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Effect of vector type, host strains and transcription terminator on heterologous gene expression in yeast
Vol. 140, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
October 30, 1986
Pages 602-608
EFFECT OF VECTOR TYPE, HOST STRAINS AND TRANSCRIPTION ON HETEROLOGOUS GENE EXPRESSION IN YEAST Kong-Bung
Choo,
Sheue-Mei
Wu, Li
Hung,and
Recombinant DNA Laboratory, Department Veterans General Hospital, Taipei, Taiwan Received
September
10,
TERMINATOR
Hsien-Hsiung
Lee
of Medical Research, 112, Republic of China
1986
Using the surface antigen gene of the hepatitis B virus, and the promoter and terminator sequences of the yeast pho5 gene as a a series of closely related expression plasmids were model system, constructed to investigate the effect of vector type, genetic background of host strains and the presence of transcription terminator on the expression of heterologous,gene in yeast. Plasmids carrying the replication origin of the 2~ plasmids were found to be much more stable than those either independently or simultaneously Gene expression was also higher with 2vmcarrying a&51 sequences. based plasmids. Yeast selection marker (ttlpl or eeu2) and therefore the host strains used did not have significant effects on gene expression. Addition of transcription terminator sequences downstream to the HBsAg gene also contributed only limited increases Q 1986 Academic Press, Inc. in gene expression levels. A wide
range
of biological
gene
expression.
have
several
with
no known pathogenicity
Among the distinct
man in brewery romosomal
hosts
industries.
systems
yeast
transformation
procedures
2) and a variety
of efficient
vectors
have
been
to suit
have
have
specific
described.
are
used
for
this
long
been
purpose,
yeasts
promoters
(3-5)
vectors
most
associated
studied
More
have now been well
Yeast
heterologous
with
and extrach-
been well
purposes.
for
common micro-organisms
The nuclear
of yeasts
manipulated
been
used
They
and they
easily
(1,
being
advantages.
and bakery
genetic
hosts
have
and are
importantly, established
and yeast commonly
cloning used
for
Abbreviations: a)Ldl, autonomously replicating sequences of yeast of replication of the 2pm plasmid; chromosome; 2um ohi, origin HBsAg, hepatitis B surface antigen; (k)b, (kilo)base pairs; Pi, inorgainc phosphate; S/N, ratio of sample value to negative value in radio-immunoassay for HBsAg. 0006-291X/86 Copyrighr All rights
$1.50 0 I986 b-k’ Academic, Press. oj reproduction in any ,fbrm
Inc. reserved.
602
Vol. 140, No. 2, 1986
gene
BIOCHEMICAL
expression
originally
have
cloned
carrying
the
plasmid
In
two types
related
carrying
yeast
constructed
to
of the
to systematically on gene
on gene
test
the
and the
the
sequences
(6)
and vectors
expression,
the
effects
of
of closely
of host
Plasmids
strains
were also
genetic
transcription
2pm
effect
a series
of different of
endogenous
compare
expression.
presence
a,tbl
yeast
to minimize
effect
RESEARCH COMMUNICATIONS
chromosomes
of replication
were designed
variables
MATERIALS
the
order
plasmids
strains
those
of vectors
and other
host
from
origin
(7).
these
been
AND BIOPHYSICAL
background
terminator
of
sequences.
AND METHODS
E,coLilyeast shuttle plasmids were Construction of shuttle plasmids: constructed according to standard procedures(8). E.coLi strain DH5 (9)was used in all E.co.& transformation experiments. The plasmids were transformed into yeast cells using the method of Ito et n!(2). Analysis of yeast transformants: In each experiment, transformants were grown in 10 1 f a mixture of phosphate-depleted YEPD (1% yeast extract, 2%mpeitone, 2% glucose) and minimal glucose medium (0.67% yeast nitrogen base, 2% glucose, 20 mg/ml uracil) in 1:4 ratio in 50 ml conical flasks at 30" for 36-40 h with vigorous rotary shaking at 200 rpm to A600 of 5-10. The cells were homogenized with glass beads and the homogenates were assayedfor HBsAg using the AusriaR kit from Abbott Laboratories as described (10). RESULTS AND DISCUSSION As a model host
strains
promoter were
for
the
investigation
and transcription
sequences
placed
of the
upstream
fragment
sequences
entire
to a 1.4 kb EcoRI-SaLI SalI of
site
to obtain
site
This
clone gene
(p2~-Sll) in
the
promoter
out
was corrected
and digesting
the
SueI
was obtained correct
acid
on gene
reading
in
of vector
(pho5)
two stages
(12)
carrying
the
This
rendered
of phase
using
by linearizing termini which frame(l0).
