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Transient assay, by [3H]guanine incorporation of Escherichia coli xanthine-guanine phosphoribosyl transferase (GPT) in transfected human fibroblasts
Geve, 40 (1985) 93-98
93
Elsevier GENE
1461
Transient assay, by [3H]guanine incorporation of Escheric~ia coli xanthine-guanine transferase (CPT) in transfected human fibroblasts (Recombinant
DNA;
long terminal
repeat)
transient
expression;
promoter;
mycophenolic
acid; SV40 virus;
phosphoribosyl
Rous sarcoma
virus;
J *F . Burke”*, M.H.L. Greenb and J.E. Loweb
(Received
July 24th, 1985)
(Accepted
September
23rd.
1985)
SUMMARY
We have used [ ‘Hlguanine incorporation as a rapid and sensitive assay of x~thine-guanine ph~sphoribosyl transferase (GPT) activity in SV40 transformed human tibroblasts. The SV40 early promoter is more efficient than the Rous sarcoma virus long terminal repeat for transient expression of the gpt gene. The assay works well in a derivative of ATSBIVA which lacks hypoxanthine-guanine phospho~bosyl transferase (hprt _ ) and to work in the hprt + ATSBIVA
we show here how the assay has been adapted
parent. --
INTRODUCTION
The Escherichia coli gene gpt has been used in a number of systems as a basis for the selection of established cell lines which have taken up DNA by transfection (Mulligan and Berg, 1981). It offers
* To whom
correspondence
and
reprint
requests
should
be
addressed. CAT, chloramphenicol G, guanine; guanine
GMP,
acetyltransferase; guanosine
phosphoribosyl
transferase;
hypoxanthine-guanine monophosphate; essential
LTR,
phenyloxazolc;
repeat;
mycophenolic
RSV, Rous sarcoma
sulfate; TG, thioguanine~
transferase;
long terminal
MPA,
GPT, xanthine-
H, hypoxanthine;
phosphoribosyl
medium;
FCS, foetal calf serum;
monophosphate;
HPRT,
IMP, inosine MEM,
acid;
minimal
PPO,
X, xanthine;
XMP, xanthosine
phosphate.
0378-I 119:85:X03.30
0
2.5di-
virus; SDS, sodium dodecyl
1985 Elsevier
Science
Publishers
mono-
advantages over HPRT (Szybalska and Szybalski, 1962), thymidine kinase (Pellicer et al., 1978), and adenine phosphoribosyltransferase (Lowy et al., 1980) in that it is a dominant
marker which confers
a selectable activity lacking in normal mammalian cells. As a consequence it can be used in a wide variety of genetic back~ounds. To date, however, a simple assay for the determination of GPT activity in mammalian cells has not been available. Existing procedures require gel electrophoresis (Mulligan and Berg, 198 1) or thin-layer chromatography (Chu and Berg, 1985). CAT can also be assayed 48 h after transfection by thin-layer chromatography (Gorman et al., 1983), but cannot be used to establish stable transfectants in mammalian cells since no suitable selection system exists. In this communication we describe a simple and sensitive assay for the measurement of the E. co/i GPT activity in a human cell line transiently ex-
pressing the gpt gene. This assay relies on the uptake
containing
of [3H]G,
and its
cytidine
activity
plates
a substrate
incorporation
for the GPT enzyme,
into RNA
and DNA.
can be readily demonstrated by scintillation adapting
counting
the selection
in HPRT-negative
system of Mulligan
hprt+ human
cell line ATSBIVA.
scribed
here
makes
unique
in that
selection
activity
By
The method
de-
can be measured human
colonies. cloning
Single
between clones
100 and
were
picked
1000 Gpt’ using
glass
cylinders.
(c) Transient hrpt- cells
assay for incorporation
of [3H]G in
system
and the system can also be used for the of stable transformed
and 5 pg glycine. 20 days after transfection, contained
and Berg
in a wild-type
the gpt transfection
enzyme
cells
or autoradiography.
(198 l), GPT activity can be measured
transiently
GPT
per ml 25 pg MPA, 10 pg X, 15 c(g deoxy-
cells.
A modification
of the procedure
of Melvin et al.
