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Identification of a cDNA clone in λgt11 for the transacylase component of branched chain ketoacid dehydrogenase
Vol. 131, No. 2, 1985 September
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
16. 1985
Pages
OF A cDNA CLONE IN lgtll OF BRANCHED CHAIN KETOACID
IDENTIFICATION COMPONENT
Stuart Division Received
Litwer
and
Dean
July
FOR THE TRANSACYLASE DEHYDROGENASE
J.
of Medical Genetics,Department Emory University, Atlanta,
961-967
Danner of Pediatrics, GA 30322
1, 1985
Two cDNA clones for the transacylase protein of the branched chain ketoacid dehydrogenase complex CE.C. 1.2.4.41 have been isolated from a human fetal liver cDNA expression library in Xgtll using antibody selection. By selective antibody elutfon from nftrocellulose filters containing the fusfon proteins* it was determined that these inserts represent the transacylase protein. These data support the hypothesis that thfs protein is synthesized in the cytosol on transcrfpts independent of the other proteins of the branched chafn ketoacid dehydrogenase complex. 0 1985 Academic Press, Inc.
Branched
chain
a multienzyme membrane
(1).
disease,
result
this
coding
associated
with
Inherited
human
disorders,
these
weight
55,000)
ketoaci
d,
whfle
El
formed
from
decarboxylase only
in
proteins
form
urine forming show
implying the
nuclear basfc
complex.
CEC 1.6.4.31, of
the
(molecular
branched
chain
dehydrogenase
forms
the
B subunits
the
syrup
families (2)
(3).
complexes.
E2 component of
46,000 Amino
phosphorylation
is
inner
proteins
patterns
activfty for
the
affected
pyruvate
a and
BCKDI
mitochondrial maple
component
protein
available
subunit
of
and acid site
BCKD
37,000
Da
sequence in
Ela
(4). Defects
result
a common
Da transacylase is
the
dehydrogenase
and
the is
Four
a-ketoglutarate
providing data
is
of
inheritance
lipoamide
CEC 1.2.4.4,
defects
analysis
proteins.
A flavoprotefn,
A 52,000
specific
Pedigree recessive
for
dehydrogenase
complex
from
complex.
autosomal
ketoacid
in
in decreased
any
of
the
three
activity
of
unique the
961
subunits
complex
All
and
of the
Copyright 0 1985 rights of reproduction
BCKD can ensuing 0006-291X/85 $1.50 by Academic Press, Inc. in any form reserved.
Vol. 131,No.
2, 1985
clinical
picture
antisera
has
subunit,
as
use
these
been
the
of provides
independently
m described in hgtll School of
to genes
a cDNA the
gene
on
cDNA
BCKD the
direct
suggests
52
evidence this
component,
clones
directing for
BCKD specific
disorder
oligonucleotide
a separate
Ilhrnr~ by Young was kindly Medicine,
inherited
develop
clone
RESEARCH COMMUNICATIONS
disease. a missing
the
select
first
and
urine
describe
for to
AND BIOPHYSICAL
syrup
to
a mechanism
of
a nuclear
maple
used
library
isolation This
of
antibodies
expression analysis
BIOCHEMKAL
protein
from
kDa,
(5). the
probes
synthesis. EZr that may
the
Here
We now Xgtll for we
component BCKD-EP be
E2
use report of
is
in
BCKD.
coded
on
made
transcript.
A cDNA library & Davis (6,7) provided by Houstonr TX.