with
the
Bat31
gene
(Fig. pku5
was first
the upstream 116-5
The BaL31
1).
A
ligated the
reading
frame
pho5
initiation
at the
and religating.
showed expression
(11)
coding
HBsAg gene via
clone
type,
expression,
83 bp of the region
116-5.
effect
phosphatase
containing
fragment
the HBsAg sequence
codon.
yeast
clone
the
terminator
to the HBsAg gene
2.7 kb EcuRI-SaLI and the
of
of digestion
S&I A
the HBsAg resulted
Vol. 140, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
E.COIi
-
60131
1
w5
----_
p2p-SI
I
--em--
BE
H l.gKb-
phob terminator
E 8, .
3.OKbd 5SKb -
E
IL---
vql7,PW2-F*
psy97
YRp7-SllT p~u2-SI IT pShl97-Sl
Fig.
in retention gene,
IT
1. Construction of yeast expression plasmids for HBsAg gene. Clone 116-5 was first constructed by assembling the various components the origin of which is described in Fig. 2.and in the text. The excess sequences between the pho5 promoter and the HBsAg gene were removed by linearizing 116-5 with SaLI and digestion with B&Z31 to obtain p21+1-S11. The 1.9 kb BumHI fragment from p2u-Sll was inserted into pLeu2-F (Fig. 2) to obtain pLeu2-Sll. A 1.1 kb HpaII fragment was excised from the 3' region of the pho5 gene, the termini filled in with DNA polymerase and was then inserted at the HpaI(H) site at the 3' -end of the HBsAg gene of p2~-Sll to produce p2~-SllT. The3.0 kb BamHI or the 5.5 kb EcoRI(E) fragment was inserted into YRp7, pLeu2-F and pSM97 (Fig. 2) to obtain YRp7-SllT, pLeu2-SllT and pSM97-SllT. Open box, pho5 coding region; hatched box, HBsAg gene; filled box, pho5 terminator sequences.
of
the
13 amino acid
(13)
and the
entire
K.B.
Choo, unpublished
first
three
residues
amino acid
from the PreS2 region
HBsAg gene in plasmid
2pm o&i from pJDB219(14)
data).
residues
Plasmid
and the tap1 604
p2~-Sll
p2~-Sll marker
also (Fig.
from the
pho5
of HBV genome (H.H.
Lee and
contains 2).
the
Vol.
140,
No
BIOCHEMICAL
2, 1986
AND
(a)
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
(b)
(a) p'Zp-Sll; (b) pLeu2-F; 2. Plasmids used in the present study. source of the various fragments: (A) Cc) pSM97. Original 2.7 kb EcoRI-SaLI fragment from pAP20 (11, 12) containing the pho5 promoter. (B) 1.4 kb SaLI-EcoRI fragment from pTWS105 containing the HBsAg gene (unpublished); (C) 2.5 kb EcoRI fragment from pJDB219 (12) containing the 2urn origin of replication; (D) 4.4 kb icoR1 fragment from YRp7 (13) carrying the thpl and Tc genesbut without the ahnl sequence; (E) 3.3 kb Hind111 fragment from pJDB219 containing the eeu2 gene and the 2pm ori; (F) 2.7 kb Hind111 fragment of pUC9; (G) 1.4 kb EcoRI fragment from YRp7 with thpl gene and atrnl sequence; (H) 5.6 kb EcoRI fragment from SW9 (P. Nagley, personal con-munication) containing the Tcii gene and the ?vm
Fig.
Ohi.