(1979) was used. Cells were seeded in j-cm containing
a maximum
of four
glass
dishes
coverslips
(9 mm x 35 mm) at a density of 1 x lo5 cells/dish. After 24 h to allow the cells to settle and resume MATERIALS
AND METHODS
(a) Cell lines and plasmids ATSBIVA is an SV40-transformed fibroblast line derived from the primary fibroblast strain ATSBI, which was established from a patient with ataxiatelangiectasia (Taylor et al., 1975). It was the kind gift of Dr. L. Toji. Line 1251 was a spontaneous TG-resistant derivative of ATSBIVA, isolated by S.A. Harcourt in this laboratory. It does not incorporate detectable amounts of exogenous G, X or H and is presumed hprt . SC was a stable gpt + transfectant of 1251 isolated by JEL. 67 is a radioresistant gpt + transfectant of ATSBIVA containing a single copy of the gpt gene. Its isolation is described elsewhere (Green et al., 1985). Plasmids pSV2gpt and pLl0 were generous gifts from Dr. Paul Berg; pRSVgpt was a generous gift from Dr. C. Gorman. All plasmids were prepared using the alkaline/SDS lysis procedure of IshHorowitz and Burke (1981). (b) DNA mediated gene transfer For the selection ofgpt+ cell lines 5 x lo5 ATSBIVA cells were seeded onto 9-cm plates. Two days later DNA transfection was carried out by the calcium phosphate precipitation method (Graham and Van der Eb, 1974) using 20 pg of genomic DNA as carrier and 10 pg of pSV2gpt plasmid DNA. After 16 h the DNA-containing medium was removed, replaced with fresh medium, and 24 h later this medium was in turn replaced with selective medium
growth, 0.5 ml of calcium phosphate precipitate containing 10 pg ofplasmid DNA was added directly to the cells in growth medium. After an overnight exposure to the DNA at 37 ‘C, the medium removed was and replaced with fresh MEM + lo”,, FCS. Coverslips were removed from petri dishes with fine, sterile forceps and 20 111of MEM containing FCS and 1 pCi of [‘H]G (dissolved in HCI and neutralised in NaOH) was spotted onto each coverslip. The coverslips were then incubated overnight at 37 “C in a humidified incubator. After incubation with [ ‘H]G for 16 h, coverslips were rinsed briefly in Dulbecco ‘A’ buffer then in methanol-acetic acid (3 : 1 v/v) and then rinsed twice in ethanol. After air drying, the coverslips were placed in 5 ml of ToluenePPO scintillant and the radioactivity incorporated into the cells was measured by liquid scintillation counting. (d) Transient assay in hprt+ cells Cells were transfected as described above except that 16 h after transfection medium was replaced with MEM plus 100 pg MPA/ml and 15 big H/ml. Cells were maintained in this medium throughout the subsequent time of the experiment.
RESIJLTS
AND DISCUSSION
(a) Incorporation
of purines in human cells
Table I shows incorporation
of ‘3C-labelled
G, X
TABLE
I
Relative uptake of G, X and H by ATSBIVA Uptake
of [‘%Z]G by Four stable
pressed
as femtomol
undetectable
.4T5BIVA,
(0.05 &i/ml,
material removed Cells
of the purine
experiments
(7 for line 67 and
with
at
1PM) with or without unlabelled
approx.
were incubated lysed
immediately,
for 24 h at 37’C.
Medium
with Dulbecco
0.3 ml/plate
of neutral
‘A’ buffer. SDS
buffer
pH 7.4). Cells
were scraped
pipetted
off the plates
j”<) trichloroacetic scintillation activity
and 0.1”ml samples
3MM paper squares. counting.
approx.
International, Cell line
acid
and twice in ethanol
[i4C]G,
[‘“C]X
50 mCi/mmol)
prior
and [“‘C]H
were obtained
on to
3 times with
4
to liquid
(all specific
from Amersham
Buckingshamshire. Genotype
flprl+
67
These were washed
8
was
( 1I“, SDS. 200 mM Tris HCI, 100 PM EDTA, Whatman
-
12
After 24 or 48 h, label was
and the plates were washed
were
for the
in 5 cm dishes
(28 @M). One set of plates was sampled
the remainder
cpm. -2 x10
lines are approximate,
3 for line SC). Cells were plated
10“ cells per dish in 3 ml MEM.
added
amounts
between
since they are based on separate x
in MEM exover 24 h. The
( - ), this is less than 0.1 Y, of the value obtained
cell line 67. The comparisons
3
cell lines grown
of G per cell incorporated
cell line 125 I incorporated indicated
and its derivatives
Uptake
(fm/cell/day)
ABCD 48-72h
G
X
H
zTf)f +
1.6
0.13
0.30
transfected
Fig. 1. I!~corporation control;
SC
hJFr[-
@:Pt+
0.22
0.12
0.02
with pRSVgpt;
AT5BIVA
hprr *
0.30
0.03
irpri -
2.4 -
measured
1251 .-_
z@ -gp1--
-
and H into nucleic acids by ATSBIVA (hpvc’ gpt - ) and its derivatives 1251 (hprt- gpt-), SC (hprt- gpr + ), and 67 (hprt” gpt + ). As expected, the cells which contain the gpt gene incorporate more X than untransfected cells. Indeed this is the basis of the selection protocol of Mulligan and Berg (1981). Cells which can utilize X will grow in a selective medium in which the only source of purine is exogenous X. Untransfected ceils are unable to salvage sufficient purines from X to survive, so that X should be the logical purine with which to assay gpt gene activity. However, as Table I shows G is incorporated more efficiently in gpt+ cells than X. As [ 3H]G is commercially available at high specific activity and is more efficiently incorporated we have used this as a basis for transient expression. (b) Transient assay of GPT in hprtFig 1 shows the inco~oration
fection.
