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The presence of multiple intrinsic membrane nickel-containing hydrogenases in Desulfovibrio vulgaris (hildenborough)
Vol. 139, No. 2, 1986
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
September 16, 1986
Pages 70]-708
THE PRESENCE OF MULTIPLE I N T R I N S I C MEMBRANE NICKEL-CONTAINING HYDROGENASES IN DESULFOVIBRIO VULGARIS (HILDENBOROUGH)
Thierry
Lissolo,
Eui
S.
Choi,
Jean
LeGall
and
Harry
D.
Peck,
Jr.
School of Chemical Sciences Department of Biochemistry University of Georgia Athens, Georgia 30602
Received July 30, 1986
Three intrinsic membrane proteins exhibiting oxygen stable hydrogenase activity have been isolated f r o m 2- 2 ~ ! g a r i s . In contrast to the periplasmtc exclusively non-heme iron hydrogenase, all three hydrogenases contain Ni i n a d d i t i o n to non-heme iron, have low s p e c i f i c activities and a r e i n s e n s i t i v e to inhibition by CO. None o f t h e t h r e e hydrogenases cross react w i t h IgA a g a i n s t the periplasmic hydrogenase o f D. v u l g a r i s b u t t w o o f t h e new hydrogenases cross react w i t h IgA a g a i n s t the periplasmic nickel containing hydrogenase o f D. g ! g a s a n d t h e o t h e r new h y d r o g e n a s e cross reacts w i t h IgA a g a i n s t the periplasmic nickel and s e l e n i u m
hydrogenase
Three been
of D. d e s u l f u r i c a n s
soluble
isolated
reducing
and
belonging
exclusively
from
D.
iron
hydrogenase
~!g~E!~
baculatus hydrogenase
Desulfovibrio established
the
[(NiFe)
D.
the
iron
activities
have
(12,13);
been
however,
these
D.
gigas
and
the
not
within been
represent
Abbreviations: BV, B e n z y l v i o l o g e n ; SDS, s o d i u m a n d PAGE, p o l y a c r y l a m i d e gel electrophoresis.
701
sulfate
hydrogenase] non-heme
(3,4,5);
and
the
[(NiFeSe)
closely and
have
the
[(Fe)
hydrogenase
reported
activities
of
containing
(8,9,10,11)
has
hydrogenase
Desulfovibrio:
from
(6),
it
of
species
nickel
selenium
associated
forms
hydrogenase
periplasmic
iron
© 1986AcademicPress, Inco
different
genus
desulfuricans
Membrane
whether
from
hydrogenase]
non-heme
from (7).
to
--4).
molecular
non-heme
(1,2);
containing
hydrogenase]
stable
characterized
bacteria
periplasmlc
nickel
oxygen
(Norway
related
multiple
a single
D.
soluble
species
of
conclusively distinct dodecyl
molecular sulfate;
0006-291X/86 $1.50 Copyr~ht © 1986 ~ Academ~ Pre~, Inc. A# r~h~ ~ r~roduction in a ~ ~ r m reservel
VoI. 139, No. 2,1986
forms
of
hydrogenase
hydrogenase In
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
with
this
other
in
are
artifacts
we
report
hydrogenases
addition
due
to
the
association
of
proteins.
communication,
nickel-containing vu!garis
or
to
the
in well
the
the
presence
membrane
characterized
of
three
fraction periplasmtc
of
D. (Fe)
hydrogenase. METHODS Assays
and
PreRarations
D. v u l g a K ~ s (NCIB 8303) was grown on lactate-sulfate medium and extracts prepared as previously described (14). Hydrogen uptake and evolution activities were assayed spectrophotometrically (15) and protein was determined by a modified Lowry method (16). Native polyacrylamide gel electrophorests employed 5~ slab gels containing 0.1~ Triton X-100 (17) and hydrogenase activities were visualized by staining with BV ( 0 . 5 mM) a n d 2 , 3 , 5 - t r l p h e n y l tetrazoltum chloride (1 mM). S l a b g e l SDS e l e c t r o p h o r e s i s was carried out and the reactivities of hydrogenases wi£h polyclonal antibodies raised against purified hydrogenases f r o m D. f f ~ f f a s ( 3 ) , D. v u l g a E ! s (2) and D. d e s u l f u r t c a n s (Norway 4) (6) were analyzed by the enzyme-linked immuno electrotransfer blot technique (18) using horse radish peroxtdase-conjugated second antibody (19). Fe, Nt and Se were determined by plasma emission spectroscopy using a Jarrell Ash model 750 atomcomp. For the inhibition o f H2 u p t a k e activity by C0, the concentration o f CO w a s v a r i e d by the addition o f CO a n d H 2 saturated buffer solutions. Purification
of
membrane-bound
h~drogenases
The crude extract was centrifuged at 100,000 xg to obtain the membrane fraction which was extracted with 1~ Triton (X-114) containing 1 5 0 mM NaC1 a n d 10 mM t r i s - H C 1 , pH 7 . 4 (20,21). After incubation a t O°C f o r 2 h o u r s , the suspension was centrifuged for 20 m i n . a t 1 2 , 0 0 0 xg to remove cell debris and the clear supernate was incubated at 30°C for 5 min. to allow for precipitation of the detergent which was removed by centrifugation at 12,000 xg for 20 min. 28°C. The lower detergent phase was collected and redlssolved in the same buffer without Triton (X-114) by incubation at 0°C. The phase separation was repeated and the washed detergent phase was diluted 10x with a solution of Triton (X-100) plus 5 mM t r i s - H C l pH7.8, to give a final concentration o f 1~ T r i t o n (X-100). The protein was loaded onto a DEAE-Bio-Gel column (4.5 x 29 cm), the column washed with a liter of 0.01M Tris - HC1, and the hydrogenases eluted with a tris-HCl linear gradient (one liter each of 0.01M and 0.40 M tris-HC1). The elution profile is shown in Figure 1, u p p e r graph. The hydrogenase fractions were pooled, and applied to a hydroxyapatite (Bio-Rad) column ( 3 x 15 c m ) , a n d t h e proteins eluted by a linear phosphate gradient ( 5 0 0 ml e a c h o f 0 . 0 2 M and 0.30 M potassium phosphate buffer). As s h o w n i n F i g u r e 1, lower graph, the first peak of hydrogenase activity contained two different hydrogenases when analyzed by gel electrophoresis and activity staining. The third hydrogenase was well separated from the other two hydrogenase activities. All procedures were carried out in air at 4°C and all buffers were adjusted t o pH 7 . 8 a n d c o n t a i n e d 0.1~ Triton X-IO0. 702
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 139, No. 2 , 1 9 8 6
£ 2 -4 ;O
Z 0.4
O m
I--
"4
Iu
0.2
/" 100
.
