- Email: [email protected]
Identification of the promoter region and gene expression for human acid alpha glucosidase
Vol.
176,
No.
May
15, 1991
BtOCHEMlCAL
3, 1991
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages
Stephanie
Tzall
1509-1515
and Fmnk Ma?&niuk*
New York University Medical Center, hparbent of Medicine 550 First Avenue, New York, NY 10016 Received
March
20,
1991
SUMMARY: Genetic deficiency of acid alpha gluaxsidase (GAA) results in glycogen storage disease type II. A CCNA containing the complete coding region was constructedandcloned intotheexpxessionvector@V2 andwastransiently transfected into an sV40 imortalized CAA deficient hmen fibrcblast cell line which has undetectable levels of CAA enzyme activity and does not express GAA mFuK Transfected cells had 4.9% of normal human fibmblast enzyme activity. Additionally a 5' 1.8 kb genomic fragment was ligated to the 5' end of the GAA cDNA construct and cloned into pUC19. Transient and stable transfection also resulted in expressed GAA enzyme activity in deficient fibroblast cells, indicating that the gentic fragment has GAA p?xxnoter function. 0 1991 Rcademlc Press,
1°C.
Acid alpha glucosidase enzyme that
hydrolyzes
GAA, glyccgen that
varies
slowly
storage
or acid maltase
glycqen disease
from a rapidly
progressive
to yield type II,
fatal
glucose
infantile
of enzyme activity,
accmulation
of glycogen
in
tissues.
In the adult
is limited
to skeletal
to residual with antibody,
enzym
muscle (2-6). activity,
and abnornkalities
We have previously human GAA (16,17) genetic
onset form, enzyme activity
cloned
presence
Cells
abnormlitiesofnif@JAardDN?+.
weakness,
muscle is variable
of
disease
and mssive
as well
as other
and involvement
frompatientsareheterogenecusas
or absence 0fproteincmssIeacting
of post-translational and detemnimd
the
and have used the cDJA to deteznune
heterogeneity
deficiency
form is characterized
muscle
and skeletal
Genetic
(Pcanpe's di sease)toa
The infantile
low levels
is a lysosomal
heterogeneous
disorder
by extremly
cardiac
(1).
is a clinically
onset myopathy.
adult
(GAA) (JZC 3.2.1.3)
among GAA deficient
patients
Approximatelyhalfof
p recessing
(7-15).
sequence of the &&JA for that
there
is extensive
as detected
by gross
infantileonsetpatimts
*Towhomallcorreqmx&anceshouldbeaddressed. 0006-291x/91
$1.50
Vol.
176,
lack
No.
3, 1991
BIOCHEMICAL
GM mRNA, while
and/or
amounts
(18,19).
been determined, junctions
many adult
(20).
AND
BIOPHYSICAL
onset patients
The organization
including
the
Tenrestriction
nu&er
RESEARCH
exhibit
mR?A of altered
of the stmctuml and sizes
of
COMMUNICATIONS
gene for GAA has
exons and intron-exon
fra~tleqthpolymorpkisms
have been
identified
(16,21-24).
determined
(17,25).
This
hcxnologyto
Splbindingsites,
(RFLPS) forGAA
The sequence
region
contains
size
5'
several
butnoC.AATorTATAbox
to
exon
GC rich
1 has been regions
with
(17).
Wehavenawconstructedafulllengthcodingregionc~clonedinthe expressionvectorpSV2 brtalized levels
andusedthisplasnidto
GAA deficient
human fibmblastcell
of GAA enzyme activity
region,weisolatedagenomic contains
a GC rich
genrnnic fragment
construct
line
and no mRNA. To grossly
region
site
transiently
including
at least
localize
to the polyadenylation and stably
expressed
site
the pmnnoter 5' -which
two Spl birding
onto the 5' end of the full
ansV40
which has undetectable
fragmentthatincludedexononeand
was ligated
frnn the A'II; start
tmnsientlytransfect
length
sites.
coding region
and the poly A tail.
GAA enzyme activity
This
This
in deficient
cells.
RNA, INA and cell
lines
F@?A, cDNA and genomic CNA were isolated or synthesized as described Amplification and purification of plasmid constructs and previously (17). Southern and Northern analysis were done by ~TAx&xI nukhcds (26). Norml fibroblastcell line GM5758 and normal lyqhoid cell line GM3202 wereusedas controls in Southern andNorthern analyses. Recipient cells for transfection were an SV40 immortalized human fibmblast cell line @I4912 (an infantile onset patient; NIH Human Genetic Mutant Cell Repository, Garden, NJ) which exhibited no enzyme activity for GAA and no GAA mRNA. The cell line was utilized for transfection experiments at passages Tll to T95. DNA-mediated
transformation
and enzyme assay
SV40 immortalized hunan fibroblast cell line GM4912 was transiently transfected as previously described (27). Briefly, cells were plated at 0.4 X lo6 cells/lOOrm~ petri dish 24 hours before addition of DNA. Calcium @osphate was carried out with plasmids precipitated transient gene expression containing constructs in either forward or reverse orientation (40 micmgrams per petri dish) by the method of Graham and van der Eb (28) as modified by washedaMias.sayed Wigler et al. (29). After 48 hours, cellswereharvested, for GAA activity using the artificial substrate 4-methyl~lliferyl-alpha-Dglucoside as previously described (30). GAA expression was also visualized by starch gel electrophoresis followed by staining for GAA (30). Stable cotransformation was carried out as previously described (31) with l-2 1510
Vol.