In order terminator
to
the effect
on the expression
sequence
of
was inserted
SllT
the
at
was contained the
the
to obtain
into
F (2um ohi,
2) and pSM97 (both
2).
SllT
The resulting
and pSM-SllT
fragment
which
from p2u-Sll
does
of all columns
These plasmids strains Marked
which
contain
the
in Table
atlbl
pLeu2-F
plasmids
1).
Subfrom p2~-
terminator) pLeu2-
itrpl)(l5),
and 2urn
04i,
YRp7-SllT, the
(Fig.
pLeu2-
promoter-HBsAg was excised
1).
described
thpl)
The major
are summarized
1.
were transformed
were auxotrophic
differences
(a&Al,
the pho5 terminator into
six
downstream
(Fig.
For comparison,
and was inserted
characteristics in left-hand
not
a 1.1 kb
located
were designated
respectively.
terminator
gene-(pho5
vectors'YRp7
plasmids
transcription
3.0 kb EcoRI fragment
sequences was inserted
(Fig.
the
p2~-SllT
(pho5 promoter)-HBsAg
eeu2)(Fig.
of
within
site
HpcrI
1.9 kb BumHI or the
containing
the presence
of the HBsAg gene,
to the HBsAg gene in p2~-Sll sequently,
of
the phu5 gene which
fragment
HpaII
test
into
at the
in the genetic
-0~~1
stability 605
three
different
and/or of
the
host Leu2 loci.
the plasmids
were
t
pLeu2-SllT
t
t
t t
t
t 38
0
96
t
t
100
t
94
52
0
a5
66
a7
70
DB746
n.d.
n.d.
n.d.
n.d.
n.d.c
96
10.9
0
25
16.5
26
20
GN3C. 2
n.d.
n.d.
0 13.4
n.d.
n.d. 47.5
7.4
n.d.
35
20 16.9
YNN27
(S/N)b
DB746
HBsAg expression
of HBsAg gene in yeast
YNN27
Stabilitya
Plasmid GN3C.2
levels
and expression
t
t
Terminator
stability
93
Leu2
marker
plasmid
t
Thpl
Yeast
affecting
thpl
uha31
bTransformants were grown in 10 ml and homogenized with glass beads Abbott Labs. Values are averages c.1+,, and 11-11indicate presence or
[a,
Cell were of low Pi medium (10 mg/l Pi) to A660 = 5 - 10. (450 pm) and the lysates were.assayed for HBsAg using Ausria of 2-3 determinations. absence of the indicated sequences. n.d., not determined.
harvested kit from
aGenetic stability was determined by plating equal aliquots of transformant cells on minimal and rich colonies on YEPD plate) x 100. (Values on minimal plate/no. (YEPD) media. Stability = (No. colonies GN3C.2: [a, ecu2 t&pl]i DB746; [a, hid1 ecu2 thpl uhfd]; YNN27: are averages of 2-4 determinations).
pSM-SUT
t
t
pLeu2-Sll
YRp7-SllT
t
p2~-SllT
ahA
2vm
tc
type
Vector
1. Factors
p2u-Sll
Plasmid
Table
Vol.
140,
No. 2, 1986
observed very
in
BIOCHEMICAL
that
unstable
plasmid
while
some differences
of
the
is
also
reflected
less
expression but
in
DB746,
amounts
plasmids
Our results
yeast
vector
than
ahcll
There
with
used.
probably and are
of
recombination
a4bl
vectors,
results
in
studies
on the loci
(CEN)
reveal used
loss
have
been
and the
sequences HBsAg gene. may still
effect
presence
case,
the
putative
was positioned Localization have
greater
use of 2pm vectors,
important
factor
which
of the
in
250 bp from the
polyA
influence the affects
the
choice
the
signal
expression 607
of stable
In
are the
case
easily Recent
by centromeric did
of the
not
host
on gene
strains expression.
pho5 terminator
closer
expression.
of promoter
type
more
plasmids.
termination
on gene
effect
sequences
terminator of
differ-
2pm plasmids
background
signal
to produce
the
Our results
of transcription
of
is
sequences
17).
of genetic
polyA
that
the
exception
marker.
copy number.
au
(16,
the
significant
chromosomal
sequences
2pm 2-fold
significantly
fact
in high
described
the
hand,
no consistent
expression
are
with
of gene
other
seemed
the most
vectors
stabilization
significant
In our
the
the
for
as selection
gene
present
produced
With
however,
due to the
extrachromosomal
YRp7-SllT
On the
terminator
showed that
2pm-based
vectors
the
or 1~2
and therefore
stability
pSM-SllT
strains.
were,
thpl
therefore
stability
with
the presence
For any plasmid,
different
plasmids
of HBsAg.
between
on plasmid
with
in
HBsAg gene.
higher
with
strains.
