in ferritin
be proposed rate
in the
a modification
in
DENA-treated
of chemically-altered
could could
no
synthesised
increase
a reduced
process
synthesis
subunits
Iron
is
in a decrease
significant
level,
neoplastic
inability
the
explanations
endocytotic
ferritin
and
have resulted
Firstly
the ultrastructural lates
cells,
foci
ferritin
As
and
Several
tradictory se in
of
was unexpected.
corporation
is
staining
which
since not iron
assembly
or to an increase in formation of apoferritin
ferritin from
at
reguof
synfree
BIOCHEMICAL
Vol. 99, No. 3,1981
Figure
AND
BIOPHYSICAL
1 : Light after
microscopy ; serial cryostat sections DENA treatment ; A) AlPase reaction ferritin by the PAP method. The focus of as compared bits a much stronger staining, hepatocytes (x 120).
882
RESEARCH
of
COMMUNICATIONS
rat liver Immunolocalization altered hepatocytes to surrounding
3 months
8)
of exhinormal
Vol. 99, No. 3,198l
Figure
2
: Light after ferritin island some
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
microscopy ; serial cryostat sections of rat liver 6 months DENA treatment ; AJ ATPase reaction U) Immunolocalization by the PAP method. The altered hepatocytes form a larqe which appears as a developping nodule ; note the presence slightly compressed surrounding hepatocytes (arrow) (X 120).
883
of of
Vol.
99, No.
subunits
3,198l
BIOCHEMICAL
dispersed
iron
in
With
the
these
throughout
altered
antibody
staining increase
the
cells
used
corresponds in ferritin
to ferritin synthesis
BIOPHYSICAL
lead study,
or not
to
stimulated
by
COMMUNICATIONS
the
of
discern
subunits
that this finding could be related to the in these hypertrophic altered cells (20). evidence
Therefore
accumulation
we cannot to
RESEARCH
(19).
cytoplasm
could
this
in
AND
unengaged
whether
or whether iron might
of
subunits.
the observed
specific" occur. We suggest
“non
high degree of ploidy which occurs this regard we have preliminary
In
albumin synthesis increases with ploidy by studying separated by counterflow centrifugation in different according to cell size. Whatever is the exact significance that
hepatocytes
tions
absence
normal rat subpopulaof this high
ferritin content of carcinogen-altered hepatocytes, our findings are the first to our knowledge, to indicate that in these cells an intracytoplasmic protein other than an enzyme is modified. Moreover all foci and nodules identified by their deficiency in ATPase activity displayed a higher ferritin Consequently ferritin accumulation could be used as a reliable marcontent. ker
detect
early
Acknowledgements
:
to
lesions
occuring
during
experimental
hepatocarcinogene-
sis.
We acknowledge
nical
We wish to assistance
Pr thank and
M.
Simon for
Mrs A. Saunier and Mrs 0. Houzelle for
This work was supported DGRST
advice.
helpful
by grants
Y. Mazurier typing
the
for their manuscript.
useful
from INSERM (ATP 82-79-114)
tech-
and from
(80-7-6016).
References 1. Merkow, L.P., Epstein, S.M., Caito, B.J., and Bartus, B. (1967) Cancer Res. 27, 1712-1721. 2. Scherer, E., and Emmelot, P. (1976) Cancer Res. 36, 2544-2554. 3. Schmitz-Moorman, Z., Gedigk, P., and Dharamadach, A. (1972) Z. Krebsforsch. 77, Y-16. 4. Farber, t. (1973) in Methods in Cancer Research (Busch, H., ed.) vol. 7, pp 345-375, Academic Press, New York. 5. Bannasch, P., Mayer, D., and Macker, H.3. (1980) Biochim. Biophys. Acta 605, 217-245. 6. Williams, G.M., and Yamamoto, R.S. (1972) 3. Natl. Cancer Inst. 49, 685692. 7. Williams, G.M. (1980) Biochim. Biophys. Acta. 605, 167-189. 8. Fineberg, R.A., and Greenberg, D.M. (1955) 3. ml. Chem. 214, 97-106. 9. Drysdale, 3.W., and Munro, H.N. (1966) 3. Biol. Chem. 241, 3630-3637. 10. Drysdale, J.W., and Munro, H.N. (1965) Biochem. 3. 95, 851-858. 11. Avrameas, S., and Ternynck, T. (1971) Immunochemistry 2, 1175-1179. 12. Guillouzo, A., Belanger, L., Beaumont, C., Valet, J.P., Briggs, R., and Chiu, 3.F. (1978) 3. Histochem. Cytochem. 3, 948-959.