176,
No.
BIOCHEMICAL
3, 1991
microgranspm-~ with the nemycin
AND
BIOPHYSICAL
and 40 mkrqram ofplamid, analog G-418 (Geneticin
Constructionofthe
RESEARCH
COMMUNICATIONS
amlthe~genewas
selected
fulllenothccdimregionclXA
AcDNAcontainingthecmpletemding regionwasconstructed by ligating a 3.2 kb cDNA fragmnt digested at an S&II site (bp 318) aMi an S@iI site in the 3' non-coding region (bp 3150) to a 0.45 kb 5' fragmant digested with NcoI at the AT3 start site (bp 1) and with SstII (bp 318) (17). -11 linkers were added and the construct cloned into lzUC18. The axxstruct was resequd by the Sanger dideoq chain termination method (32) through the 5' NcoI site, and the SstII restriction site, all of whi& wexe the ATG start signal, Theconstructwas recloned intotheSV4O+as&expressionvector, lrlaintained. pSV2 (gift of Dr. S. H. Orkin.) and named GAA-pSV2-forward. As a control, the insert was also ligated in the reverse orientation (GAA-pSK+reverse). Isolation
of the promoter
r&on
and liaation
onto the c&ins
reuion
In order to grossly locate the promter region, we isolated a 1.8 kb XhoI/AatII genmic fragmentwhichcontainedthe St untranslated186bpe.xon1, plus an additional 5' 1.5 kb segment. AfteradditionofHiMIII linkers, this fragmnt was ligated to the ATG start site on the 5' end of the full length GAA cDNA including the poly (A) addition site and poly (A) tail, and cloned into plJcl9 (GAA-pmter-forward). As a control, the reverse orientation was also isolated (GAA-promoter-reverse).
Cells
transiently
(0.11 U/g)
transfectd
of norm1 fibroblast
with
the GAA-@V2-forward
activity
(2.26 U/g),
with the GAA-pSV2-reverse showed no detectable to
determine
electrophoresed
activityby
if
the &acts
staining
increase
in GAA enzyme activity
of transfected asdescribed
activity
cells
inmaterials
on star&
while cells (Table 1).
o.ll+o.o7(n=11)
GAA-psv2-met-se
< 0.003
GAA-Pmmote~Fomanl
0.040 0.018
GAA-hnmoter-Rarerse
< 0.003
Normal fibmblast
Ql 08399
(u=5)
Eqmassionofthe
2.2eO.25 (~4)
a pies of 4-methyl~lliferyl-alFSla-Dglucoside hydrolyzed/min/g protein at 37OC_+SD. 1511
% Nomel 4.9 < 0.0 1.8 1.2
0-1
In order
gel armdvisualized
Table 1. Transient Ekpression 0fGAA in sV40 linmrtalized HmanGAAtkficient Fibroblasts
GA?+-W-Forward
transfected
was indeed GAA, we
andmethods.
EZmymeActivitya
cC@?Ahad 4.9%
< 0.0 100.0
GAA
Vol.
176,
No.
BIOCHEMICAL
3, 1991
GAA-pSV2-forward could
be visualized
cmigratingwiththeextracts
GAA-promoter-forward
cm
reverse cDNAconstruct further
replicated
nemycin
with
the next
1.5
U/g
fibroblasts no&
E'coFU and HiMI
gencm follow&
were
1). stable
gene
picked
into
were assay&
lA).
by Northern
equal tothatseen
activities
for
(W)
with
These levels cells
e.
GAA
appeared
DJA from this
and was
colony rang&i
as observed
were in the rarqe
The
to be stable
of this
confluemcy,
(0.7-2.0
The colony
to keunstablewithtime.
The enzyme activity
frcan
with
normal
of enzyme activity
frcm
U/g).
colony
(W) seven days @passage.
of copies of the plasmid (releasing
analysis.
(Fig.
These colonies
activity
increased
fibroblast
the nmber
by Southern
highest
which
We next extracted estimated
M-pm
(Table
colonies
(ES) appear&
analysis.
(13).
control
the
we utilized
resistant
with the highest
enzyme activity
expanded for further to
activity
with the
u/g) of normal
(0.03 with
region,
plates.
and the four colonies
colony
1.5%
kansfected
promotor
transfect&
in~t~ialsandmethods.?heenzymeactivityperwlony
with the highest
0.5
the
microtiter
activityasdescribed varied
cells
as a band
(not shown).
transiently
showed nodeteckableenzym
analyze
24-well
cells
COMMUNICATIONS
gel electrcphoresis
exhibited
while
RESEARCH
fibrublasts
construct
Twenty-four
expression.
by starch
GAA deficient
enzyme activity,
To
BIOPHYSICAL
frmnorml
SV40 immortalized
fibrcblast
AND
the coding
in this
region)
We
colony by digestion
or with FmRI
alone,
with
follmed
~~wereapproximatelyfivetotencapiespresentper We additionally analysis.
estimated
ccpy nuker
GAA nWNA was of normal
fromanormalfibroblastcellline
by mRNA isolation
size and approximately (Fig.