produced essentially as from human fetal liver inserted Dr. Savio C.L. Woo, Baylor
Polyclonal antisera was produced in rabbits AJ.whlIlasi as previously described (8). Antibodies which recognize &9harIchla cc;nll proteins were absorbed from the IgG fraction by affinity gel chromatography. E. coli strain BNN97 containing Xgtll without the cDNA library was grown in LB broth to stationery log phase and the cells pelleted by centrlfugation. Cells were washed in 100 ml of phosphate buffered saline CPBSI, pelleted by centrifugation# and suspended in 40 ml of O.lM HOPS pH 7.5 for lysis by sonication. After removal of cell debrls by low speed centrifugation, the soluble proteins were mixed with BioRad Affigel 10 8 15 according to the manufacturer's instructions. Coupling was allowed to continue overnight at 4'. Unreacted coupling sites were blocked by incubation of the gel for one hour in IM glycfne ethyl ester. After extensive washing with PBS, the mixed bed Afflgel-lo,15 was incubated overnlght at 4' with anti-BCKD IgG. The gel was then poured into a 0.7 X 10 cm column and unbound antibody collected. This procedure was repeated and the solutions of unbound IgG combined for use in screening the llbrary. E. co11 strain Y1090 was infected Su!%ning ltha Ilhrary: Selection of plaques with Xgtll containing the cDNA library. producing antigenic proteins was mad8 essentially as described by deWet ti nL (9). Briefly, 2.8 X 10 recombinants were plated in top agarose on 7 150cm2 plates of LB agar. After growth for 4 hours at 42' C the plates were overlayed with a nitrocellulose filter impregnated with 10 m# isopropyl-B-D-thiogalactopyranoside CIPTGI. After 2 hours at 37' C, filters and plates were keyed and the filters removed. Each filter was soaked in 50mM TrisHClr pH 7.4 containing 150mH NaCl, 1% gelatin and 1% Tween 20 (IM-1) for 1 hr and then in 50mM Trfs-HCl, pH 7.4 containing 150 0.5H EDTA, 1% Tween 20 (IM-2) for 45 min. mM NaCl, 0.25% gelatin, Filters were then placed in IM-2 with 5% bovine serum and 25~1 of anti-BCKD IgG per 10 ml for 1 hr. After washing 3 X 10 mfn with IM-2, the filters were placed in IM-2 plus 5% bovine serum and 3 962
Vol.
131,
No. 2, 1985
BlOCHEMlCALANDBlOPHYSlCALRESEARCHCOMMUNlCATlONS
ul/lO ml goat antlrabbit IgG-peroxidase CBio-Radl for 45 min. Filters were washed 3 X 10 min with IM-2 prfor to stalning in filtered solution of 5OmM Trls-HClr pH 7.5 containing 0.3mg When the color diaminobenzidine/ml and 0.2ul/ml of 50% H202. fully developed (S-60 min), the filters were washed in deionized water and dried. This staining procedure gave lower background than using radiolabel detection. Plaques producing antlgenic fusion proteins were selected for subsequent rounds using the large bore of a sterile Pasteur pipette. Plaque number/plate reduced 10 fold for each successive round of screening beginning at 400,00O/plate down to 4O/plate.
a was
was
Selar;j&2n Qf E2 dQnas: To Select the clone for the E2 protein, plaques were grown as before and the protein production induced with IPTG impregnated nitrocellulose filters. Filters were exposed to the polyclonal BCKD-IgG for 1 hr. Unbound antibodies were washed from the filters and specifically bound antibodies eluted with 5mH glycine-HCl, pH 2.3, contalnlng 15OmM NaCl, 0.5% Triton X-100, and 100 ug BSA/ml. Washes were immediately neutralized with 1M Tris-HCl to a pH of 7.4. Eluted antibodies were used for Western blot analysis (5) of either purlfied BCKD or mitochondrial proteins. A similar procedure has been reported for the identification of the glucocordicoid receptor gene (10).
Initial positive
plaques
through all
six
were
were after
third
tested
and
of
rounds positive
expanslon. final
2.8
found
successive
plaques
positive the
screening
X
which of
for
round
recombinant
five
phage
each
Figure (6th)
lo6
of 1
of
continued selection.
five shows
selection
phage. positive At
clones stained for
Seven
and
this
remained
filters clone
point,
from 58.
Figure 1: Nltrocellulose fllters stalned with dlamlnobenzldtne as described for Western blot analysts In Methods. Left side shows the third selectlon round at a density of 4000 plaques/plate. Right side shows the final selectlon round with all plaques staining posltlve for antlgenic fusion protetn. Data is for clone 58. 963
Vol.
131,
No.
2, 1985
BIOCHEMICALAND
BIOPHYSICALRESEARCH
COMMUNICATIONS
Figure 2: Western blot of fusion protein from the five positive clones. The two outside lanes are molecular weight markers. The flve middle lanes represent fusion protein from clones 6, 58, 5A, 4 and 3 readtng left to rtght. Arrow Indtcates the posltion of 8galactosldase.