884
BIOCHEMICAL
Vol. 99, No. 3,1981
13. Weichstein, 14. 15. 16.
Stenberger, 3. Histochem. Graham, R.C. 291-302. Lee, I.C.K.,
18.
Lee,
RESEARCH
COMMUNICATIONS
S.S.,
Schlesinger,
(1970) l4,
K.J.,
and
Richter,
G.W.
(1974)
Am.
K.I.,
and
Richter,
G.W.
(1975)
Am.
473-488.
Lee, I.C.K., Lee, S.S., Schlesinger, 3. Pathol. 80, 235-248. Van Wyk, C.P., Linder-Horowitz, M., 246, 1025-1031.
19.
Zshringer, 3., Baliga, Sci. USA 2, 857-861.
B.S.,
20.
Wanson, (1980)
D., Penasse, 459-471.
J.C., Cancer
BIOPHYSICAL
and Meisel, E. (1957) Am. 3. Clin. Path. 27, 13-23. M., L.A., Hardy, P.H. Jr., Cuculis, 3.3., and Meyer, H.G. Cytochem. I& 315-333. Jr., and Karnovsky, M.3. (1966) 3. Histochem. Cytochem.
3. Pathol. 2, 17.
AND
Bernaert, Res. 2,
and
and
Munro,
H.N. W.,
885
Munro,
H.N.
(1971)
Biol.
3.
(1976) Proc. Natl.
Mosselmans,
R.,
and
Chem.
Acad.
Bannasch,
P.
Vol. 99, No. 3,1981 April
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages 879-865
15, 1981
FERRITIN
IS
Carole
INCREASED
IN
Beaumont,
Elisabeth
Marie-France
Unit6
DIETHYLNITROSAMINE
Latinier,
de Recherches
January
Bourel
Hkpatologiques,
RAT
Christiane
Rumeur*,
Michel
35011
Received
Le
- ALTERED
INSERM
and
Guillouzo, Guillouzo
And&
49,
U
HEPATOCYTES
H6pital
de Pontchaillou,
- France
RENNES
14,1981
Summary : Ferritin was localized by immunoperoxidase in rat liver during the early stages of experimental carcinogenesis induced by diethylnitrosamine. Carcinogen - altered hepatocytes, identified by their reduction in membranebound ATPase activity, showed a highly elevated content in ferritin (or ferritin subunits), compared to normal hepatocytes. This could correspond to an accumulation of free subunits in the cytoplasm or to a “non-specific” increase in ferritin synthesis related to the carcinogenic process. Our results suggest that some cytoplasmic proteins other than enzymes can be modified during the early stages of carcinogenesis and that ferritin accumulation detedted by immunolocalization can be used as a valuable marker to identify foci of cellular alterations. Introduction variety
A
of cellular
before
cinogens
hepatocellular
tic
nodules
are
and
several
enzyme
for
the
their
two
has
lesions
are resistant
in
storaye could
the
*
during Supported
Abbreviations
this
by the
(6,
the
“Ligue
normal 9)
which
observations stages
we performed stages
of
neoplas-
heterogeneity all
has
been
shown
FranGaise
diethylnitrosamine ; SDS, PAP, peroxidase - antiperoxidase HEPES, N-2 Hydroxyethylpiperazine
it
sodium
an
in-
iron-
ferritin
synthesis In
order in rat
by diethylnitrosamine. le cancer”. dodecyl
sulfate
-N’-2-ethanesulfonic 0006-291
879
in
cellular
of ferritin
induced
the
with
has been well results
the major
contre
that
hand,
that
in
hepatocellular
is overloaded
immunolocalization
: DENA,
2)
markers
liver
suggest
(1,
valuable
4).
hepatocytes is
and
of hepatocarcinogenesis.
carcinogenesis
Nationale
it the
car-
chemical
described as
identifies
On the other
(8,
early
used
(3,
which
when
7).
foci
phenotypic
procedure,
into
ferritin
different
hypothesis,
the first
this
incorporation
during
cells
accumulation
by
precisely
been
have been
a new marker
With
of
These
modified
to verify liver
synthesis
protein. be
(51,
to iron iron
have
liver
Altered
considerable
display
administration that
that
reactions
developped.
dietary
demonstrated crease
may
properties been
lesions
in rat
develop.
carcinogen-altered
of
lesions by
carcinomas of
cells
these
enzymatic
iron
types
are produced
histochemical
identification
Since
lesions
;
acid
X/81/070879-07$01.00/0
Cop.vrigh/ G I981 by Academic Press, Inc. Ail righ/s of reproduction in any form reserved.