US).
DISUJSSION
Wehavepreviouslydeteminedthe GAA and identified sequeme
ad
an intron
demonstrated
deficient
that
transient
human fibroblast
the coding gene cell
fortheccdingregionofhman
separates
from the second exon containing We have now ligated
(17).
sequeme
the
the initiation region
into
expression
in
line
as detected 1512
5'
untranslated
leader
of translation
the expmion
(AYE)
vector
an SV40 innmrtalized by an increase
pSV2 GAA
in enzyme
Vol.
176,
No.
BIOCHEMICAL
3, 1991
AND
BIOPHYSICAL
RESEARCH
-23
COMMUNICATIONS
B
- 9.6
- 6.6 -44 -23 1234667
3
2
1
Fiu. 1 A Scuthexn analysis of gencmic DNA from the stable cotransfonnantD6 prabe utilized for to estimate the GAA-promter-forward copy rumba. hybridizationwas theGAAccdingr@on. Lam 1: CNA frmnomal fitmblast Lanes 2 and 3: CNA frm stable cell line (CN5758) digested with EcoRI. u&.ransfomantD6digestedwithEccRI inlane 2, aMwithhalftheCNAinlane 3. Digestion with EccRI n&es a siqle cut at the 3' end of the plaanidconstict. Onemjor site of integrationcanbe seenas averydensebamlof approximately 9 kb. Lane4:DNAfnmnormalfibrcblastoelllinedigested with EcaRI a& Hi&III. Lanes 5,6 and 7: DNAfmn stable cotzamformantD6 digffi~witi EknRI andHindII1 in lane 5, with lanes 6 a& 7 1:lti 1:4 dilutions of lane 5. AnEcoFU/Hi.rSUII digestion releasesthe czdim~regian, seenasaverydensebandatapproximtely3 kb, dermnsbattingasinglemajor site of integration. We estimtethatthexeare approximtely five to ten copies inthisbard. analysis of URNA fztm stable cmtransf0rmarrtD6~rlc& Ficr. 1 B Northern Probe utilized for hybridization was the GAA coding region. Iane cell lines. lmhoid cell line (GN3202). lane 2: mRliA fran norml 1: mRNA frm normal fibmblast cell line (CN5758). Iane3:MNAfrmstable cotransformantD6. Hybridization for all samples was to the sqazcbd 3.6kbGAAbarL Theanmunt 0fmRNA fromD6 (Iane 3) wasapproximtelyequal tothatfmnthenoxmal fibroblastline (lane 2). activity
5% of normal)
(approximately
starch
and visualization
We tested the deficient
gel.
humm cell
by el~oresis
line
for its
in
ability
to take
up at-d express the &g gene, alX3wefouIXIthatthiscelllinetakesupand qresses
DNA approximately
(unpublished obsemation).
one fifth
to one tenth
merefore
that
of muse 3T3 cells
the apparentlmlevelof
qression
is
a functionofthehostcellline. We have also demnstrated
that
with a GC rich area and at least&o TheGAAprcmoterresulted
of transcription,
analysis
fragment 5' to axon 1
SplbimIir~~siteshaspzmmter
function.
inlowertransientgeneexpzessionccprcparedtothe
This may be due to the akseme of the 32 bp 58 of the An; start
P=P-ter. site
a 1.8 kb genmic
of
stable
which was not cotransformants
inclukd
reveald
copies per gencme were presentatonemajor enzyme activity
qua1 to that
obseme the expect&
ratio
okerved
in the construct. that
approximately
integration
site,
in normal fibroblasts.
However, five
to ten
with express& We did not
of estimated mpy number versus expressed enzym 1513
Vol.
176,
level,
No.
BIOCHEMICAL
3. 1991
that
is,
f&&lasts.
AND
we did not observe expression This
would suggest
that
prcsnoter sequences but my be lacking for
the
interest, activity (13).
higher the with
Thismay
or that nongenetic
the
enzyme activity stable
that
the
obsexved
RESEARCH
five
in
with
will
in
GAA specific
activity
When the regulatory
that
of the nomal
fragment
does contain
fibrcblast
cell
increase
in
nornbal fibroblast
irdicatethatsomeregulatoryorenhaxer increase
COMMUNICATIONS
or -elementsneeded
showed the
is observed
times
gerxxnic
regulatory
cotransfomant
confluency
factors.
these questions
BIOPHYSICAL
lines.
Of
GAA specific cell
lines
elertentsampresent with
or enhaxer
confluency
elements
is due to
am identified,
be answered.