To
estimate
production these
the
of
an
clones
IPTG plates
2
hr
into
of
In
Xgtll
a
control
procedure
which were
BCKD
library
was and
from coli
with
to
antigenic
In
a
7.5% blot
identified
BNN97
kDa
by
(figure
which
the
product
single
Western
200
through
2mM
from
proteins 180
by a
washed
sulfate.
strain
carried
no
plaques
resolved
single
ranging E.
production
lauryl
revealed
antisera of
used
the
complex
selectively exposed
and
the
protein
were
buffer
substantiate
contains
induction was
detected
shown).
subunits the
the
sodium
sizes
analysis
Polyclonal
of
sample
products
and
fusion
proteins
containing
the
insert
overlaying
experiment
and not
four
(11)
with
without
(Data
Induced
these
BCKD-antibodies 2).
37'.
Laemmli
cDNA
product, by
gel
analysis
the
induced at
polyacrylamide
of
antigenic
was
for
size
BCKD
to
complex.
these bound resolved
for
To
fusion the mouse
clonal
proteins
fusion
proteins mltochondrial 964
selection
recognized
establish
which
represent, from proteins
all
proteins antibodies
clones
3 in
and a
58
Vol. 131, No. 2, 1985
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
w-=
Western blot of mouse liver mftochondrfa reacted with antf odfes selectively eluted from nftrocellulose filters containing fusion protein. Left lane represents antfbodfes from lane represents the analysis with polyclonal clone 3, middle antisera and the right lane represents antibodies eluted from clone 58.
Western
blot
staining
analysis.
patterns
Figure
3 shows
complex
or
assay
with the
human
with
the
patterns
polyclonal
selected
Similar
E2 protein.
Staining
antisera
antibodies
results
were
were
mitochondrfal
on
obtained
eluted
the
same
recognize
proteins
specifically
compared
the
the
purified
tested
antibodies
filter.
exclusively
when were
to
BCKD
by this
(data
not
shown).
Rl.ssassinn Reduced severe
activity
pathologic
Causative
genetic
questions
also
multienzyme has
been
directed
of condition,
remain
to
the
BCKD complex maple
alterations
complexes proposed
the
remain
regarding entirely
whereby inner
syrup to
from
be
of 965
of
nuclear made
humans
urine
assembly
proteins
membrane
in
results
disease.
described.
Basic
mitochondrial genes.
in
mitochondria
in
the
A mechanism
cytosol by
are
N-terminal
a
Vol. 131, No. 2, 1985
leader for
BIOCHEMICAL
sequences
(12,13).
lipoamide
unique transcripts
of for
we demonstrate
This
cDNA
from
the
c-terminal
a molecular
large
enough
insert
would
to
analysis.
two
of
pub1 ication from
disease,
Taken
together,
we
subunits
coded,
of
no
El.
dehydrogenase on
the
(figure
data
In
in El
of
precursor
transcripts
El
Western
were
present
the
B subunits
independent
appears
from
each
syrup
were that
E2
present. is
independent for
describing
it
in
E2 protein maple
transcript
reports
(14,15).
the
with
translated
the
If
by the
a hypothesis
the
kDa. component
of
a patient
a and
on
be
a previous
absence
support
must
one
In
basepair
cDNA 90
than
3).
cytosolically
view
to
53
2).
CEC 3.2.1.231
E2 protein
the
information
Da(Figure gene
80
more
for
E3,
200,000
antigenically
proteins
these
have
detected
the
membrane.
inserted of
we demonstrated
while
a nuclear
the
from
clones
ca
that
individual
B-galactosidase
116,000,
epitopes
mltochondrial
urine
made
a polypeptide
(51,
the
As yet
encode
isolated
from
of
described
suggests
mitochondrial
Since
peptides
data
been
B-galactosidase
of
Only
the
the
(6).
be
the
protein
weight
would
Our
in
in
end
contain
these
blot
as
resides
has
synthesized
assembly a fusion
library
has
be
RESEARCH COMMUNICATIONS
precursor
(14,151.
BCKD may
later
Here
protein,
A larger
dehydrogenase
proteins
AND BIOPHYSICAL
made
protein. the
~1 or
8
lipoamide
that
E3 and
other
and
E2 are
distinct
from
El. Availability containing study
of mutations
both
diesase
and
multienzyme
the the
and
for
biochemical
Sells
in
S.L.C. for
the
and BCKD
resulting
reactions
human
fibroblasts
proteins
allows
us
in
syrup
urine
involved
maple in
the
assembly
to
of
mitochondria.
We thank Dr.
clone,
mechanism
complexes
help, Susan
E2-cDNA
specific
genetic
&Kng.whdw: their
this
Drs. Woo
manuscript
E.I. for
sharing
preparation.