tells
of [ 3H]G into acid
of [3H]G
by 1251 (hprt _ )
(B) transfected
(D) transfected
transiently
with pLl0;
with pSV2mz.
over two different
[“WIG (specific
Amersham
ABCD 72-96h
International,
activity
periods
5 Ci/mmol)
ceils. (A) non(C) transfected
Incorporation
is
following trans-
was obtained
from
Buckinghamshire.
insoluble material following the transfection of various gpt constructs into a TG-resistant derivative of ATSBIVA (1251). Maximal activity is observed with the vector pSV2gpt (Mulligan and Berg, 1981) in which the gpt gene is under control of the SV40 promoter. A construct in which the gpt gene is under control of the RSV LTR (pRSVg~~) (Gorman et al., 1983) gives only half as much activity. Cells transfected with pLl0 which has the gpt gene cloned into pBR322 and no eukaryotic promoter sequence fail to incorporate any [ 3H]G. (c) Transient assay of GPT in hprt+ cells In cells which contain a functional hprt gene G is incorporated in nontransfected cells, because of the ability of the human HPRT to salvage G from the medium (Table I). To block the incorporation of G we have tested various components of the Mulligan and Berg selection system. Fig. 2 shows that H in
.-.:’ :-. . .. (:. ;*.:. ..:.. .‘.
.
*.
. l-l :.
: :
.’ . . . :;:.
:‘:.
:: I. I ,.
;y:;
’
I.
_:. ..., . .._. . __.. . .. ....‘.
8
. .
I *
H
.:
\
to the standard MA.1 l~KIAt.S
. .
I.(. .‘,
f.‘.
:
.‘:
..I
by non-transfected
.
,:
:
H + MPA
. ,a’
~ :.
’ . ..*
of [‘H]G
I
,..*~
Control ATSBIVA
’ ) cells (open bars) or cells 50-68 h post-transfcction
pSV2gpplir(stippled in
: . .
MPA
Fig. 2. Incorporation (heat
:. .
. : n’rcl
5 “’ ,. . .
: f. _: _. f .. .I
*: : . .*
4-
..’ *..
.‘. :
*
. .
‘* . ., .: :.. . . ‘. ’
.:. ..
..
. . . .
. . . ‘
I,
::e.
‘.
:
I.
‘..
‘.,.
with
bars). H and MPA were added or not (control)
MEM at the times and concentrations AND
METIIODS,
SeCtiOn
indicated
C.
the medium reduces the incorporation of [ ‘H]G by a factor of more than 100 in both control and pSV2gpt transfected ATSBIVA cells. However, little preferential incorporation of [3H]G in pSV2gpt transfected cells could be observed. If MPA alone is added to the standard MEM, cells transfected with pSV2gpt show a slightly higher (two-fold) increase in [“H]G incorporation over control cells. By adding both II and MPA, control cells incorporate [“H]G as they would in the presence of H alone whereas inco~oration by pSV2gpt transfected celis is ten-fold greater than controls and can be used as a reliable assay for the gpt activity in the hprt + human cell line ATSBIVA. Similar results have obtained with the SV40 transformed fibroblast line MRCSV I although in this case the control background is higher. The kinetics of expression of the gpt gene by hprt + and hprt -- cells transfected with pSV2gpt is similar, maximal incorporation being observed within 48 h of transfection. It should be noted however that the absolute amount of activity in the two systems is different, maximal activity in hprt cells being 17.5 “/, of that in hprt’ cells after a 16 h labelling period.
Fig. 3. Autoradiography WI 72-96
was for 10 days. shows
of
h post-transfection.
two
(b) part of (a) at higher
cells,
one
(c) ATSBIVA (hprr+). two days. removed
After
Kodak
incorporating
Magnification
liquid
from scintitlant,
for I-10 days
scintillation
magnification.
[‘H]G,
the
counting,
to Kodak
NTB2
(Gurr,
emulsion.