This resxlmhwas supportedbythefollowinggrants:MuscularDystmphy Association, American Heart Association #870992, and NIH Grant ROI 39669. WewculdliketothankDr.Angel was a fellow of the Arthritis Foun3ation. Fellicer for his fruitful discussions.
ST
1. Hers, H.G. (1963) Biochem. J. 86,11-16. 2. Pcanpe, J: C. (1932) Ned. Tijdschr. Gemrskd. 76,304-311. 3. Courteclussf, v., Royer F., Habib, R., Monnifer, C., and Denvos, J. (1965) Arch. Franc. Fediat. 22,1153-1164. 4. EM@, A. G., Gomz, M. R., Seybold, M. E., and La&x-t, E. H. (1973) Neurology 23,95-106. 5. M&le.r, M., and Di Mauro, S. (1977) Neurology 27,178-184. 6. H&s, H.G., vanHoof, F., and deBamy, T. (1989) In The Metabolic Basis of Inherited Disease (C.R. Striver, A.L. Beaudet, W. Sly, and D. Valle, Eds.). Vol.1, pp. 425-452. McXraw-Hill, New York. 7. Beratis, N.G., IaBadie, G.U., and Him&horn, K. (1978) J. Clin. Invest. 62,1264-1274. 8. Beratis, N.G., La&die, G.U., and Him&horn, K. (1983) Am. J. Hus.Genet. 35,21-33. 9. Brown, B. I., and Brown, D. H. (1965) Bicchim. Biophys. Acta. 110,124-133. 10. Hasilik, A., and Neufeld, E. F. J. Biol. Chem. (1980) 255,4937-4945. 11. Komfeld, S. (1986) J. Clin. Invest. 77,1-6. 12. LaBadie, G. U., Harris, H., Beratis, N. G., and Him&horn, K. (1985) Am. J. Mrm. Genet. (1985) 37,Al2 (abstract). 13. LaBadie, G.U. (1986) Ph.D. Thesis, City University of New York, Mt. Sinai Hospital. 14. Reuser, A. J. J., Kroos, M., Cude Elferink, R. P. J., and Tager, J. M. J. (1985) Biol. Chem. 260,8336-8341. 15. Reuser, A. J. J., Kroos, M., Williamson, R., Swallow, D., Tager, J. M., at-d Galjaard, H. (1987) J. Clin. Invest. 79,1689-1699. 16. !Qrtiniuk, F., M&&r, M., Pellicer, A., Tzall, S., IaBadie, G. U., Ellenbqen, A., and Hirschhom, R. (1986) Proc. NatI. Acad. Sci. USA 83,9641-9644. 17. Martiniuk, F., M&&r, M., Tzall, S., Meredith, G., and Him&horn, R. (1990) DNA and Cell Bio. 9‘85-94. 18. Martiniuk, F., Mehler, M., Tzall, S., Meredith, G., and Hir?XhhOm, R. (1990) Am. J. H\rm. mt. 47,73-78. 1514
Vol.
176,
No.
3, 1991
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
19. van der Ploeg, A.T. Hcefslot, L.H., Hoogeveen-Westeweld, M., Petersen, (1989) Am. J. Hum. Genet. 44,787-793. E.M., and Reuser, A.J.J. 20. Martiniuk, F., Bodkin, M., Tzall, S., and I3irs&hom, R. (1991) r%lA ti Cell Biolcgy, In press. 21. Tzall, s., Martiniuk, F., Adler, A., and Hire&horn, R. (1990) Nut. Acids Res. 18,1661. R. (1990) Nut. Acids Res. 22. Tzall, S., Martiniuk, F., and Hirwhhom, 18,193O. 23. Tzall, S., Martiniuk, F., Ozelius, L., Gusella, J., and Hire&horn, R. (1991) Nut. Acids Res. In press. 24. Tzall, S., Martiniuk, F., and Hirschhorn, R. (1991) Nut. Acids Res. In press. 25. Hcefsloot, L-H., Hcogeveen-Westerveld, M., Kmos, M., van Beeumen, J., Reuser, A.J.J., and Oostra, B.A. (1988) EM83 J. 7,1697-1704. 26. Sambrook, J., Fritsch, E.F, and Maniatis, T. (1989) Molecular Clonirq: A UbxatoryManual. ColdSpringHarborLabxatory Press, ColdSpring Harbor,NY. 27. Martiniuk, F., Bodkin, M., Tzall, S., at-d HiE&hOm, R. (1990) Am. J. M. Genet. 47,440-445. 28. Graham, F.L., and van der Eb, A.J. (1973) Virology 52,456-467. 29. Wigler, M., Pellicer, A., Silverstein, S., and &el, R. (1978) -11 14,725-731. 30. Martiniuk, F., and Hirschhom, R. (1981) Biochim. Bisphys. Acta. 658,248-261. 31. %X+kl.iUk, F., PelliCer, A., Mehhr, M. and Hi.rs&hom, R. (1986) SopMtic Cell and Mol. Gal&. 12,1-12. 32. Sanqer, F., Nicklen, S. and Coulson, A.R. Prcc. Natl. Acad. Sci., uSA (1977) 74,5463-5468.