Ginns the
6 J.A. Xgtll
Barranger cDNA
for library
Vol. 131,No.
1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
2, 1985
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Dannet-, D. J. and Elsas, L.J. (1975) Biochem. Med. 1l 7-22. Rosenberg, L.E. and Striver, C.R. (1980) In wMetabolic control and disease” Ed. by P.K. Bondy and L.E. Rosenberg, Philadelphia, pp. 691-699. W.B. Saunders, Heffelfinger, S.C., Sewell, E.T. and Danner, D.J. (1983) Biochemistry 22, 5519-5522. Cook, K.G., Bradford, A.P., and Yeaman, S.J. (1984) Eur. J. Biochem. J& 587-591. Danner, D.J., Armstrong, N., Heffelfinger, S.C., Sewell, Priest, J.H., and Elsas, L.J. (1985) J. Clin. Invest. &:*;158-860. Young, R.A. and Davis, R.W. (1983) Proc. Natl. Acad. Sci. USA BQ, 1194-1198. R.A. and Davis, R.W. (1983) Science 222, 778-782. Young, Heffelfinger, S.C., Sewell, E.T., and Danner, D.J. (1983) Biochem. J. Uz 339-344. deWet, J.R., Fukushima, H., Dewji, N.N., Wilcox, E., O’Brien, J.S. and Helinski, D.R. (1984) DNA 1, 437-447. Weinberger, C.# Hollenberg, S.M.D Ong, E.S., Harmon, J.M., Brower, S.T., Cldlowski, J.# Thompson, E.B., Rosenfeld, M.G., Evans, R.M. (1985) Science 228, 740-742. Laemmli, U. (1970) Nature 221, 680-685. Felipo, V. and Grisolla, S. (1984) Curr. Top. Cell. Reg. 21, 217-249. Hay, R., Bohni, P. and Gasser, S. (1984) Biochim. Blophys. Acta lzPI 65-07. Koike, K., Tsuji, A., Urata, Y., Morlyasu, M.* and Koike, M. pp B03-806rEd. by R.C. (1984) In Elnuins an9 fln~nprn~a~~ Bray, P.C., W. de Gruyter 8 Co., New York. Matuda, S., Shirahama, T., Saheki, T., Miura, S. and Mori, M. (1983) Biochim. Biophys. Acta 141, 86-93.
967
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
16. 1985
Pages
OF A cDNA CLONE IN lgtll OF BRANCHED CHAIN KETOACID
IDENTIFICATION COMPONENT
Stuart Division Received
Litwer
and
Dean
July
FOR THE TRANSACYLASE DEHYDROGENASE
J.
of Medical Genetics,Department Emory University, Atlanta,
961-967
Danner of Pediatrics, GA 30322
1, 1985
Two cDNA clones for the transacylase protein of the branched chain ketoacid dehydrogenase complex CE.C. 1.2.4.41 have been isolated from a human fetal liver cDNA expression library in Xgtll using antibody selection. By selective antibody elutfon from nftrocellulose filters containing the fusfon proteins* it was determined that these inserts represent the transacylase protein. These data support the hypothesis that thfs protein is synthesized in the cytosol on transcrfpts independent of the other proteins of the branched chafn ketoacid dehydrogenase complex. 0 1985 Academic Press, Inc.
Branched
chain
a multienzyme membrane
(1).
disease,
result
this
coding
associated
with
Inherited
human
disorders,
these
weight
55,000)
ketoaci
d,
whfle
El
formed
from
decarboxylase only
in
proteins
form
urine forming show
implying the
nuclear basfc
complex.
CEC 1.6.4.31, of
the
(molecular
branched
chain
dehydrogenase
forms
the
B subunits
the
syrup
families (2)
(3).
complexes.
E2 component of
46,000 Amino
phosphorylation
is
inner
proteins
patterns
activfty for
the
affected
pyruvate
a and
BCKDI
mitochondrial maple
component
protein
available
subunit
of
and acid site
BCKD
37,000
Da
sequence in
Ela
(4). Defects
result
a common
Da transacylase is
the
dehydrogenase
and
the is
Four
a-ketoglutarate
providing data
is
of
inheritance
lipoamide
CEC 1.2.4.4,
defects
analysis
proteins.
A flavoprotefn,
A 52,000
specific
Pedigree recessive
for
dehydrogenase
complex
from
complex.
autosomal
ketoacid
in
in decreased
any
of
the
three
activity
of
unique the
961
subunits
complex
All
and
of the
Copyright 0 1985 rights of reproduction
BCKD can ensuing 0006-291X/85 $1.50 by Academic Press, Inc. in any form reserved.