' 150 FRACTION
2
i
c v
>" 1
t,,m
20 22 24 26 28 30 0.4
pig
t~ 0.2
Fig.
1.
z
,.(
i
!
25
O
50 75 FRACTION
Chromatography of m e m b r a n e ( U p p e r ) and h y d r o x y a p a t i t e
100
bound hydrogenases (Lower)
on
DEAE-BioGel
The d e t e r g e n t - r i c h phase containing membrane bound hydrogenases was l o a d e d o n t o a D E A - B i o G e l c o l u m n a f t e r 10X d i l u t i o n w i t h T r i t o n X - 1 0 0 ( f i n a l conc. 1~) and the p r o t e i n s were eluted with a linear 0.01-0.40 M tris-HCl gradient (Upper) . The h y d r o g e n a s e fractions from DEA-BioGel a p p l i e d to a h y d r o x y a p a t i t e c o l u m n and the eluted with a linear 0.02-0.30M potassium (Lower). The f r a c t i o n s of the f i r s t p e a k gel e l e c t r o p h o r e s i s and a c t i v i t y s t a i n i n g
were pooled, proteins were phosphate gradient w e r e a n a l y z e d by (inset).
RESULTS AND D I S C U S S I O N
Cell-free the to
high
preparations
specific
contaminate
activities.
all
was
(Fe)
and
(Fe)
hydrogenase
by
activity
Our
hydrogenase
(NiFe)
CO w h i l e
the
of
cell first
perlplasmic fractions
evidence
obtained
as
for
As
mask
the CO a s shown
anticipated,
membrane-bound
(Fe)
and
employing
hydrogenases. is,
vu!g~[!~ contain
D.
in
highly
hydrogenase 703
amounts
hydrogenase other
presence a
large
probe Figure
tends
hydrogenase of
multiple
to
differentiate
2,
sensitive activity
which
of
the to was
periplasmic inhibition relatively
Vol. 139, No, 2,1986
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
,°° k 60 ko 40
20
I
I
Io
20
m
Inhibition
2.
o f D. ~ ! g ~ E ~
hydrogenases
The h y d r o g e n a s e a c t i v i t y (-0-0-) and t h e p u r i f i e d measured in the presence extent of inhibition was
insensitive
to
inhibition
hydrogenase(s).
This
solubilization
and
hydrogenase
activities.
with
X-114
Triton
hydrogenase the
(21).
has
properties
After
forms
hydrogenase-l, hydrogenase hydroxyapatite, the
first
in
at the
of
30°C
is
hydrogenase
which
remains
the on
periplasmic
DEAE-Biogel
hydrogenase
activity (NiFe)
in
eluted
and
were the by
early 30
and
an
(NiFe) 704
extended
membrane a
the
contained
of
hydrogenase-3
that
hydrophilic (Table
phase I).
three
follows: the
buffer in
the
membrane
hydroxyapatite,
fractlons
of
indicating
intrinsic
as
fractlon
portion
hydrogenase
identified
by
membrane-bound
phase
in
mM p h o s p h a t e
hydrogenase-2, peak
(Fe)
three
the
hydrophobic
(NiFe)
been
(20),
activity
contained
activity
extraction
of
has of
for
of
of
presence
observation
partitioning remains
chromatography
molecular
of
The
the
characterization
responsible
protein the
and
activity
enzyme(s)
preliminary
After
by CO
of t h e c r u d e membrane f r a c t i o n periplasmic hydrogenase ( - e - O - ) was of different a m o u n t s o f CO. The expressed as % remaining activity.
suggesting
partial
50
(pL)
CO Fig.
40
30
(NiFe)
first
peak
of
from
the
late
which
fractions was
Vol. 139, No. 2, 1986
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table i.
Comparison of the Hydrogenase
from D. vulgaris
Specific Activities (kat/@) H 2 Uptake H 2 Evolution
Subunit Structure (KDa)
Effect of CO
Hydrogenase
Electrophoresis (Rf)
Hase l q A Dv. Dg. Db.