1515
176,
No.
May
15, 1991
BtOCHEMlCAL
3, 1991
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages
Stephanie
Tzall
1509-1515
and Fmnk Ma?&niuk*
New York University Medical Center, hparbent of Medicine 550 First Avenue, New York, NY 10016 Received
March
20,
1991
SUMMARY: Genetic deficiency of acid alpha gluaxsidase (GAA) results in glycogen storage disease type II. A CCNA containing the complete coding region was constructedandcloned intotheexpxessionvector@V2 andwastransiently transfected into an sV40 imortalized CAA deficient hmen fibrcblast cell line which has undetectable levels of CAA enzyme activity and does not express GAA mFuK Transfected cells had 4.9% of normal human fibmblast enzyme activity. Additionally a 5' 1.8 kb genomic fragment was ligated to the 5' end of the GAA cDNA construct and cloned into pUC19. Transient and stable transfection also resulted in expressed GAA enzyme activity in deficient fibroblast cells, indicating that the gentic fragment has GAA p?xxnoter function. 0 1991 Rcademlc Press,
1°C.
Acid alpha glucosidase enzyme that
hydrolyzes
GAA, glyccgen that
varies
slowly
storage
or acid maltase
glycqen disease
from a rapidly
progressive
to yield type II,
fatal
glucose
infantile
of enzyme activity,
accmulation
of glycogen
in
tissues.
In the adult
is limited
to skeletal
to residual with antibody,
enzym
muscle (2-6). activity,
and abnornkalities
We have previously human GAA (16,17) genetic
onset form, enzyme activity
cloned
presence
Cells
abnormlitiesofnif@JAardDN?+.
weakness,
muscle is variable
of
disease
and mssive
as well
as other
and involvement
frompatientsareheterogenecusas
or absence 0fproteincmssIeacting
of post-translational and detemnimd
the
and have used the cDJA to deteznune
heterogeneity
deficiency
form is characterized
muscle
and skeletal
Genetic
(Pcanpe's di sease)toa
The infantile
low levels
is a lysosomal
heterogeneous
disorder
by extremly
cardiac
(1).
is a clinically
onset myopathy.
adult
(GAA) (JZC 3.2.1.3)
among GAA deficient
patients
Approximatelyhalfof
p recessing
(7-15).
sequence of the &&JA for that
there
is extensive
as detected
by gross
infantileonsetpatimts
*Towhomallcorreqmx&anceshouldbeaddressed. 0006-291x/91
$1.50
Vol.
176,
lack
No.
3, 1991
BIOCHEMICAL
GM mRNA, while
and/or
amounts
(18,19).
been determined, junctions
many adult
(20).
AND
BIOPHYSICAL
onset patients
The organization
including
the
Tenrestriction
nu&er
RESEARCH
exhibit
mR?A of altered
of the stmctuml and sizes
of
COMMUNICATIONS
gene for GAA has
exons and intron-exon
fra~tleqthpolymorpkisms
have been
identified
(16,21-24).
determined
(17,25).
This
hcxnologyto
Splbindingsites,
(RFLPS) forGAA
The sequence
region
contains
size
5'
several
butnoC.AATorTATAbox
to
exon
GC rich
1 has been regions
with
(17).
Wehavenawconstructedafulllengthcodingregionc~clonedinthe expressionvectorpSV2 brtalized levels
andusedthisplasnidto
GAA deficient
human fibmblastcell
of GAA enzyme activity
region,weisolatedagenomic contains
a GC rich
genrnnic fragment
construct
line
and no mRNA. To grossly
region
site
transiently
including
at least
localize
to the polyadenylation and stably
expressed
site
the pmnnoter 5' -which
two Spl birding
onto the 5' end of the full
ansV40
which has undetectable
fragmentthatincludedexononeand
was ligated
frnn the A'II; start
tmnsientlytransfect
length
sites.
coding region
and the poly A tail.
GAA enzyme activity
This
This
in deficient
cells.
RNA, INA and cell
lines
F@?A, cDNA and genomic CNA were isolated or synthesized as described Amplification and purification of plasmid constructs and previously (17). Southern and Northern analysis were done by ~TAx&xI nukhcds (26). Norml fibroblastcell line GM5758 and normal lyqhoid cell line GM3202 wereusedas controls in Southern andNorthern analyses. Recipient cells for transfection were an SV40 immortalized human fibmblast cell line @I4912 (an infantile onset patient; NIH Human Genetic Mutant Cell Repository, Garden, NJ) which exhibited no enzyme activity for GAA and no GAA mRNA. The cell line was utilized for transfection experiments at passages Tll to T95. DNA-mediated
transformation
and enzyme assay
SV40 immortalized hunan fibroblast cell line GM4912 was transiently transfected as previously described (27). Briefly, cells were plated at 0.4 X lo6 cells/lOOrm~ petri dish 24 hours before addition of DNA. Calcium @osphate was carried out with plasmids precipitated transient gene expression containing constructs in either forward or reverse orientation (40 micmgrams per petri dish) by the method of Graham and van der Eb (28) as modified by washedaMias.sayed Wigler et al. (29). After 48 hours, cellswereharvested, for GAA activity using the artificial substrate 4-methyl~lliferyl-alpha-Dglucoside as previously described (30). GAA expression was also visualized by starch gel electrophoresis followed by staining for GAA (30). Stable cotransformation was carried out as previously described (31) with l-2 1510
Vol.