Vol. 131,No.
2, 1985
clinical
picture
antisera
has
subunit,
as
use
these
been
the
of provides
independently
m described in hgtll School of
to genes
a cDNA the
gene
on
cDNA
BCKD the
direct
suggests
52
evidence this
component,
clones
directing for
BCKD specific
disorder
oligonucleotide
a separate
Ilhrnr~ by Young was kindly Medicine,
inherited
develop
clone
RESEARCH COMMUNICATIONS
disease. a missing
the
select
first
and
urine
describe
for to
AND BIOPHYSICAL
syrup
to
a mechanism
of
a nuclear
maple
used
library
isolation This
of
antibodies
expression analysis
BIOCHEMKAL
protein
from
kDa,
(5). the
probes
synthesis. EZr that may
the
Here
We now Xgtll for we
component BCKD-EP be
E2
use report of
is
in
BCKD.
coded
on
made
transcript.
A cDNA library & Davis (6,7) provided by Houstonr TX.
produced essentially as from human fetal liver inserted Dr. Savio C.L. Woo, Baylor
Polyclonal antisera was produced in rabbits AJ.whlIlasi as previously described (8). Antibodies which recognize &9harIchla cc;nll proteins were absorbed from the IgG fraction by affinity gel chromatography. E. coli strain BNN97 containing Xgtll without the cDNA library was grown in LB broth to stationery log phase and the cells pelleted by centrlfugation. Cells were washed in 100 ml of phosphate buffered saline CPBSI, pelleted by centrifugation# and suspended in 40 ml of O.lM HOPS pH 7.5 for lysis by sonication. After removal of cell debrls by low speed centrifugation, the soluble proteins were mixed with BioRad Affigel 10 8 15 according to the manufacturer's instructions. Coupling was allowed to continue overnight at 4'. Unreacted coupling sites were blocked by incubation of the gel for one hour in IM glycfne ethyl ester. After extensive washing with PBS, the mixed bed Afflgel-lo,15 was incubated overnlght at 4' with anti-BCKD IgG. The gel was then poured into a 0.7 X 10 cm column and unbound antibody collected. This procedure was repeated and the solutions of unbound IgG combined for use in screening the llbrary. E. co11 strain Y1090 was infected Su!%ning ltha Ilhrary: Selection of plaques with Xgtll containing the cDNA library. producing antigenic proteins was mad8 essentially as described by deWet ti nL (9). Briefly, 2.8 X 10 recombinants were plated in top agarose on 7 150cm2 plates of LB agar. After growth for 4 hours at 42' C the plates were overlayed with a nitrocellulose filter impregnated with 10 m# isopropyl-B-D-thiogalactopyranoside CIPTGI. After 2 hours at 37' C, filters and plates were keyed and the filters removed. Each filter was soaked in 50mM TrisHClr pH 7.4 containing 150mH NaCl, 1% gelatin and 1% Tween 20 (IM-1) for 1 hr and then in 50mM Trfs-HCl, pH 7.4 containing 150 0.5H EDTA, 1% Tween 20 (IM-2) for 45 min. mM NaCl, 0.25% gelatin, Filters were then placed in IM-2 with 5% bovine serum and 25~1 of anti-BCKD IgG per 10 ml for 1 hr. After washing 3 X 10 mfn with IM-2, the filters were placed in IM-2 plus 5% bovine serum and 3 962
Vol.
131,
No. 2, 1985
BlOCHEMlCALANDBlOPHYSlCALRESEARCHCOMMUNlCATlONS
ul/lO ml goat antlrabbit IgG-peroxidase CBio-Radl for 45 min. Filters were washed 3 X 10 min with IM-2 prfor to stalning in filtered solution of 5OmM Trls-HClr pH 7.5 containing 0.3mg When the color diaminobenzidine/ml and 0.2ul/ml of 50% H202. fully developed (S-60 min), the filters were washed in deionized water and dried. This staining procedure gave lower background than using radiolabel detection. Plaques producing antlgenic fusion proteins were selected for subsequent rounds using the large bore of a sterile Pasteur pipette. Plaque number/plate reduced 10 fold for each successive round of screening beginning at 400,00O/plate down to 4O/plate.