This
other
as for(b). Exposure
not.
was for
coverslips
rinsed briefly in methanol
DlY X-ray developer
and May-Gr~n~a~d
cells expressing transiently (a) Line 1251 (hprt-). Exposure
were
and exposed
After developing
in
the cells were stained with Giemsa Poole. U.K.).
(d) Autoradiograp~y
of transfected ceils
fore impossible The addition
Measurement
of gpt activity
ration is a determination activity in the population
by [3H]G
incorpo-
of the total amount of of cells. To determine
whether the activity measured
was due to a few cells
synthesizing a large amount of enzyme or a larger number of cells with less activity. coverslips with either control cells or cells transfected were taken
and autoradiographed.
show 125 1 (ATSBIVA with pSV2gpt.
From
hprt -gpt-
with pSV2gpt Figs. 3a and 3b
) cells transfected
the autoradiographs
we esti-
mate that approx. 2-5% of the cells are expressing the gpt gene. Autoradiography of ATSBIVA (hprt + ) cells transfected with pSV2gpf again gives a clear distinction between cells expressing or not expressing gpt {Fig. 3~). Incorporation is limited to about 5% of cells. No labelled cells are seen on the control slide. This suggests that H and MPA inhibit incorporation of G via the HPRT pathway very efficiently in all cells in the population and that the activity detected by scintillation counting arises from a minority of cells in the population.
by HPRT
to detect
via gpt.
G incorporation
of H and MPA blocks the uptake of G
and the conversion
of IMP derived from
H to XMP so starving the cell of G and allowing the sensitive ration
of gpt activity
measurement
by incorpo-
of [3H]G.
Using gpt+ derivatives
we have shown that this
system can be used to assay the activity of promoters tr~siently.
The ability to assay a promoter
ly and select cells expressing parison
transient-
the gene allows a com-
to be made of the activity of the same gene
extrachromosomally chromosome.
and when integrated
Potentially
the system
map sites of constitutive gene.
into the
allows one to
expression
for a regulated
ACKNOWLEDGEMENTS
We would like to thank Dr. Alan R. Lehmann Dr. R. Angus Harkness for valuable discussions advice.
and and
(ef Conclusions REFERENCES
We have shown that the dominant selectable gene gpt can be assayed simply and with a high degree of sensitivity, both in stable gpt transfectants and also transiently, using [ 3H]G incorporation. Although G is a substrate for both the HPRT and GPT enzymes, the K,,, for the GPT enzyme is several-fold lower, and uptake by HPRT but not GPT, is competitively inhibited by H. Other advantages of G are the availability of high specific activity 3H-labelled material and the negligible levels of G in FCS. X and H may be present in FCS at levels sufficient to give final concentrations in medium of l-2 pg/ml (Simmonds and Harkness, 1981). A second important point is that with hprt + cells, only those transfected with pSV2gpt will incorporate G in the presence of MPA and H. This is best explained by the fact that H is the preferred substrate for human HPRT (Table I) and if H is present in excess, the incorporation of [ 3H]G is reduced both by competition with H for HPRT and by dilution of the radioactive GMP by unlabelled GMP derived from H via IMP. In the absence of MPA it is there-
Burke, J.F., Sinclair,
J.H., Sang, J.H. and Ish-Horowitz,
assay for transient cells using
gene expression
[3H]guanine
incorporation.
D.: An Drosophila
in transfected
EMBO J. 3 (1984)
X49-2554. Chu, G. and Berg, P.: Rapid assay for detection xanthine-guanine transduced Gorman,
of Edwrichia
coli
activity
in
phosphoribosyltransferase
cells. Nuol. Acids Res. 13 (1985) 2921-2930.
C., Pa~anabhan,
ey DNA-mediated
R. and Howard, transformation
B.H.: High efftcien-
of primate
cells. Science
221 (1983) 551-553. Green.
M.H.L.,
attempt
to
telangiectasia
Lowe, J.E., James,
M.R. and Arlett,
transfer
resistance
radiation
cell line, in Gatti,
Ataxia-telangiectasia:
Genetics,
nology of a Degenerative York, Graham,
1985,
to
R. and
and Immu-
of Childhood.
Liss, New
pp. 173-183.
F.L. and Van der Eb, A.J.: A new technique
analysis
An
ataxia-
Swift, M. (Eds.),
Neuropathology
Disease
CF.: an
of human
adenovirus
5 DNA.
Virology
for the 52 (1974)
456-467. fsh-Horowitz, cloning.
D. and Burke,
Lowy, I., Pellicer,
A., Jackson,
and Axel, R.: Isolation hamster
J.F.: Rapid and efficient
plasmid
Nucl. Acids Res. 9 (1981) 2989-2998. J.F., Sim, G.-K.,
of transforming
Silverstein,
DNA:
cloning
S. the
uprt gene. Cell 22 (1980) 817-823.