Periplasmic (Fe) hydrogenase
S
800x103
80x103
0.49
43,110
I
5.3
3.9
0.ii
85,45
+ +
Membrane(NiFe) hydrogenase (NiFe) hydrogenase
(2)
I
328
112
0.14
85,45
(NiFe) hydrogenase
(3)
I
560
1850
0.06
86,45
i.
S, sensitive,
contained buffer.
in The
hydrogenases gel
(i)
containing
activity
stain
the
+
I, insensitive second
activity
electrophoretic and
the
0.i~ is
(Fe) Triton
shown
in
peak
eluting
Soluble periplasmic
with
behavior
of
the
hydrogenase
on
a native
(X-IO0) Figure
as 3.
detected In
the
123
200
three
by
mM p h o s p h a t e
(NiFe) (5~) the
absence
polyacrylamide hydrogenase
of
the
) Membrane t b°und
&
D. vulgaris Hydrogenases Fig.
3.
-
Native
gel
electrophoresis
o f D.
vu~gar~s
hydrogenases.
Three membrane hound hydrogenases separated on hydroxyapatite c o l u m n w e r e a n a l y z e d by n a t i v e g e l electrophoresis (5~ a c r y l a m i d e and 0 . 1 ~ T r i t o n X-IO0) and compared with the periplasmic h y d r o g e n a s e by a c t i v i t y staining w i t h BV (0.SmM) a n d 2 , 3 , 5 - t r i p h e n y l tetrazolium chloride (1.OmM). 705
Vol. 139, No. 2,1986
detergents, stacking
the
(NiFe)
gel.
Each
protein
and their
(12.5~
acrylamide
into
two
also
were
minor were
not
of
giving
are
and
0.1~
SDS)
(~6
and
dissociated
completely
nickel
to it
completely
the
of
be
(Fe)
hydrogenase
of
D.
gigas,
Western
blot
technique.
that
vulgaris
bydrogenases
of
D.
D.
the
but
each
of
(NiFe)
2
4 to
5
of
the of
0.3
g.
bydrogenase
selenium
(NiFe)
and
hydregenases
presence
molecule
the
the
in
an
amount
hydrogenase-1
hydrogenase-1
and
is
3;
not
hydrogenase-1
-2
of
D.
against
~g~!~,
the
cytoplasmic
each
results
of
antibody provided
least
three
the
purified
periplasmic
(NiFeSe)
reactivities
the
(Fe)
the
(NiFe)
hydrogenase
of
different
determined definitive
antigenically
hydrogenase
against
but
with
-2
not
the
fact
the
does
not
(NiFe)
by
the
evidence distinct
other
two
of
desulfuricans
D.
subunit large
with
706
subunits
with of
of
the
subunits
antibody
(NiFe)
against mean
and
(Norway
of
that
the D.
~igas
(NiFe)
hydrogenases;
of
necessarily
only
bydrogenase
large
the
react
reacted
the
large
that
cross
gigas
the
against
hydrogenase
The and
raised
1).
(NiFeSe)
vulgaris.
and
at
reactivity
exclusively
D.
with
antibody
and
were
the
The
against
hydrogenase; weak
4)
contains
antibody
hydrogenase
major
dissociates
these of
the
On SDS-PAGE
Kda)
analyses
per
in
the
of
vulgaris
(Table
hydrogenase-1
reacts
that
45
that
addition,
found
and
(Norway of
against
In
antibodies
hydrogenases
exhibited
+ 1.
was
and
indicate
iron
1.
on
hydrogenases-1
indicating
of
one
hydrogenase-3
(85
emission
hydrogenase
desulfuricans
(Fe)
13
Table
(NiFe)
Metal
atom
noted
rabbit
periplasmlc
Thus,
(NiFe) the
remained
purified.
Polyclonal
D.
g.
in
subunits
detected
nickel
should
the
and
contained
presented
two
plasma
4.0
ratio
preparation
purified.
by
and
a Fe/Ni
however,
were
precipitated
45 K D a ) ;
into
bands
yet
equivalent
D.
values
hydrogenases
atom
hydrogenases
hydrogenase
Rf
subunits
protein
three
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
antibody 4)
hydrogenase-3
the
(NiFe)
the
(NiFe)
the
two
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
VoI. 139, No. 2 , 1 9 8 6
hydrogenases
are
forms
results
these
two
from
D.
and
results
vulgaris
kay
of play
hydrogen
hydrogen
E.
coll
for
of
to
a
model specific
one
be
of
of
the
the The by
D.
nickel
the
electrophoretlc relationship
of
further
not
hydrogenase
been
reductions
kay or
of
D.
be
g~gas
and
however,
postulated
involved
oxidations
of
to
physiological
established; as
fraction
hydrogenases
The
hydrogenase
they
membrane
containing
desulfuricans.
cytoplasmic or
that
(NiFe)
have
(23)
of
established
establish
hydrogenases role
that
characterization.
types
hydrogenase
cycling
of
two
related
these the
only
biochemical
contains
(NiFeSe)
roles
can
or
modification.
conclusively
immunologically the
(22)
proteolytic
hydrogenases
purification Our
identical
in as
in
the the
in
one the
activation case
of
(24,25).