a was
was
Selar;j&2n Qf E2 dQnas: To Select the clone for the E2 protein, plaques were grown as before and the protein production induced with IPTG impregnated nitrocellulose filters. Filters were exposed to the polyclonal BCKD-IgG for 1 hr. Unbound antibodies were washed from the filters and specifically bound antibodies eluted with 5mH glycine-HCl, pH 2.3, contalnlng 15OmM NaCl, 0.5% Triton X-100, and 100 ug BSA/ml. Washes were immediately neutralized with 1M Tris-HCl to a pH of 7.4. Eluted antibodies were used for Western blot analysis (5) of either purlfied BCKD or mitochondrial proteins. A similar procedure has been reported for the identification of the glucocordicoid receptor gene (10).
Initial positive
plaques
through all
six
were
were after
third
tested
and
of
rounds positive
expanslon. final
2.8
found
successive
plaques
positive the
screening
X
which of
for
round
recombinant
five
phage
each
Figure (6th)
lo6
of 1
of
continued selection.
five shows
selection
phage. positive At
clones stained for
Seven
and
this
remained
filters clone
point,
from 58.
Figure 1: Nltrocellulose fllters stalned with dlamlnobenzldtne as described for Western blot analysts In Methods. Left side shows the third selectlon round at a density of 4000 plaques/plate. Right side shows the final selectlon round with all plaques staining posltlve for antlgenic fusion protetn. Data is for clone 58. 963
Vol.
131,
No.
2, 1985
BIOCHEMICALAND
BIOPHYSICALRESEARCH
COMMUNICATIONS
Figure 2: Western blot of fusion protein from the five positive clones. The two outside lanes are molecular weight markers. The flve middle lanes represent fusion protein from clones 6, 58, 5A, 4 and 3 readtng left to rtght. Arrow Indtcates the posltion of 8galactosldase.
To
estimate
production these
the
of
an
clones
IPTG plates
2
hr
into
of
In
Xgtll
a
control
procedure
which were
BCKD
library
was and
from coli
with
to
antigenic
In
a
7.5% blot
identified
BNN97
kDa
by
(figure
which
the
product
single
Western
200
through
2mM
from
proteins 180
by a
washed
sulfate.
strain
carried
no
plaques
resolved
single
ranging E.
production
lauryl
revealed
antisera of
used
the
complex
selectively exposed
and
the
protein
were
buffer
substantiate
contains
induction was
detected
shown).
subunits the
the
sodium
sizes
analysis
Polyclonal
of
sample
products
and
fusion
proteins
containing
the
insert
overlaying
experiment
and not
four
(11)
with
without
(Data
Induced
these
BCKD-antibodies 2).
37'.
Laemmli
cDNA
product, by
gel
analysis
the
induced at
polyacrylamide
of
antigenic
was
for
size
BCKD
to
complex.
these bound resolved
for
To
fusion the mouse
clonal
proteins
fusion
proteins mltochondrial 964
selection
recognized
establish
which
represent, from proteins
all
proteins antibodies
clones
3 in
and a
58
Vol. 131, No. 2, 1985
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
w-=
Western blot of mouse liver mftochondrfa reacted with antf odfes selectively eluted from nftrocellulose filters containing fusion protein. Left lane represents antfbodfes from lane represents the analysis with polyclonal clone 3, middle antisera and the right lane represents antibodies eluted from clone 58.
Western
blot
staining
analysis.
patterns
Figure
3 shows
complex
or
assay
with the
human
with
the
patterns
polyclonal
selected
Similar
E2 protein.
Staining
antisera
antibodies
results
were
were
mitochondrfal
on
obtained
eluted
the
same
recognize
proteins
specifically
compared
the
the
purified
tested
antibodies
filter.
exclusively
when were
to
BCKD
by this
(data
not
shown).
Rl.ssassinn Reduced severe
activity
pathologic
Causative
genetic
questions
also
multienzyme has
been
directed
of condition,
remain
to
the
BCKD complex maple
alterations
complexes proposed
the
remain
regarding entirely
whereby inner
syrup to
from
be
of 965
of
nuclear made
humans
urine
assembly
proteins
membrane
in
results
disease.
described.