176,
No.
BIOCHEMICAL
3, 1991
microgranspm-~ with the nemycin
AND
BIOPHYSICAL
and 40 mkrqram ofplamid, analog G-418 (Geneticin
Constructionofthe
RESEARCH
COMMUNICATIONS
amlthe~genewas
selected
fulllenothccdimregionclXA
AcDNAcontainingthecmpletemding regionwasconstructed by ligating a 3.2 kb cDNA fragmnt digested at an S&II site (bp 318) aMi an S@iI site in the 3' non-coding region (bp 3150) to a 0.45 kb 5' fragmant digested with NcoI at the AT3 start site (bp 1) and with SstII (bp 318) (17). -11 linkers were added and the construct cloned into lzUC18. The axxstruct was resequd by the Sanger dideoq chain termination method (32) through the 5' NcoI site, and the SstII restriction site, all of whi& wexe the ATG start signal, Theconstructwas recloned intotheSV4O+as&expressionvector, lrlaintained. pSV2 (gift of Dr. S. H. Orkin.) and named GAA-pSV2-forward. As a control, the insert was also ligated in the reverse orientation (GAA-pSK+reverse). Isolation
of the promoter
r&on
and liaation
onto the c&ins
reuion
In order to grossly locate the promter region, we isolated a 1.8 kb XhoI/AatII genmic fragmentwhichcontainedthe St untranslated186bpe.xon1, plus an additional 5' 1.5 kb segment. AfteradditionofHiMIII linkers, this fragmnt was ligated to the ATG start site on the 5' end of the full length GAA cDNA including the poly (A) addition site and poly (A) tail, and cloned into plJcl9 (GAA-pmter-forward). As a control, the reverse orientation was also isolated (GAA-promoter-reverse).
Cells
transiently
(0.11 U/g)
transfectd
of norm1 fibroblast
with
the GAA-@V2-forward
activity
(2.26 U/g),
with the GAA-pSV2-reverse showed no detectable to
determine
electrophoresed
activityby
if
the &acts
staining
increase
in GAA enzyme activity
of transfected asdescribed
activity
cells
inmaterials
on star&
while cells (Table 1).
o.ll+o.o7(n=11)
GAA-psv2-met-se
< 0.003
GAA-Pmmote~Fomanl
0.040 0.018
GAA-hnmoter-Rarerse
< 0.003
Normal fibmblast
Ql 08399
(u=5)
Eqmassionofthe
2.2eO.25 (~4)
a pies of 4-methyl~lliferyl-alFSla-Dglucoside hydrolyzed/min/g protein at 37OC_+SD. 1511
% Nomel 4.9 < 0.0 1.8 1.2
0-1
In order
gel armdvisualized
Table 1. Transient Ekpression 0fGAA in sV40 linmrtalized HmanGAAtkficient Fibroblasts
GA?+-W-Forward
transfected
was indeed GAA, we
andmethods.
EZmymeActivitya
cC@?Ahad 4.9%
< 0.0 100.0
GAA
Vol.
176,
No.
BIOCHEMICAL
3, 1991
GAA-pSV2-forward could
be visualized
cmigratingwiththeextracts
GAA-promoter-forward
cm
reverse cDNAconstruct further
replicated
nemycin
with
the next
1.5
U/g
fibroblasts no&
E'coFU and HiMI
gencm follow&
were
1). stable
gene
picked
into
were assay&
lA).
by Northern
equal tothatseen
activities
for
(W)
with
These levels cells
e.
GAA
appeared
DJA from this
and was
colony rang&i
as observed
were in the rarqe
The
to be stable
of this
confluemcy,
(0.7-2.0
The colony
to keunstablewithtime.
The enzyme activity
frcan
with
normal
of enzyme activity
frcm
U/g).
colony
(W) seven days @passage.
of copies of the plasmid (releasing
analysis.
(Fig.
These colonies
activity
increased
fibroblast
the nmber
by Southern
highest
which
We next extracted estimated
M-pm
(Table
colonies
(ES) appear&
analysis.
(13).
control
the
we utilized
resistant
with the highest
enzyme activity
expanded for further to
activity
with the
u/g) of normal
(0.03 with
region,
plates.
and the four colonies
colony
1.5%
kansfected
promotor
transfect&
in~t~ialsandmethods.?heenzymeactivityperwlony
with the highest
0.5
the
microtiter
activityasdescribed varied
cells
as a band
(not shown).
transiently
showed nodeteckableenzym
analyze
24-well
cells
COMMUNICATIONS
gel electrcphoresis
exhibited
while
RESEARCH
fibrublasts
construct
Twenty-four
expression.
by starch
GAA deficient
enzyme activity,
To
BIOPHYSICAL
frmnorml
SV40 immortalized
fibrcblast
AND
the coding
in this
region)
We
colony by digestion
or with FmRI
alone,
with
follmed
~~wereapproximatelyfivetotencapiespresentper We additionally analysis.
estimated
ccpy nuker
GAA nWNA was of normal
fromanormalfibroblastcellline
by mRNA isolation
size and approximately (Fig.