Melvin, W.T., Burke, J.F., Blair, A.A. and Keir, H.M.: Effect of
98
amino-acid
deprivation
on DNA synthesis
in BHK-2l/Cl3
Mulligan,
R.C. and
Berg,
P.: Selection
express the Escherichia
coli gene coding
phosphoribosyl-transferase.
for animal
cells that
for xanthine-guanine
Proc. Natl. Acad.
Sci. USA 77
( 198 1) 2072-2076. and stable integration
S.: The transfer
of the HSV TK gene into mouse cells.
Cell 14 (1978) 133-141. R.J. and Harkness,
chromatographic
Szybalska,
methods
fluids and in cells. J. Chromatogr.
E.H. and Szybalski,
IV. DNA-mediated A.M.R.,
Lehmann, telangiectasia: sensitivity.
R.A.: High-performance for base and nucleoside
Harnden, A.R.,
226 (1981)
Communicated
Arlett,
mutation
CF.,
Harcourt,
Bridges,
B.A.:
with abnormal
258 (1975) 427-429.
by G. Wilcox.
cell lines,
of a biochemi-
Sci. USA 48 (1962) 2026-2034. S. and
liquid analysis in
ofhuman
transformation
D.G.,
Stevens,
a human Nature
W.: Genetics
heritable
cal trait. Proc. Natl. Acad. Taylor,
Pellicer, A., Wigler, A., Axel, R. and Silverstein,
Simmonds,
extracellular 369-381.
cells. J. Cell Phys. 98 (1979) 73-81.
S.A., Ataxia-
radiation
93
Elsevier GENE
1461
Transient assay, by [3H]guanine incorporation of Escheric~ia coli xanthine-guanine transferase (CPT) in transfected human fibroblasts (Recombinant
DNA;
long terminal
repeat)
transient
expression;
promoter;
mycophenolic
acid; SV40 virus;
phosphoribosyl
Rous sarcoma
virus;
J *F . Burke”*, M.H.L. Greenb and J.E. Loweb
(Received
July 24th, 1985)
(Accepted
September
23rd.
1985)
SUMMARY
We have used [ ‘Hlguanine incorporation as a rapid and sensitive assay of x~thine-guanine ph~sphoribosyl transferase (GPT) activity in SV40 transformed human tibroblasts. The SV40 early promoter is more efficient than the Rous sarcoma virus long terminal repeat for transient expression of the gpt gene. The assay works well in a derivative of ATSBIVA which lacks hypoxanthine-guanine phospho~bosyl transferase (hprt _ ) and to work in the hprt + ATSBIVA
we show here how the assay has been adapted
parent. --
INTRODUCTION
The Escherichia coli gene gpt has been used in a number of systems as a basis for the selection of established cell lines which have taken up DNA by transfection (Mulligan and Berg, 1981). It offers
* To whom
correspondence
and
reprint
requests
should
be
addressed. CAT, chloramphenicol G, guanine; guanine
GMP,
acetyltransferase; guanosine
phosphoribosyl
transferase;
hypoxanthine-guanine monophosphate; essential
LTR,
phenyloxazolc;
repeat;
mycophenolic
RSV, Rous sarcoma
sulfate; TG, thioguanine~
transferase;
long terminal
MPA,
GPT, xanthine-
H, hypoxanthine;
phosphoribosyl
medium;
FCS, foetal calf serum;
monophosphate;
HPRT,
IMP, inosine MEM,
acid;
minimal
PPO,
X, xanthine;
XMP, xanthosine
phosphate.
0378-I 119:85:X03.30
0
2.5di-
virus; SDS, sodium dodecyl
1985 Elsevier
Science
Publishers
mono-
advantages over HPRT (Szybalska and Szybalski, 1962), thymidine kinase (Pellicer et al., 1978), and adenine phosphoribosyltransferase (Lowy et al., 1980) in that it is a dominant
marker which confers
a selectable activity lacking in normal mammalian cells. As a consequence it can be used in a wide variety of genetic back~ounds. To date, however, a simple assay for the determination of GPT activity in mammalian cells has not been available. Existing procedures require gel electrophoresis (Mulligan and Berg, 198 1) or thin-layer chromatography (Chu and Berg, 1985). CAT can also be assayed 48 h after transfection by thin-layer chromatography (Gorman et al., 1983), but cannot be used to establish stable transfectants in mammalian cells since no suitable selection system exists. In this communication we describe a simple and sensitive assay for the measurement of the E. co/i GPT activity in a human cell line transiently ex-
pressing the gpt gene. This assay relies on the uptake
containing
of [3H]G,
and its
cytidine
activity
plates
a substrate
incorporation
for the GPT enzyme,
into RNA
and DNA.
can be readily demonstrated by scintillation adapting
counting
the selection
in HPRT-negative
system of Mulligan
hprt+ human
cell line ATSBIVA.
scribed
here
makes
unique
in that
selection
activity
By
The method
de-
can be measured human
colonies. cloning
Single
between clones
100 and
were
picked
1000 Gpt’ using
glass
cylinders.