ACKNOWLEDGEMENTS T h e s e s t u d i e s w e r e s u p p o r t e d in part u n d e r c o n t r a c t no. D E A - 5 0 9 - 7 9 ER I 0 4 9 9 - A 0 0 2 f r o m the U.S. D e p a r t m e n t of E n e r g y to H . D . P . , and g r a n t s from the N a t i o n a l S c i e n c e F o u n d a t i o n no. DMB 8 4 1 9 6 3 2 to J,L. and H . D . P . and f r o m the N a t i o n a l I n s t i t u t e s of H e a l t h no. I Rol GM 3 4 9 0 3 to J.L. and H . D . P . The a u t h o r s w i s h to t h a n k the p e r s o n n e l of the U n i v e r s i t y of Georgia fermentation p l a n t for the g r o w t h of D. vulgari_ss, B e n e t C. P r i c k r i l and N a n c y B o n d for a s s i s t a n c e in the p r e p a r a t i o n of h y d r o g e n a s e antibodies, Dr. D a l u l a t S. P a t i l for the p r e p a r a t i o n of a n t i b o d i e s to D. b a c u l a t u s hydrogenase, and Dr. N a n d a K. M e n o n for a s s i s t i n g the W e s t e r n i m m u n o b l o t s .
REFERENCES 1. 2,
3.
4. 5.
6. 7. 8. 9.
Van der Westen, H., Mayhew, S.G. and Veeger, C. 1978. FEBS Lett. 86: 122-26. Huynh, B.H., Czechowskt, M.H., Kruger, H.J., DerVartanian, D.V., Peck, H.D., Jr., and LeGall, J. 1984. Proc. Natl. Acad. Sci. (US) 8~: 3728-3732. LeGall, J., Ljungdahl, P.O., Noura, I., Peck, H.D., Jr., Xavier, A.V., Moura, J.J.6., Teixeira, M., Huynh, B.H., and DerVartanian, D.V. 1982. Biochem. Biophys. Res. Commun. ~06: 610-816. Cammack, R., Patil, D., Aguirre, R., and Hatchikian, E.C., 1982. FEBS L e t t . ~42: 289-292. Teixeira, M., Moura, I., Xavier, A.V., Ruynh, B.H., DerVartanian, D.V., Peck, H.D., Jr., LeGall, J., and J.J.6. Noura. 1985. 3. Biol. Chem. 280: 8942-8950. Rieder, R., Cammack, R., and Hall, D.O., 1984. Eur. J. Biochem. ~45: 637-643. Teixeira, N., Moura, I., Xavier, A.V., Moura, J.J.6., Fauque, G., Pickril, B., and LeGall, J. (1985) Rev. Port. Quim. 27: 194-195 Martin, S.N., Glick, 8.R., and Martin, W.G., 1980. Can. J. Biochem. 26: 1204-1213. Lalla-Naharajh, W.V., Hall, D.O., Cammack, R., Rao, K.K., and LeGall, J., 1983. Blochem. J. 209: 445-454. 707
Vol. 139, No. 2,1986
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
10. Yagi, T., Kimura, K., Daldoji, H., Sakai, F., Tamura, S., and Inokuchi, H., 1978. J. B i o c h e m (Tokyo) 79: 661-671. 11. Yagi, T., Kimura, g., and Inokuchi, H., 1985. J. Biochem. (Tokyo) 97: 181-187. 12. Ackrell, B.A.C., Asato, R.M., and Mower, H.F. (1966) J. B a c t e r l o l 92: 8 2 8 - 8 3 8 . 13. Kruger, H.J., Huynh, B.H., Ljungdahl, P.O., Xavier, A.V., D e r V a r t a n l a n , D.V., Houra, J., Peck, H.D., Jr., Telxeira, M., Moura, J.J.G., and LeGall, J., (1982) J. Biol. Chem. ~ Z : 14620-14623. 14. L e G a l l , J . , M a z z a , G . , and D r a g o n i , N . , ( 1 9 6 5 ) B i o c h e m . B i o p h y s . Acts 99: 385-387. 15. L i s s o l o , T., Poluin, S . , and Thomas, D . , ( 1 9 8 4 ) J. B i o l . Chem. 259: 11725-11729. 16. M a r k w e l ] , H . A . K . , Haas, S.M., B i e b e r , L . L . , and T o l b e r t , N.E., (1978) A n a l . Btochem. 87: 2 0 6 - 2 1 0 . 17. L a e m m l i , U . K . , ( 1 9 7 0 ) N a t u r e 2 2 7 : 6 8 0 - 6 8 5 . 18. H a t d , A. and S u t s s a , M ., ( 1 9 8 3 ) M e t h o d s E n z y m o l . 9 6 : 1 9 2 - 2 0 5 19. Hawkes, R . , N i d a y , E. and G o r d o n , J . , (1982) Anal. Btochem. 119: 142-147 20. B o r d i e r , C . , ( 1 9 8 1 ) J. B i o l . Chem. 2 5 6 : 1 6 0 4 - 1 6 0 7 . 21. B r i c k e r , T . M . , and S h e r m a n , L . A . , (!984) Arch. Biochem. Biophys. 235: 2 0 4 - 2 1 1 . 22. B a l l a n t i n e , S.P., and Boxer, D.H., (1985) J. Bacteriol. !~: 454-459. 2 3 . Odom, J . H . , and Peck, H.D., Jr., ( 1 9 8 1 ) FEMS L e t t . !~: 47-50. 24. S a w e r s , R . G . , B a l l a n t i n e , S.P., and Boxer, D.H., (1985) J. Bacteriol. !~: 1324-1331. 25. Harker, A . R . , Z u b e r , M., a n d E v a n s , H . J . (1986) J. Bactertol. 165: 579-584. m
m
708
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
September 16, 1986
Pages 70]-708
THE PRESENCE OF MULTIPLE I N T R I N S I C MEMBRANE NICKEL-CONTAINING HYDROGENASES IN DESULFOVIBRIO VULGARIS (HILDENBOROUGH)
Thierry
Lissolo,
Eui
S.