US).
DISUJSSION
Wehavepreviouslydeteminedthe GAA and identified sequeme
ad
an intron
demonstrated
deficient
that
transient
human fibroblast
the coding gene cell
fortheccdingregionofhman
separates
from the second exon containing We have now ligated
(17).
sequeme
the
the initiation region
into
expression
in
line
as detected 1512
5'
untranslated
leader
of translation
the expmion
(AYE)
vector
an SV40 innmrtalized by an increase
pSV2 GAA
in enzyme
Vol.
176,
No.
BIOCHEMICAL
3, 1991
AND
BIOPHYSICAL
RESEARCH
-23
COMMUNICATIONS
B
- 9.6
- 6.6 -44 -23 1234667
3
2
1
Fiu. 1 A Scuthexn analysis of gencmic DNA from the stable cotransfonnantD6 prabe utilized for to estimate the GAA-promter-forward copy rumba. hybridizationwas theGAAccdingr@on. Lam 1: CNA frmnomal fitmblast Lanes 2 and 3: CNA frm stable cell line (CN5758) digested with EcoRI. u&.ransfomantD6digestedwithEccRI inlane 2, aMwithhalftheCNAinlane 3. Digestion with EccRI n&es a siqle cut at the 3' end of the plaanidconstict. Onemjor site of integrationcanbe seenas averydensebamlof approximately 9 kb. Lane4:DNAfnmnormalfibrcblastoelllinedigested with EcaRI a& Hi&III. Lanes 5,6 and 7: DNAfmn stable cotzamformantD6 digffi~witi EknRI andHindII1 in lane 5, with lanes 6 a& 7 1:lti 1:4 dilutions of lane 5. AnEcoFU/Hi.rSUII digestion releasesthe czdim~regian, seenasaverydensebandatapproximtely3 kb, dermnsbattingasinglemajor site of integration. We estimtethatthexeare approximtely five to ten copies inthisbard. analysis of URNA fztm stable cmtransf0rmarrtD6~rlc& Ficr. 1 B Northern Probe utilized for hybridization was the GAA coding region. Iane cell lines. lmhoid cell line (GN3202). lane 2: mRliA fran norml 1: mRNA frm normal fibmblast cell line (CN5758). Iane3:MNAfrmstable cotransformantD6. Hybridization for all samples was to the sqazcbd 3.6kbGAAbarL Theanmunt 0fmRNA fromD6 (Iane 3) wasapproximtelyequal tothatfmnthenoxmal fibroblastline (lane 2). activity
5% of normal)
(approximately
starch
and visualization
We tested the deficient
gel.
humm cell
by el~oresis
line
for its
in
ability
to take
up at-d express the &g gene, alX3wefouIXIthatthiscelllinetakesupand qresses
DNA approximately
(unpublished obsemation).
one fifth
to one tenth
merefore
that
of muse 3T3 cells
the apparentlmlevelof
qression
is
a functionofthehostcellline. We have also demnstrated
that
with a GC rich area and at least&o TheGAAprcmoterresulted
of transcription,
analysis
fragment 5' to axon 1
SplbimIir~~siteshaspzmmter
function.
inlowertransientgeneexpzessionccprcparedtothe
This may be due to the akseme of the 32 bp 58 of the An; start
P=P-ter. site
a 1.8 kb genmic
of
stable
which was not cotransformants
inclukd
reveald
copies per gencme were presentatonemajor enzyme activity
qua1 to that
obseme the expect&
ratio
okerved
in the construct. that
approximately
integration
site,
in normal fibroblasts.
However, five
to ten
with express& We did not
of estimated mpy number versus expressed enzym 1513
Vol.
176,
level,
No.
BIOCHEMICAL
3. 1991
that
is,
f&&lasts.
AND
we did not observe expression This
would suggest
that
prcsnoter sequences but my be lacking for
the
interest, activity (13).
higher the with
Thismay
or that nongenetic
the
enzyme activity stable
that
the
obsexved
RESEARCH
five
in
with
will
in
GAA specific
activity
When the regulatory
that
of the nomal
fragment
does contain
fibrcblast
cell
increase
in
nornbal fibroblast
irdicatethatsomeregulatoryorenhaxer increase
COMMUNICATIONS
or -elementsneeded
showed the
is observed
times
gerxxnic
regulatory
cotransfomant
confluency
factors.
these questions
BIOPHYSICAL
lines.
Of
GAA specific cell
lines
elertentsampresent with
or enhaxer
confluency
elements
is due to
am identified,
be answered.