(c) Transient hrpt- cells
assay for incorporation
of [3H]G in
system
and the system can also be used for the of stable transformed
and 5 pg glycine. 20 days after transfection, contained
and Berg
in a wild-type
the gpt transfection
enzyme
cells
or autoradiography.
(198 l), GPT activity can be measured
transiently
GPT
per ml 25 pg MPA, 10 pg X, 15 c(g deoxy-
cells.
A modification
of the procedure
of Melvin et al.
(1979) was used. Cells were seeded in j-cm containing
a maximum
of four
glass
dishes
coverslips
(9 mm x 35 mm) at a density of 1 x lo5 cells/dish. After 24 h to allow the cells to settle and resume MATERIALS
AND METHODS
(a) Cell lines and plasmids ATSBIVA is an SV40-transformed fibroblast line derived from the primary fibroblast strain ATSBI, which was established from a patient with ataxiatelangiectasia (Taylor et al., 1975). It was the kind gift of Dr. L. Toji. Line 1251 was a spontaneous TG-resistant derivative of ATSBIVA, isolated by S.A. Harcourt in this laboratory. It does not incorporate detectable amounts of exogenous G, X or H and is presumed hprt . SC was a stable gpt + transfectant of 1251 isolated by JEL. 67 is a radioresistant gpt + transfectant of ATSBIVA containing a single copy of the gpt gene. Its isolation is described elsewhere (Green et al., 1985). Plasmids pSV2gpt and pLl0 were generous gifts from Dr. Paul Berg; pRSVgpt was a generous gift from Dr. C. Gorman. All plasmids were prepared using the alkaline/SDS lysis procedure of IshHorowitz and Burke (1981). (b) DNA mediated gene transfer For the selection ofgpt+ cell lines 5 x lo5 ATSBIVA cells were seeded onto 9-cm plates. Two days later DNA transfection was carried out by the calcium phosphate precipitation method (Graham and Van der Eb, 1974) using 20 pg of genomic DNA as carrier and 10 pg of pSV2gpt plasmid DNA. After 16 h the DNA-containing medium was removed, replaced with fresh medium, and 24 h later this medium was in turn replaced with selective medium
growth, 0.5 ml of calcium phosphate precipitate containing 10 pg ofplasmid DNA was added directly to the cells in growth medium. After an overnight exposure to the DNA at 37 ‘C, the medium removed was and replaced with fresh MEM + lo”,, FCS. Coverslips were removed from petri dishes with fine, sterile forceps and 20 111of MEM containing FCS and 1 pCi of [‘H]G (dissolved in HCI and neutralised in NaOH) was spotted onto each coverslip. The coverslips were then incubated overnight at 37 “C in a humidified incubator. After incubation with [ ‘H]G for 16 h, coverslips were rinsed briefly in Dulbecco ‘A’ buffer then in methanol-acetic acid (3 : 1 v/v) and then rinsed twice in ethanol. After air drying, the coverslips were placed in 5 ml of ToluenePPO scintillant and the radioactivity incorporated into the cells was measured by liquid scintillation counting. (d) Transient assay in hprt+ cells Cells were transfected as described above except that 16 h after transfection medium was replaced with MEM plus 100 pg MPA/ml and 15 big H/ml. Cells were maintained in this medium throughout the subsequent time of the experiment.
RESIJLTS
AND DISCUSSION
(a) Incorporation
of purines in human cells
Table I shows incorporation
of ‘3C-labelled
G, X
TABLE
I
Relative uptake of G, X and H by ATSBIVA Uptake
of [‘%Z]G by Four stable
pressed
as femtomol
undetectable
.4T5BIVA,
(0.05 &i/ml,
material removed Cells
of the purine
experiments
(7 for line 67 and
with
at
1PM) with or without unlabelled
approx.
were incubated lysed
immediately,
for 24 h at 37’C.
Medium
with Dulbecco
0.3 ml/plate
of neutral
‘A’ buffer. SDS
buffer
pH 7.4). Cells
were scraped
pipetted
off the plates
j”<) trichloroacetic scintillation activity
and 0.1”ml samples
3MM paper squares. counting.
approx.