Choi,
Jean
LeGall
and
Harry
D.
Peck,
Jr.
School of Chemical Sciences Department of Biochemistry University of Georgia Athens, Georgia 30602
Received July 30, 1986
Three intrinsic membrane proteins exhibiting oxygen stable hydrogenase activity have been isolated f r o m 2- 2 ~ ! g a r i s . In contrast to the periplasmtc exclusively non-heme iron hydrogenase, all three hydrogenases contain Ni i n a d d i t i o n to non-heme iron, have low s p e c i f i c activities and a r e i n s e n s i t i v e to inhibition by CO. None o f t h e t h r e e hydrogenases cross react w i t h IgA a g a i n s t the periplasmic hydrogenase o f D. v u l g a r i s b u t t w o o f t h e new hydrogenases cross react w i t h IgA a g a i n s t the periplasmic nickel containing hydrogenase o f D. g ! g a s a n d t h e o t h e r new h y d r o g e n a s e cross reacts w i t h IgA a g a i n s t the periplasmic nickel and s e l e n i u m
hydrogenase
Three been
of D. d e s u l f u r i c a n s
soluble
isolated
reducing
and
belonging
exclusively
from
D.
iron
hydrogenase
~!g~E!~
baculatus hydrogenase
Desulfovibrio established
the
[(NiFe)
D.
the
iron
activities
have
(12,13);
been
however,
these
D.
gigas
and
the
not
within been
represent
Abbreviations: BV, B e n z y l v i o l o g e n ; SDS, s o d i u m a n d PAGE, p o l y a c r y l a m i d e gel electrophoresis.
701
sulfate
hydrogenase] non-heme
(3,4,5);
and
the
[(NiFeSe)
closely and
have
the
[(Fe)
hydrogenase
reported
activities
of
containing
(8,9,10,11)
has
hydrogenase
Desulfovibrio:
from
(6),
it
of
species
nickel
selenium
associated
forms
hydrogenase
periplasmic
iron
© 1986AcademicPress, Inco
different
genus
desulfuricans
Membrane
whether
from
hydrogenase]
non-heme
from (7).
to
--4).
molecular
non-heme
(1,2);
containing
hydrogenase]
stable
characterized
bacteria
periplasmlc
nickel
oxygen
(Norway
related
multiple
a single
D.
soluble
species
of
conclusively distinct dodecyl
molecular sulfate;
0006-291X/86 $1.50 Copyr~ht © 1986 ~ Academ~ Pre~, Inc. A# r~h~ ~ r~roduction in a ~ ~ r m reservel
VoI. 139, No. 2,1986
forms
of
hydrogenase
hydrogenase In
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
with
this
other
in
are
artifacts
we
report
hydrogenases
addition
due
to
the
association
of
proteins.
communication,
nickel-containing vu!garis
or
to
the
in well
the
the
presence
membrane
characterized
of
three
fraction periplasmtc
of
D. (Fe)
hydrogenase. METHODS Assays
and
PreRarations
D. v u l g a K ~ s (NCIB 8303) was grown on lactate-sulfate medium and extracts prepared as previously described (14). Hydrogen uptake and evolution activities were assayed spectrophotometrically (15) and protein was determined by a modified Lowry method (16). Native polyacrylamide gel electrophorests employed 5~ slab gels containing 0.1~ Triton X-100 (17) and hydrogenase activities were visualized by staining with BV ( 0 . 5 mM) a n d 2 , 3 , 5 - t r l p h e n y l tetrazoltum chloride (1 mM). S l a b g e l SDS e l e c t r o p h o r e s i s was carried out and the reactivities of hydrogenases wi£h polyclonal antibodies raised against purified hydrogenases f r o m D. f f ~ f f a s ( 3 ) , D. v u l g a E ! s (2) and D. d e s u l f u r t c a n s (Norway 4) (6) were analyzed by the enzyme-linked immuno electrotransfer blot technique (18) using horse radish peroxtdase-conjugated second antibody (19). Fe, Nt and Se were determined by plasma emission spectroscopy using a Jarrell Ash model 750 atomcomp. For the inhibition o f H2 u p t a k e activity by C0, the concentration o f CO w a s v a r i e d by the addition o f CO a n d H 2 saturated buffer solutions. Purification
of
membrane-bound
h~drogenases
The crude extract was centrifuged at 100,000 xg to obtain the membrane fraction which was extracted with 1~ Triton (X-114) containing 1 5 0 mM NaC1 a n d 10 mM t r i s - H C 1 , pH 7 . 4 (20,21). After incubation a t O°C f o r 2 h o u r s , the suspension was centrifuged for 20 m i n . a t 1 2 , 0 0 0 xg to remove cell debris and the clear supernate was incubated at 30°C for 5 min. to allow for precipitation of the detergent which was removed by centrifugation at 12,000 xg for 20 min. 28°C. The lower detergent phase was collected and redlssolved in the same buffer without Triton (X-114) by incubation at 0°C. The phase separation was repeated and the washed detergent phase was diluted 10x with a solution of Triton (X-100) plus 5 mM t r i s - H C l pH7.8, to give a final concentration o f 1~ T r i t o n (X-100). The protein was loaded onto a DEAE-Bio-Gel column (4.5 x 29 cm), the column washed with a liter of 0.01M Tris - HC1, and the hydrogenases eluted with a tris-HCl linear gradient (one liter each of 0.01M and 0.40 M tris-HC1). The elution profile is shown in Figure 1, u p p e r graph. The hydrogenase fractions were pooled, and applied to a hydroxyapatite (Bio-Rad) column ( 3 x 15 c m ) , a n d t h e proteins eluted by a linear phosphate gradient ( 5 0 0 ml e a c h o f 0 . 0 2 M and 0.30 M potassium phosphate buffer). As s h o w n i n F i g u r e 1, lower graph, the first peak of hydrogenase activity contained two different hydrogenases when analyzed by gel electrophoresis and activity staining. The third hydrogenase was well separated from the other two hydrogenase activities. All procedures were carried out in air at 4°C and all buffers were adjusted t o pH 7 . 8 a n d c o n t a i n e d 0.1~ Triton X-IO0. 702
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 139, No. 2 , 1 9 8 6
£ 2 -4 ;O
Z 0.4
O m
I--
"4
Iu
0.2
/" 100
.