Vol.
99, No.
Material
3,198l
and
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
methods
Material
tial tube,
after trols.
Young adult female Sprague-Dawley hepatectomy, the rats received 24h, 48h and 72h later. Fifteen DENA treatment and 5 female
Immunological
rats were used. After two-third parthree doses of DENA (25 mg/kg) by stomach rats were sacrified at 3 and 6 months rats of the same strain were used as con-
methods.
Ferritin was prepared from normal rat liver using the method of Drysdale et al. (10). The purity of the preparation was checked by SDS-polyacrylamide gel electrophoresis. Specific antiserum was raised in rabbits and purified by affinity chromatography on ferritin-CNDr Sepharose (Pharmacia, Uppsala, Sseden) column. Purified antibodies and normal rabbit immunoglobulins were coupled to peroxidase according to the two step procedure described by Avrameas and Ternynck (11). Sheep anti-rabbit y-globulin antiserum was obtained from>lTInstitut Pasteur, Paris and peroxidase-anti-peroxidase complexes from Miles Yeda Ltd, Rehovot, Israel. fixation-
Tissue
Fixation of liver was performed as previously described (12) with the following modifications: before fixation, rat livers were washed by perfusion via the portal vein with Hepes buffer for 30 sec. then cut into fragments and immersed in 10 % paraformaldehyde buffered with 0.1 M phosphate for 6-8h at 4OC. The samples were washed several times in phosphate buffer and soaked in 10% glycerol in phosphate buffer before freezing in liquid nitrogen-cooled isopentane. Eight-micron thick serial sections were performed for histochemical and immunoperoxidase reactions.
Histochemical
Bile Wachstein
staining
of
canaliculi-membrane and Meisel method
were performed or ATP in the inhibitor.
(13)
for lh at 37’C. incubation medium
Immunolocalization
of
ATPase
activity
bound ATPase activity was revealed by the using sodium ATP as a substrate. Incuba$$ons Controls were obtained with omission of Mg or with 10 mM p-chloromercuric benzoate as an
ferritin
Liver two different
cryostat sections were processed for immunoperoxidase staining by methods a) by the PAP method first using anti-ferritin antibodies then anti-rabbit y-globulin and finally peroxidase anti-peroxidase complexes according to Stenberger et al. (14) ; bl by the direct technique using peroxidase-labelled rabbit anti-ferritin antibodies. Peroxidase activity was demonstrated by the technique of Graham and Karnovsky (15). Control reactions included : a) incubation peroxidase labelled normal antiserum ; b) with c) with normal rabbit serum then with anti-rabbit peroxidase-anti-peroxidase complexes.
with ferritin-absorbed rabbit rabbit immunoglobulins ; y-globulin and finally with
BIOCHEMICAL
Vol. 99, No. 3,198l
The early similar
morpholoqical
to those
vealed
foci
after
wing
nodules.
nique
yielded
At
the
hepatocytes
6 months,
results:
contained
by
both
(4):
PAP
Altered
appeared
and
and
small as gro-
direct
the
in DENA-treated
and
re-
formed
staining
was observed
hepatocytes,
ferritin
no
were
hepatocytes
activity
method
normal
and
COMMUNICATIONS
diethylnitrosamine
by
persisted
the
in
ferritin
RESEARCH
ATPase
lesions
the
ferritin
of
same
by others
in membrane-bound
Immunolocalization all
induced
uescribed
deficiency
3 months.
BIOPHYSICAL
alterations
previousiy
their
by
AND
tech-
rat in
livers,
Kupffer
cells.
However,
in the
consistently
higher
on serial (Fig,
carcinogen-altered than
in the surrounding
all
sections,
normal
ATPase-deficient
1) or in
nodules
(Fig.