International, Cell line
acid
and twice in ethanol
[i4C]G,
[‘“C]X
50 mCi/mmol)
prior
and [“‘C]H
were obtained
on to
3 times with
4
to liquid
(all specific
from Amersham
Buckingshamshire. Genotype
flprl+
67
These were washed
8
was
( 1I“, SDS. 200 mM Tris HCI, 100 PM EDTA, Whatman
-
12
After 24 or 48 h, label was
and the plates were washed
were
for the
in 5 cm dishes
(28 @M). One set of plates was sampled
the remainder
cpm. -2 x10
lines are approximate,
3 for line SC). Cells were plated
10“ cells per dish in 3 ml MEM.
added
amounts
between
since they are based on separate x
in MEM exover 24 h. The
( - ), this is less than 0.1 Y, of the value obtained
cell line 67. The comparisons
3
cell lines grown
of G per cell incorporated
cell line 125 I incorporated indicated
and its derivatives
Uptake
(fm/cell/day)
ABCD 48-72h
G
X
H
zTf)f +
1.6
0.13
0.30
transfected
Fig. 1. I!~corporation control;
SC
hJFr[-
@:Pt+
0.22
0.12
0.02
with pRSVgpt;
AT5BIVA
hprr *
0.30
0.03
irpri -
2.4 -
measured
1251 .-_
z@ -gp1--
-
and H into nucleic acids by ATSBIVA (hpvc’ gpt - ) and its derivatives 1251 (hprt- gpt-), SC (hprt- gpr + ), and 67 (hprt” gpt + ). As expected, the cells which contain the gpt gene incorporate more X than untransfected cells. Indeed this is the basis of the selection protocol of Mulligan and Berg (1981). Cells which can utilize X will grow in a selective medium in which the only source of purine is exogenous X. Untransfected ceils are unable to salvage sufficient purines from X to survive, so that X should be the logical purine with which to assay gpt gene activity. However, as Table I shows G is incorporated more efficiently in gpt+ cells than X. As [ 3H]G is commercially available at high specific activity and is more efficiently incorporated we have used this as a basis for transient expression. (b) Transient assay of GPT in hprtFig 1 shows the inco~oration
fection.
tells
of [ 3H]G into acid
of [3H]G
by 1251 (hprt _ )
(B) transfected
(D) transfected
transiently
with pLl0;
with pSV2mz.
over two different
[“WIG (specific
Amersham
ABCD 72-96h
International,
activity
periods
5 Ci/mmol)
ceils. (A) non(C) transfected
Incorporation
is
following trans-
was obtained
from
Buckinghamshire.
insoluble material following the transfection of various gpt constructs into a TG-resistant derivative of ATSBIVA (1251). Maximal activity is observed with the vector pSV2gpt (Mulligan and Berg, 1981) in which the gpt gene is under control of the SV40 promoter. A construct in which the gpt gene is under control of the RSV LTR (pRSVg~~) (Gorman et al., 1983) gives only half as much activity. Cells transfected with pLl0 which has the gpt gene cloned into pBR322 and no eukaryotic promoter sequence fail to incorporate any [ 3H]G. (c) Transient assay of GPT in hprt+ cells In cells which contain a functional hprt gene G is incorporated in nontransfected cells, because of the ability of the human HPRT to salvage G from the medium (Table I). To block the incorporation of G we have tested various components of the Mulligan and Berg selection system. Fig. 2 shows that H in
.-.:’ :-. . .. (:. ;*.:. ..:.. .‘.
.
*.
. l-l :.
: :
.’ . . . :;:.
:‘:.
:: I. I ,.
;y:;
’
I.
_:. ..., . .._. . __.. . .. ....‘.
8
. .
I *
H
.:
\
to the standard MA.1 l~KIAt.S
. .
I.(. .‘,
f.‘.
:
.‘:
..I
by non-transfected
.
,:
:
H + MPA
. ,a’
~ :.
’ . ..*
of [‘H]G
I
,..*~
Control ATSBIVA
’ ) cells (open bars) or cells 50-68 h post-transfcction
pSV2gpplir(stippled in
: . .
MPA
Fig. 2. Incorporation (heat
:. .
. : n’rcl
5 “’ ,. . .
: f. _: _. f .. .I
*: : . .*
4-
..’ *..
.‘. :
*
. .
‘* . ., .: :.. . . ‘. ’
.:. ..
..
. . . .
. . . ‘
I,
::e.
‘.
:
I.
‘..