' 150 FRACTION
2
i
c v
>" 1
t,,m
20 22 24 26 28 30 0.4
pig
t~ 0.2
Fig.
1.
z
,.(
i
!
25
O
50 75 FRACTION
Chromatography of m e m b r a n e ( U p p e r ) and h y d r o x y a p a t i t e
100
bound hydrogenases (Lower)
on
DEAE-BioGel
The d e t e r g e n t - r i c h phase containing membrane bound hydrogenases was l o a d e d o n t o a D E A - B i o G e l c o l u m n a f t e r 10X d i l u t i o n w i t h T r i t o n X - 1 0 0 ( f i n a l conc. 1~) and the p r o t e i n s were eluted with a linear 0.01-0.40 M tris-HCl gradient (Upper) . The h y d r o g e n a s e fractions from DEA-BioGel a p p l i e d to a h y d r o x y a p a t i t e c o l u m n and the eluted with a linear 0.02-0.30M potassium (Lower). The f r a c t i o n s of the f i r s t p e a k gel e l e c t r o p h o r e s i s and a c t i v i t y s t a i n i n g
were pooled, proteins were phosphate gradient w e r e a n a l y z e d by (inset).
RESULTS AND D I S C U S S I O N
Cell-free the to
high
preparations
specific
contaminate
activities.
all
was
(Fe)
and
(Fe)
hydrogenase
by
activity
Our
hydrogenase
(NiFe)
CO w h i l e
the
of
cell first
perlplasmic fractions
evidence
obtained
as
for
As
mask
the CO a s shown
anticipated,
membrane-bound
(Fe)
and
employing
hydrogenases. is,
vu!g~[!~ contain
D.
in
highly
hydrogenase 703
amounts
hydrogenase other
presence a
large
probe Figure
tends
hydrogenase of
multiple
to
differentiate
2,
sensitive activity
which
of
the to was
periplasmic inhibition relatively
Vol. 139, No, 2,1986
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
,°° k 60 ko 40
20
I
I
Io
20
m
Inhibition
2.
o f D. ~ ! g ~ E ~
hydrogenases
The h y d r o g e n a s e a c t i v i t y (-0-0-) and t h e p u r i f i e d measured in the presence extent of inhibition was
insensitive
to
inhibition
hydrogenase(s).
This
solubilization
and
hydrogenase
activities.
with
X-114
Triton
hydrogenase the
(21).
has
properties
After
forms
hydrogenase-l, hydrogenase hydroxyapatite, the
first
in
at the
of
30°C
is
hydrogenase
which
remains
the on
periplasmic
DEAE-Biogel
hydrogenase
activity (NiFe)
in
eluted
and
were the by
early 30
and
an
(NiFe) 704
extended
membrane a
the
contained
of
hydrogenase-3
that
hydrophilic (Table
phase I).
three
follows: the
buffer in
the
membrane
hydroxyapatite,
fractlons
of
indicating
intrinsic
as
fractlon
portion
hydrogenase
identified
by
membrane-bound
phase
in
mM p h o s p h a t e
hydrogenase-2, peak
(Fe)
three
the
hydrophobic
(NiFe)
been
(20),
activity
contained
activity
extraction
of
has of
for
of
of
presence
observation
partitioning remains
chromatography
molecular
of
The
the
characterization
responsible
protein the
and
activity
enzyme(s)
preliminary
After
by CO
of t h e c r u d e membrane f r a c t i o n periplasmic hydrogenase ( - e - O - ) was of different a m o u n t s o f CO. The expressed as % remaining activity.
suggesting
partial
50
(pL)
CO Fig.
40
30
(NiFe)
first
peak
of
from
the
late
which
fractions was
Vol. 139, No. 2, 1986
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table i.
Comparison of the Hydrogenase
from D. vulgaris
Specific Activities (kat/@) H 2 Uptake H 2 Evolution
Subunit Structure (KDa)
Effect of CO
Hydrogenase
Electrophoresis (Rf)
Hase l q A Dv. Dg. Db.