This resxlmhwas supportedbythefollowinggrants:MuscularDystmphy Association, American Heart Association #870992, and NIH Grant ROI 39669. WewculdliketothankDr.Angel was a fellow of the Arthritis Foun3ation. Fellicer for his fruitful discussions.
ST
1. Hers, H.G. (1963) Biochem. J. 86,11-16. 2. Pcanpe, J: C. (1932) Ned. Tijdschr. Gemrskd. 76,304-311. 3. Courteclussf, v., Royer F., Habib, R., Monnifer, C., and Denvos, J. (1965) Arch. Franc. Fediat. 22,1153-1164. 4. EM@, A. G., Gomz, M. R., Seybold, M. E., and La&x-t, E. H. (1973) Neurology 23,95-106. 5. M&le.r, M., and Di Mauro, S. (1977) Neurology 27,178-184. 6. H&s, H.G., vanHoof, F., and deBamy, T. (1989) In The Metabolic Basis of Inherited Disease (C.R. Striver, A.L. Beaudet, W. Sly, and D. Valle, Eds.). Vol.1, pp. 425-452. McXraw-Hill, New York. 7. Beratis, N.G., IaBadie, G.U., and Him&horn, K. (1978) J. Clin. Invest. 62,1264-1274. 8. Beratis, N.G., La&die, G.U., and Him&horn, K. (1983) Am. J. Hus.Genet. 35,21-33. 9. Brown, B. I., and Brown, D. H. (1965) Bicchim. Biophys. Acta. 110,124-133. 10. Hasilik, A., and Neufeld, E. F. J. Biol. Chem. (1980) 255,4937-4945. 11. Komfeld, S. (1986) J. Clin. Invest. 77,1-6. 12. LaBadie, G. U., Harris, H., Beratis, N. G., and Him&horn, K. (1985) Am. J. Mrm. Genet. (1985) 37,Al2 (abstract). 13. LaBadie, G.U. (1986) Ph.D. Thesis, City University of New York, Mt. Sinai Hospital. 14. Reuser, A. J. J., Kroos, M., Cude Elferink, R. P. J., and Tager, J. M. J. (1985) Biol. Chem. 260,8336-8341. 15. Reuser, A. J. J., Kroos, M., Williamson, R., Swallow, D., Tager, J. M., at-d Galjaard, H. (1987) J. Clin. Invest. 79,1689-1699. 16. !Qrtiniuk, F., M&&r, M., Pellicer, A., Tzall, S., IaBadie, G. U., Ellenbqen, A., and Hirschhom, R. (1986) Proc. NatI. Acad. Sci. USA 83,9641-9644. 17. Martiniuk, F., M&&r, M., Tzall, S., Meredith, G., and Him&horn, R. (1990) DNA and Cell Bio. 9‘85-94. 18. Martiniuk, F., Mehler, M., Tzall, S., Meredith, G., and Hir?XhhOm, R. (1990) Am. J. H\rm. mt. 47,73-78. 1514
Vol.
176,
No.
3, 1991
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
19. van der Ploeg, A.T. Hcefslot, L.H., Hoogeveen-Westeweld, M., Petersen, (1989) Am. J. Hum. Genet. 44,787-793. E.M., and Reuser, A.J.J. 20. Martiniuk, F., Bodkin, M., Tzall, S., and I3irs&hom, R. (1991) r%lA ti Cell Biolcgy, In press. 21. Tzall, s., Martiniuk, F., Adler, A., and Hire&horn, R. (1990) Nut. Acids Res. 18,1661. R. (1990) Nut. Acids Res. 22. Tzall, S., Martiniuk, F., and Hirwhhom, 18,193O. 23. Tzall, S., Martiniuk, F., Ozelius, L., Gusella, J., and Hire&horn, R. (1991) Nut. Acids Res. In press. 24. Tzall, S., Martiniuk, F., and Hirschhorn, R. (1991) Nut. Acids Res. In press. 25. Hcefsloot, L-H., Hcogeveen-Westerveld, M., Kmos, M., van Beeumen, J., Reuser, A.J.J., and Oostra, B.A. (1988) EM83 J. 7,1697-1704. 26. Sambrook, J., Fritsch, E.F, and Maniatis, T. (1989) Molecular Clonirq: A UbxatoryManual. ColdSpringHarborLabxatory Press, ColdSpring Harbor,NY. 27. Martiniuk, F., Bodkin, M., Tzall, S., at-d HiE&hOm, R. (1990) Am. J. M. Genet. 47,440-445. 28. Graham, F.L., and van der Eb, A.J. (1973) Virology 52,456-467. 29. Wigler, M., Pellicer, A., Silverstein, S., and &el, R. (1978) -11 14,725-731. 30. Martiniuk, F., and Hirschhom, R. (1981) Biochim. Bisphys. Acta. 658,248-261. 31. %X+kl.iUk, F., PelliCer, A., Mehhr, M. and Hi.rs&hom, R. (1986) SopMtic Cell and Mol. Gal&. 12,1-12. 32. Sanqer, F., Nicklen, S. and Coulson, A.R. Prcc. Natl. Acad. Sci., uSA (1977) 74,5463-5468.
1515