The plasmid
is relatively
was
stable
host
average.
do exist.
sequence
reduced
of the
on the
COMMUNICATIONS
more
or no HBsAg while
some variations
of p2~-SllT
ences
expression
HBsAg gene
are observed
utrnl
different
was greatly
plasmids
differences
higher
among the
little
other
of the
plasmids
the
produced
HBsAg than
the
as shown by pSM-SllT.
in
transformants
RESEARCH
carrying
2urn plasmid
sequences
BIOPHYSICAL
were relatively
stability
of the
am1
YRp7-SllT
2pm plasmids
in
The stability
AND
codon to the Thus,
may be the
of foreign
of
genes
the
gene besides
more in
yeast.
Vol. 140, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
ACKNOWLEDGMENT
from
This work was supported by research the National Science Council of the
grant NSC75-0609-B075-01 Republic of China.
REFERENCES 1.
2. 3. 4. 5. 6. 7. a. 9. 10.
11. 12. 13.
:;: 16. 17.
Hinnen, A., Hicks, J-B., Fink, G.R. (1978) Proc. Natl. Acad. Sci. USA 75 1929-1938. Ito, H., Ekuda, Y., Murata, K., Kimura, A. (1983) 5. Bacterial. 153, 163-168. Miyanohara, A., Toh-e, A., Nozaki, C., Hamada F., Ohtoms, N., Matsubara, K. (1983) Proc. Natl. Sci. USA 80, l-5. Hitzeman, R.A., Chan, C. Y., Haige, F.K. et UL. (1983) Nucl Acids Res. I.& 2745-2763. Bitter, G., Chen, K.K., Banks, A.R., Lai, P.H. (1984) Proc. Nacl. Acad. Sci. USA 81, 5330-5334. D., Sherer, S., Davis, R. (1979) Proc. Struhl, K., Stinchcom6; Natl. Acad. Sci. USA 76, 1035-1039. Hollenberg, C.P. (1982) Curr. Topics Microbial. Immunol. 96, 119-114. Maniatis, T., Fritsch, E.F., Sambrook, J. (1982) Molecular Cloning: A Laboratory Manual. Cold Spring Harbor Laboratory, Cold Spring Harbor. Hahanan, D. (1985) In: "DNA Cloning: A Practical Approach" (D.M. Glover, Ed.) IRL Press, Oxford, pp109-136. Choo, K.B., Wu S.M., Lee, H.H., Lo, S.J. (1985) Biochem. Biophys Res. Commun. 131, 160-166. (1980) Proc. Natl. Acad. Sci. USA -77 Kramer, R.A., Andersen, N. 6541-6545. Arima, K., Oshima, T., Kubota, I., Nakamura, N., Mizunaga, T., Toh-e, A. (1983) Nucl. Acids Res. ll-, 1657-1672. 2. lichel, M-L., Sorigo, P., Tiollais, P., Dejean, A., Brechot, C., Michel, Wain-Hobson, S. (1984) In: "Viral Hepatitis and Liver Diseases" (G.N. Vyas, J.L. Dienstag, J.H. Hoofnagle, fnagle, Eds) Grunt Fr Stratton, Inc., N&w York, ~~49-66.~ Beggs J.D. (1978) Nature 275, 104-109. Stinchcomb, D.T., Struhl, K., Davis, R.W. (1979) Nature E, 39-43, Dani, G-M., Zakian, V.A. (1983) Proc. Natl. Acad. Sci. USA Q 3406-3410. Larionov, V.,Kouprina, N., Karpova, T. (1984) Gene 28, 229-235.