Periplasmic (Fe) hydrogenase
S
800x103
80x103
0.49
43,110
I
5.3
3.9
0.ii
85,45
+ +
Membrane(NiFe) hydrogenase (NiFe) hydrogenase
(2)
I
328
112
0.14
85,45
(NiFe) hydrogenase
(3)
I
560
1850
0.06
86,45
i.
S, sensitive,
contained buffer.
in The
hydrogenases gel
(i)
containing
activity
stain
the
+
I, insensitive second
activity
electrophoretic and
the
0.i~ is
(Fe) Triton
shown
in
peak
eluting
Soluble periplasmic
with
behavior
of
the
hydrogenase
on
a native
(X-IO0) Figure
as 3.
detected In
the
123
200
three
by
mM p h o s p h a t e
(NiFe) (5~) the
absence
polyacrylamide hydrogenase
of
the
) Membrane t b°und
&
D. vulgaris Hydrogenases Fig.
3.
-
Native
gel
electrophoresis
o f D.
vu~gar~s
hydrogenases.
Three membrane hound hydrogenases separated on hydroxyapatite c o l u m n w e r e a n a l y z e d by n a t i v e g e l electrophoresis (5~ a c r y l a m i d e and 0 . 1 ~ T r i t o n X-IO0) and compared with the periplasmic h y d r o g e n a s e by a c t i v i t y staining w i t h BV (0.SmM) a n d 2 , 3 , 5 - t r i p h e n y l tetrazolium chloride (1.OmM). 705
Vol. 139, No. 2,1986
detergents, stacking
the
(NiFe)
gel.
Each
protein
and their
(12.5~
acrylamide
into
two
also
were
minor were
not
of
giving
are
and
0.1~
SDS)
(~6
and
dissociated
completely
nickel
to it
completely
the
of
be
(Fe)
hydrogenase
of
D.
gigas,
Western
blot
technique.
that
vulgaris
bydrogenases
of
D.
D.
the
but
each
of
(NiFe)
2
4 to
5
of
the of
0.3
g.
bydrogenase
selenium
(NiFe)
and
hydregenases
presence
molecule
the
the
in
an
amount
hydrogenase-1
hydrogenase-1
and
is
3;
not
hydrogenase-1
-2
of
D.
against
~g~!~,
the
cytoplasmic
each
results
of
antibody provided
least
three
the
purified
periplasmic
(NiFeSe)
reactivities
the
(Fe)
the
(NiFe)
hydrogenase
of
different
determined definitive
antigenically
hydrogenase
against
but
with
-2
not
the
fact
the
does
not
(NiFe)
by
the
evidence distinct
other
two
of
desulfuricans
D.
subunit large
with
706
subunits
with of
of
the
subunits
antibody
(NiFe)
against mean
and
(Norway
of
that
the D.
~igas
(NiFe)
hydrogenases;
of
necessarily
only
bydrogenase
large
the
react
reacted
the
large
that
cross
gigas
the
against
hydrogenase
The and
raised
1).
(NiFeSe)
vulgaris.
and
at
reactivity
exclusively
D.
with
antibody
and
were
the
The
against
hydrogenase; weak
4)
contains
antibody
hydrogenase
major
dissociates
these of
the
On SDS-PAGE
Kda)
analyses
per
in
the
of
vulgaris
(Table
hydrogenase-1
reacts
that
45
that
addition,
found
and
(Norway of
against
In
antibodies
hydrogenases
exhibited
+ 1.
was
and
indicate
iron
1.
on
hydrogenases-1
indicating
of
one
hydrogenase-3
(85
emission
hydrogenase
desulfuricans
(Fe)
13
Table
(NiFe)
Metal
atom
noted
rabbit
periplasmlc
Thus,
(NiFe) the
remained
purified.
Polyclonal
D.
g.
in
subunits
detected
nickel
should
the
and
contained
presented
two
plasma
4.0
ratio
preparation
purified.
by
and
a Fe/Ni
however,
were
precipitated
45 K D a ) ;
into
bands
yet
equivalent
D.
values
hydrogenases
atom
hydrogenases
hydrogenase
Rf
subunits
protein
three
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
antibody 4)
hydrogenase-3
the
(NiFe)
the
(NiFe)
the
two
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
VoI. 139, No. 2 , 1 9 8 6
hydrogenases
are
forms
results
these
two
from
D.
and
results
vulgaris
kay
of play
hydrogen
hydrogen
E.
coll
for
of
to
a
model specific
one
be
of
of
the
the The by
D.
nickel
the
electrophoretlc relationship
of
further
not
hydrogenase
been
reductions
kay or
of
D.
be
g~gas
and
however,
postulated
involved
oxidations
of
to
physiological
established; as
fraction
hydrogenases
The
hydrogenase
they
membrane
containing
desulfuricans.
cytoplasmic or
that
(NiFe)
have
(23)
of
established
establish
hydrogenases role
that
characterization.
types
hydrogenase
cycling
of
two
related
these the
only
biochemical
contains
(NiFeSe)
roles
can
or
modification.
conclusively
immunologically the
(22)
proteolytic
hydrogenases
purification Our
identical
in as
in
the the
in
one the
activation case
of
(24,25).