‘.,.
with
bars). H and MPA were added or not (control)
MEM at the times and concentrations AND
METIIODS,
SeCtiOn
indicated
C.
the medium reduces the incorporation of [ ‘H]G by a factor of more than 100 in both control and pSV2gpt transfected ATSBIVA cells. However, little preferential incorporation of [3H]G in pSV2gpt transfected cells could be observed. If MPA alone is added to the standard MEM, cells transfected with pSV2gpt show a slightly higher (two-fold) increase in [“H]G incorporation over control cells. By adding both II and MPA, control cells incorporate [“H]G as they would in the presence of H alone whereas inco~oration by pSV2gpt transfected celis is ten-fold greater than controls and can be used as a reliable assay for the gpt activity in the hprt + human cell line ATSBIVA. Similar results have obtained with the SV40 transformed fibroblast line MRCSV I although in this case the control background is higher. The kinetics of expression of the gpt gene by hprt + and hprt -- cells transfected with pSV2gpt is similar, maximal incorporation being observed within 48 h of transfection. It should be noted however that the absolute amount of activity in the two systems is different, maximal activity in hprt cells being 17.5 “/, of that in hprt’ cells after a 16 h labelling period.
Fig. 3. Autoradiography WI 72-96
was for 10 days. shows
of
h post-transfection.
two
(b) part of (a) at higher
cells,
one
(c) ATSBIVA (hprr+). two days. removed
After
Kodak
incorporating
Magnification
liquid
from scintitlant,
for I-10 days
scintillation
magnification.
[‘H]G,
the
counting,
to Kodak
NTB2
(Gurr,
emulsion.
This
other
as for(b). Exposure
not.
was for
coverslips
rinsed briefly in methanol
DlY X-ray developer
and May-Gr~n~a~d
cells expressing transiently (a) Line 1251 (hprt-). Exposure
were
and exposed
After developing
in
the cells were stained with Giemsa Poole. U.K.).
(d) Autoradiograp~y
of transfected ceils
fore impossible The addition
Measurement
of gpt activity
ration is a determination activity in the population
by [3H]G
incorpo-
of the total amount of of cells. To determine
whether the activity measured
was due to a few cells
synthesizing a large amount of enzyme or a larger number of cells with less activity. coverslips with either control cells or cells transfected were taken
and autoradiographed.
show 125 1 (ATSBIVA with pSV2gpt.
From
hprt -gpt-
with pSV2gpt Figs. 3a and 3b
) cells transfected
the autoradiographs
we esti-
mate that approx. 2-5% of the cells are expressing the gpt gene. Autoradiography of ATSBIVA (hprt + ) cells transfected with pSV2gpf again gives a clear distinction between cells expressing or not expressing gpt {Fig. 3~). Incorporation is limited to about 5% of cells. No labelled cells are seen on the control slide. This suggests that H and MPA inhibit incorporation of G via the HPRT pathway very efficiently in all cells in the population and that the activity detected by scintillation counting arises from a minority of cells in the population.
by HPRT
to detect
via gpt.
G incorporation
of H and MPA blocks the uptake of G
and the conversion
of IMP derived from
H to XMP so starving the cell of G and allowing the sensitive ration
of gpt activity
measurement
by incorpo-
of [3H]G.
Using gpt+ derivatives
we have shown that this
system can be used to assay the activity of promoters tr~siently.
The ability to assay a promoter
ly and select cells expressing parison
transient-
the gene allows a com-
to be made of the activity of the same gene
extrachromosomally chromosome.
and when integrated
Potentially
the system
map sites of constitutive gene.
into the
allows one to
expression
for a regulated
ACKNOWLEDGEMENTS
We would like to thank Dr. Alan R. Lehmann Dr. R. Angus Harkness for valuable discussions advice.
and and
(ef Conclusions REFERENCES
We have shown that the dominant selectable gene gpt can be assayed simply and with a high degree of sensitivity, both in stable gpt transfectants and also transiently, using [ 3H]G incorporation. Although G is a substrate for both the HPRT and GPT enzymes, the K,,, for the GPT enzyme is several-fold lower, and uptake by HPRT but not GPT, is competitively inhibited by H. Other advantages of G are the availability of high specific activity 3H-labelled material and the negligible levels of G in FCS. X and H may be present in FCS at levels sufficient to give final concentrations in medium of l-2 pg/ml (Simmonds and Harkness, 1981). A second important point is that with hprt + cells, only those transfected with pSV2gpt will incorporate G in the presence of MPA and H. This is best explained by the fact that H is the preferred substrate for human HPRT (Table I) and if H is present in excess, the incorporation of [ 3H]G is reduced both by competition with H for HPRT and by dilution of the radioactive GMP by unlabelled GMP derived from H via IMP. In the absence of MPA it is there-
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