608
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
October 30, 1986
Pages 602-608
EFFECT OF VECTOR TYPE, HOST STRAINS AND TRANSCRIPTION ON HETEROLOGOUS GENE EXPRESSION IN YEAST Kong-Bung
Choo,
Sheue-Mei
Wu, Li
Hung,and
Recombinant DNA Laboratory, Department Veterans General Hospital, Taipei, Taiwan Received
September
10,
TERMINATOR
Hsien-Hsiung
Lee
of Medical Research, 112, Republic of China
1986
Using the surface antigen gene of the hepatitis B virus, and the promoter and terminator sequences of the yeast pho5 gene as a a series of closely related expression plasmids were model system, constructed to investigate the effect of vector type, genetic background of host strains and the presence of transcription terminator on the expression of heterologous,gene in yeast. Plasmids carrying the replication origin of the 2~ plasmids were found to be much more stable than those either independently or simultaneously Gene expression was also higher with 2vmcarrying a&51 sequences. based plasmids. Yeast selection marker (ttlpl or eeu2) and therefore the host strains used did not have significant effects on gene expression. Addition of transcription terminator sequences downstream to the HBsAg gene also contributed only limited increases Q 1986 Academic Press, Inc. in gene expression levels. A wide
range
of biological
gene
expression.
have
several
with
no known pathogenicity
Among the distinct
man in brewery romosomal
hosts
industries.
systems
yeast
transformation
procedures
2) and a variety
of efficient
vectors
have
been
to suit
have
have
specific
described.
are
used
for
this
long
been
purpose,
yeasts
promoters
(3-5)
vectors
most
associated
studied
More
have now been well
Yeast
heterologous
with
and extrach-
been well
purposes.
for
common micro-organisms
The nuclear
of yeasts
manipulated
been
used
They
and they
easily
(1,
being
advantages.
and bakery
genetic
hosts
have
and are
importantly, established
and yeast commonly
cloning used
for
Abbreviations: a)Ldl, autonomously replicating sequences of yeast of replication of the 2pm plasmid; chromosome; 2um ohi, origin HBsAg, hepatitis B surface antigen; (k)b, (kilo)base pairs; Pi, inorgainc phosphate; S/N, ratio of sample value to negative value in radio-immunoassay for HBsAg. 0006-291X/86 Copyrighr All rights
$1.50 0 I986 b-k’ Academic, Press. oj reproduction in any ,fbrm
Inc. reserved.
602
Vol. 140, No. 2, 1986
gene
BIOCHEMICAL
expression
originally
have
cloned
carrying
the
plasmid
In
two types
related
carrying
yeast
constructed
to
of the
to systematically on gene
on gene
test
the
and the
the
sequences
(6)
and vectors
expression,
the
effects
of
of closely
of host
Plasmids
strains
were also
genetic
transcription
2pm
effect
a series
of different of
endogenous
compare
expression.
presence
a,tbl
yeast
to minimize
effect
RESEARCH COMMUNICATIONS
chromosomes
of replication
were designed
variables
MATERIALS
the
order
plasmids
strains
those
of vectors
and other
host
from
origin
(7).
these
been
AND BIOPHYSICAL
background
terminator
of
sequences.
AND METHODS
E,coLilyeast shuttle plasmids were Construction of shuttle plasmids: constructed according to standard procedures(8). E.coLi strain DH5 (9)was used in all E.co.& transformation experiments. The plasmids were transformed into yeast cells using the method of Ito et n!(2). Analysis of yeast transformants: In each experiment, transformants were grown in 10 1 f a mixture of phosphate-depleted YEPD (1% yeast extract, 2%mpeitone, 2% glucose) and minimal glucose medium (0.67% yeast nitrogen base, 2% glucose, 20 mg/ml uracil) in 1:4 ratio in 50 ml conical flasks at 30" for 36-40 h with vigorous rotary shaking at 200 rpm to A600 of 5-10. The cells were homogenized with glass beads and the homogenates were assayedfor HBsAg using the AusriaR kit from Abbott Laboratories as described (10). RESULTS AND DISCUSSION As a model host
strains
promoter were
for
the
investigation
and transcription
sequences
placed
of the
upstream
fragment
sequences
entire
to a 1.4 kb EcoRI-SaLI SalI of
site
to obtain
site
This
clone gene
(p2~-Sll) in
the
promoter
out
was corrected
and digesting
the
SueI
was obtained correct
acid
on gene
reading
in
of vector
(pho5)
two stages
(12)
carrying
the
This
rendered
of phase
using
by linearizing termini which frame(l0).