ACKNOWLEDGEMENTS T h e s e s t u d i e s w e r e s u p p o r t e d in part u n d e r c o n t r a c t no. D E A - 5 0 9 - 7 9 ER I 0 4 9 9 - A 0 0 2 f r o m the U.S. D e p a r t m e n t of E n e r g y to H . D . P . , and g r a n t s from the N a t i o n a l S c i e n c e F o u n d a t i o n no. DMB 8 4 1 9 6 3 2 to J,L. and H . D . P . and f r o m the N a t i o n a l I n s t i t u t e s of H e a l t h no. I Rol GM 3 4 9 0 3 to J.L. and H . D . P . The a u t h o r s w i s h to t h a n k the p e r s o n n e l of the U n i v e r s i t y of Georgia fermentation p l a n t for the g r o w t h of D. vulgari_ss, B e n e t C. P r i c k r i l and N a n c y B o n d for a s s i s t a n c e in the p r e p a r a t i o n of h y d r o g e n a s e antibodies, Dr. D a l u l a t S. P a t i l for the p r e p a r a t i o n of a n t i b o d i e s to D. b a c u l a t u s hydrogenase, and Dr. N a n d a K. M e n o n for a s s i s t i n g the W e s t e r n i m m u n o b l o t s .
REFERENCES 1. 2,
3.
4. 5.
6. 7. 8. 9.
Van der Westen, H., Mayhew, S.G. and Veeger, C. 1978. FEBS Lett. 86: 122-26. Huynh, B.H., Czechowskt, M.H., Kruger, H.J., DerVartanian, D.V., Peck, H.D., Jr., and LeGall, J. 1984. Proc. Natl. Acad. Sci. (US) 8~: 3728-3732. LeGall, J., Ljungdahl, P.O., Noura, I., Peck, H.D., Jr., Xavier, A.V., Moura, J.J.6., Teixeira, M., Huynh, B.H., and DerVartanian, D.V. 1982. Biochem. Biophys. Res. Commun. ~06: 610-816. Cammack, R., Patil, D., Aguirre, R., and Hatchikian, E.C., 1982. FEBS L e t t . ~42: 289-292. Teixeira, M., Moura, I., Xavier, A.V., Ruynh, B.H., DerVartanian, D.V., Peck, H.D., Jr., LeGall, J., and J.J.6. Noura. 1985. 3. Biol. Chem. 280: 8942-8950. Rieder, R., Cammack, R., and Hall, D.O., 1984. Eur. J. Biochem. ~45: 637-643. Teixeira, N., Moura, I., Xavier, A.V., Moura, J.J.6., Fauque, G., Pickril, B., and LeGall, J. (1985) Rev. Port. Quim. 27: 194-195 Martin, S.N., Glick, 8.R., and Martin, W.G., 1980. Can. J. Biochem. 26: 1204-1213. Lalla-Naharajh, W.V., Hall, D.O., Cammack, R., Rao, K.K., and LeGall, J., 1983. Blochem. J. 209: 445-454. 707
Vol. 139, No. 2,1986
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
10. Yagi, T., Kimura, K., Daldoji, H., Sakai, F., Tamura, S., and Inokuchi, H., 1978. J. B i o c h e m (Tokyo) 79: 661-671. 11. Yagi, T., Kimura, g., and Inokuchi, H., 1985. J. Biochem. (Tokyo) 97: 181-187. 12. Ackrell, B.A.C., Asato, R.M., and Mower, H.F. (1966) J. B a c t e r l o l 92: 8 2 8 - 8 3 8 . 13. Kruger, H.J., Huynh, B.H., Ljungdahl, P.O., Xavier, A.V., D e r V a r t a n l a n , D.V., Houra, J., Peck, H.D., Jr., Telxeira, M., Moura, J.J.G., and LeGall, J., (1982) J. Biol. Chem. ~ Z : 14620-14623. 14. L e G a l l , J . , M a z z a , G . , and D r a g o n i , N . , ( 1 9 6 5 ) B i o c h e m . B i o p h y s . Acts 99: 385-387. 15. L i s s o l o , T., Poluin, S . , and Thomas, D . , ( 1 9 8 4 ) J. B i o l . Chem. 259: 11725-11729. 16. M a r k w e l ] , H . A . K . , Haas, S.M., B i e b e r , L . L . , and T o l b e r t , N.E., (1978) A n a l . Btochem. 87: 2 0 6 - 2 1 0 . 17. L a e m m l i , U . K . , ( 1 9 7 0 ) N a t u r e 2 2 7 : 6 8 0 - 6 8 5 . 18. H a t d , A. and S u t s s a , M ., ( 1 9 8 3 ) M e t h o d s E n z y m o l . 9 6 : 1 9 2 - 2 0 5 19. Hawkes, R . , N i d a y , E. and G o r d o n , J . , (1982) Anal. Btochem. 119: 142-147 20. B o r d i e r , C . , ( 1 9 8 1 ) J. B i o l . Chem. 2 5 6 : 1 6 0 4 - 1 6 0 7 . 21. B r i c k e r , T . M . , and S h e r m a n , L . A . , (!984) Arch. Biochem. Biophys. 235: 2 0 4 - 2 1 1 . 22. B a l l a n t i n e , S.P., and Boxer, D.H., (1985) J. Bacteriol. !~: 454-459. 2 3 . Odom, J . H . , and Peck, H.D., Jr., ( 1 9 8 1 ) FEMS L e t t . !~: 47-50. 24. S a w e r s , R . G . , B a l l a n t i n e , S.P., and Boxer, D.H., (1985) J. Bacteriol. !~: 1324-1331. 25. Harker, A . R . , Z u b e r , M., a n d E v a n s , H . J . (1986) J. Bactertol. 165: 579-584. m
m
708