Basic
mitochondrial genes.
in
mitochondria
in
the
A mechanism
cytosol by
are
N-terminal
a
Vol. 131, No. 2, 1985
leader for
BIOCHEMICAL
sequences
(12,13).
lipoamide
unique transcripts
of for
we demonstrate
This
cDNA
from
the
c-terminal
a molecular
large
enough
insert
would
to
analysis.
two
of
pub1 ication from
disease,
Taken
together,
we
subunits
coded,
of
no
El.
dehydrogenase on
the
(figure
data
In
in El
of
precursor
transcripts
El
Western
were
present
the
B subunits
independent
appears
from
each
syrup
were that
E2
present. is
independent for
describing
it
in
E2 protein maple
transcript
reports
(14,15).
the
with
translated
the
If
by the
a hypothesis
the
kDa. component
of
a patient
a and
on
be
a previous
absence
support
must
one
In
basepair
cDNA 90
than
3).
cytosolically
view
to
53
2).
CEC 3.2.1.231
E2 protein
the
information
Da(Figure gene
80
more
for
E3,
200,000
antigenically
proteins
these
have
detected
the
membrane.
inserted of
we demonstrated
while
a nuclear
the
from
clones
ca
that
individual
B-galactosidase
116,000,
epitopes
mltochondrial
urine
made
a polypeptide
(51,
the
As yet
encode
isolated
from
of
described
suggests
mitochondrial
Since
peptides
data
been
B-galactosidase
of
Only
the
the
(6).
be
the
protein
weight
would
Our
in
in
end
contain
these
blot
as
resides
has
synthesized
assembly a fusion
library
has
be
RESEARCH COMMUNICATIONS
precursor
(14,151.
BCKD may
later
Here
protein,
A larger
dehydrogenase
proteins
AND BIOPHYSICAL
made
protein. the
~1 or
8
lipoamide
that
E3 and
other
and
E2 are
distinct
from
El. Availability containing study
of mutations
both
diesase
and
multienzyme
the the
and
for
biochemical
Sells
in
S.L.C. for
the
and BCKD
resulting
reactions
human
fibroblasts
proteins
allows
us
in
syrup
urine
involved
maple in
the
assembly
to
of
mitochondria.
We thank Dr.
clone,
mechanism
complexes
help, Susan
E2-cDNA
specific
genetic
&Kng.whdw: their
this
Drs. Woo
manuscript
E.I. for
sharing
preparation.
Ginns the
6 J.A. Xgtll
Barranger cDNA
for library
Vol. 131,No.
1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
2, 1985
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Dannet-, D. J. and Elsas, L.J. (1975) Biochem. Med. 1l 7-22. Rosenberg, L.E. and Striver, C.R. (1980) In wMetabolic control and disease” Ed. by P.K. Bondy and L.E. Rosenberg, Philadelphia, pp. 691-699. W.B. Saunders, Heffelfinger, S.C., Sewell, E.T. and Danner, D.J. (1983) Biochemistry 22, 5519-5522. Cook, K.G., Bradford, A.P., and Yeaman, S.J. (1984) Eur. J. Biochem. J& 587-591. Danner, D.J., Armstrong, N., Heffelfinger, S.C., Sewell, Priest, J.H., and Elsas, L.J. (1985) J. Clin. Invest. &:*;158-860. Young, R.A. and Davis, R.W. (1983) Proc. Natl. Acad. Sci. USA BQ, 1194-1198. R.A. and Davis, R.W. (1983) Science 222, 778-782. Young, Heffelfinger, S.C., Sewell, E.T., and Danner, D.J. (1983) Biochem. J. Uz 339-344. deWet, J.R., Fukushima, H., Dewji, N.N., Wilcox, E., O’Brien, J.S. and Helinski, D.R. (1984) DNA 1, 437-447. Weinberger, C.# Hollenberg, S.M.D Ong, E.S., Harmon, J.M., Brower, S.T., Cldlowski, J.# Thompson, E.B., Rosenfeld, M.G., Evans, R.M. (1985) Science 228, 740-742. Laemmli, U. (1970) Nature 221, 680-685. Felipo, V. and Grisolla, S. (1984) Curr. Top. Cell. Reg. 21, 217-249. Hay, R., Bohni, P. and Gasser, S. (1984) Biochim. Blophys. Acta lzPI 65-07. Koike, K., Tsuji, A., Urata, Y., Morlyasu, M.* and Koike, M. pp B03-806rEd. by R.C. (1984) In Elnuins an9 fln~nprn~a~~ Bray, P.C., W. de Gruyter 8 Co., New York. Matuda, S., Shirahama, T., Saheki, T., Miura, S. and Mori, M. (1983) Biochim. Biophys. Acta 141, 86-93.
967