with
the
Bat31
gene
(Fig. pku5
was first
the upstream 116-5
The BaL31
1).
A
ligated the
reading
frame
pho5
initiation
at the
and religating.
showed expression
(11)
coding
HBsAg gene via
clone
type,
expression,
83 bp of the region
116-5.
effect
phosphatase
containing
fragment
the HBsAg sequence
codon.
yeast
clone
the
terminator
to the HBsAg gene
2.7 kb EcuRI-SaLI and the
of
of digestion
S&I A
the HBsAg resulted
Vol. 140, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
E.COIi
-
60131
1
w5
----_
p2p-SI
I
--em--
BE
H l.gKb-
phob terminator
E 8, .
3.OKbd 5SKb -
E
IL---
vql7,PW2-F*
psy97
YRp7-SllT p~u2-SI IT pShl97-Sl
Fig.
in retention gene,
IT
1. Construction of yeast expression plasmids for HBsAg gene. Clone 116-5 was first constructed by assembling the various components the origin of which is described in Fig. 2.and in the text. The excess sequences between the pho5 promoter and the HBsAg gene were removed by linearizing 116-5 with SaLI and digestion with B&Z31 to obtain p21+1-S11. The 1.9 kb BumHI fragment from p2u-Sll was inserted into pLeu2-F (Fig. 2) to obtain pLeu2-Sll. A 1.1 kb HpaII fragment was excised from the 3' region of the pho5 gene, the termini filled in with DNA polymerase and was then inserted at the HpaI(H) site at the 3' -end of the HBsAg gene of p2~-Sll to produce p2~-SllT. The3.0 kb BamHI or the 5.5 kb EcoRI(E) fragment was inserted into YRp7, pLeu2-F and pSM97 (Fig. 2) to obtain YRp7-SllT, pLeu2-SllT and pSM97-SllT. Open box, pho5 coding region; hatched box, HBsAg gene; filled box, pho5 terminator sequences.
of
the
13 amino acid
(13)
and the
entire
K.B.
Choo, unpublished
first
three
residues
amino acid
from the PreS2 region
HBsAg gene in plasmid
2pm o&i from pJDB219(14)
data).
residues
Plasmid
and the tap1 604
p2~-Sll
p2~-Sll marker
also (Fig.
from the
pho5
of HBV genome (H.H.
Lee and
contains 2).
the
Vol.
140,
No
BIOCHEMICAL
2, 1986
AND
(a)
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
(b)
(a) p'Zp-Sll; (b) pLeu2-F; 2. Plasmids used in the present study. source of the various fragments: (A) Cc) pSM97. Original 2.7 kb EcoRI-SaLI fragment from pAP20 (11, 12) containing the pho5 promoter. (B) 1.4 kb SaLI-EcoRI fragment from pTWS105 containing the HBsAg gene (unpublished); (C) 2.5 kb EcoRI fragment from pJDB219 (12) containing the 2urn origin of replication; (D) 4.4 kb icoR1 fragment from YRp7 (13) carrying the thpl and Tc genesbut without the ahnl sequence; (E) 3.3 kb Hind111 fragment from pJDB219 containing the eeu2 gene and the 2pm ori; (F) 2.7 kb Hind111 fragment of pUC9; (G) 1.4 kb EcoRI fragment from YRp7 with thpl gene and atrnl sequence; (H) 5.6 kb EcoRI fragment from SW9 (P. Nagley, personal con-munication) containing the Tcii gene and the ?vm
Fig.
Ohi.
In order terminator
to
the effect
on the expression
sequence
of
was inserted
SllT
the
at
was contained the
the
to obtain
into
F (2um ohi,
2) and pSM97 (both
2).