Ferritin
and
subunits
hepatocytes.
a strong
staining
been
localized
was
As shown
located
hepatocytes
21 displayed
content either for
foci
in
ferritin.
Discussion
in cultured
and
a diffuse some
rat
A
very
munoperoxidase ment with
cells
(171
fluorescence similar
is
biochemical
if
data
any,
in our in
in
that
showed
“granules”
in
with
the Kupffer
cells
sug-
is
in agree-
cells.
This
the
iron
nodules
in
of
(16)
conditions
these
most
liver
rat
they
fluorescent
of staining ferritin
showing
(18)
with
was observed
The absence
little,
in
by immunofluorescence:
together
pattern
technique. there
that
already
have
hepatoma
cytoplasmic
cells.
gests
its
is
the im-
deposited
as
hemosiderin. The
rat
enhanced
liver
into
the
to store
iron
contrary
an early
observed. the
should
results.
shown).
ferritin thesis.
Secondly
has
into been
could the shown
occur.
completed
shell the
881
these
to
turnover
mechanism a defect
by in
the
the
content
apparently
con-
or an increa-
The latter seems excluded vesicles were seen (results
control
either
induce
in ferritin
On
ferritin
for
in-
hepatocytes content.
in intracellular
endocytotic
lead
to
to iron
reponse
in ferritin
be proposed rate
in the
a modification
in
DENA-treated
of chemically-altered
could could
no
synthesised
increase
a reduced
process
synthesis
subunits
Iron
is
in a decrease
significant
level,
neoplastic
inability
the
explanations
endocytotic
ferritin
and
have resulted
Firstly
the ultrastructural lates
cells,
foci
ferritin
As
and
Several
tradictory se in
of
was unexpected.
corporation
is
staining
which
since not iron
assembly
or to an increase in formation of apoferritin
ferritin from
at
reguof
synfree
BIOCHEMICAL
Vol. 99, No. 3,1981
Figure
AND
BIOPHYSICAL
1 : Light after
microscopy ; serial cryostat sections DENA treatment ; A) AlPase reaction ferritin by the PAP method. The focus of as compared bits a much stronger staining, hepatocytes (x 120).
882
RESEARCH
of
COMMUNICATIONS
rat liver Immunolocalization altered hepatocytes to surrounding
3 months
8)
of exhinormal
Vol. 99, No. 3,198l
Figure
2
: Light after ferritin island some
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
microscopy ; serial cryostat sections of rat liver 6 months DENA treatment ; AJ ATPase reaction U) Immunolocalization by the PAP method. The altered hepatocytes form a larqe which appears as a developping nodule ; note the presence slightly compressed surrounding hepatocytes (arrow) (X 120).
883
of of
Vol.
99, No.
subunits
3,198l
BIOCHEMICAL
dispersed
iron
in
With
the
these
throughout
altered
antibody
staining increase
the
cells
used
corresponds in ferritin
to ferritin synthesis
BIOPHYSICAL
lead study,
or not
to
stimulated
by
COMMUNICATIONS
the
of
discern
subunits
that this finding could be related to the in these hypertrophic altered cells (20). evidence
Therefore
accumulation
we cannot to
RESEARCH
(19).
cytoplasm
could
this
in
AND
unengaged
whether
or whether iron might
of
subunits.
the observed
specific" occur. We suggest
“non
high degree of ploidy which occurs this regard we have preliminary
In
albumin synthesis increases with ploidy by studying separated by counterflow centrifugation in different according to cell size. Whatever is the exact significance that
hepatocytes
tions
absence
normal rat subpopulaof this high
ferritin content of carcinogen-altered hepatocytes, our findings are the first to our knowledge, to indicate that in these cells an intracytoplasmic protein other than an enzyme is modified. Moreover all foci and nodules identified by their deficiency in ATPase activity displayed a higher ferritin Consequently ferritin accumulation could be used as a reliable marcontent. ker
detect
early
Acknowledgements
:
to
lesions
occuring
during
experimental
hepatocarcinogene-
sis.
We acknowledge
nical
We wish to assistance
Pr thank and
M.
Simon for
Mrs A. Saunier and Mrs 0. Houzelle for
This work was supported DGRST
advice.
helpful
by grants
Y. Mazurier typing
the
for their manuscript.
useful
from INSERM (ATP 82-79-114)
tech-
and from
(80-7-6016).
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