SllT
The resulting
and pSM-SllT
fragment
which
from p2u-Sll
does
of all columns
These plasmids strains Marked
which
contain
the
in Table
atlbl
pLeu2-F
plasmids
1).
Subfrom p2~-
terminator) pLeu2-
itrpl)(l5),
and 2urn
04i,
YRp7-SllT, the
(Fig.
pLeu2-
promoter-HBsAg was excised
1).
described
thpl)
The major
are summarized
1.
were transformed
were auxotrophic
differences
(a&Al,
the pho5 terminator into
six
downstream
(Fig.
For comparison,
and was inserted
characteristics in left-hand
not
a 1.1 kb
located
were designated
respectively.
terminator
gene-(pho5
vectors'YRp7
plasmids
transcription
3.0 kb EcoRI fragment
sequences was inserted
(Fig.
the
p2~-SllT
(pho5 promoter)-HBsAg
eeu2)(Fig.
of
within
site
HpcrI
1.9 kb BumHI or the
containing
the presence
of the HBsAg gene,
to the HBsAg gene in p2~-Sll sequently,
of
the phu5 gene which
fragment
HpaII
test
into
at the
in the genetic
-0~~1
stability 605
three
different
and/or of
the
host Leu2 loci.
the plasmids
were
t
pLeu2-SllT
t
t
t t
t
t 38
0
96
t
t
100
t
94
52
0
a5
66
a7
70
DB746
n.d.
n.d.
n.d.
n.d.
n.d.c
96
10.9
0
25
16.5
26
20
GN3C. 2
n.d.
n.d.
0 13.4
n.d.
n.d. 47.5
7.4
n.d.
35
20 16.9
YNN27
(S/N)b
DB746
HBsAg expression
of HBsAg gene in yeast
YNN27
Stabilitya
Plasmid GN3C.2
levels
and expression
t
t
Terminator
stability
93
Leu2
marker
plasmid
t
Thpl
Yeast
affecting
thpl
uha31
bTransformants were grown in 10 ml and homogenized with glass beads Abbott Labs. Values are averages c.1+,, and 11-11indicate presence or
[a,
Cell were of low Pi medium (10 mg/l Pi) to A660 = 5 - 10. (450 pm) and the lysates were.assayed for HBsAg using Ausria of 2-3 determinations. absence of the indicated sequences. n.d., not determined.
harvested kit from
aGenetic stability was determined by plating equal aliquots of transformant cells on minimal and rich colonies on YEPD plate) x 100. (Values on minimal plate/no. (YEPD) media. Stability = (No. colonies GN3C.2: [a, ecu2 t&pl]i DB746; [a, hid1 ecu2 thpl uhfd]; YNN27: are averages of 2-4 determinations).
pSM-SUT
t
t
pLeu2-Sll
YRp7-SllT
t
p2~-SllT
ahA
2vm
tc
type
Vector
1. Factors
p2u-Sll
Plasmid
Table
Vol.
140,
No. 2, 1986
observed very
in
BIOCHEMICAL
that
unstable
plasmid
while
some differences
of
the
is
also
reflected
less
expression but
in
DB746,
amounts
plasmids
Our results
yeast
vector
than
ahcll
There
with
used.
probably and are
of
recombination
a4bl
vectors,
results
in
studies
on the loci
(CEN)
reveal used
loss
have
been
and the
sequences HBsAg gene. may still
effect
presence
case,
the
putative
was positioned Localization have
greater
use of 2pm vectors,
important
factor
which
of the
in
250 bp from the
polyA
influence the affects
the
choice
the
signal
expression 607
of stable
In
are the
case
easily Recent
by centromeric did
of the
not
host
on gene
strains expression.
pho5 terminator
closer
expression.
of promoter
type
more
plasmids.
termination
on gene
effect
sequences
terminator of
differ-
2pm plasmids
background
signal
to produce
the
Our results
of transcription
of
is
sequences
17).
of genetic
polyA
that
the
exception
marker.
copy number.
au
(16,
the
significant
chromosomal
sequences
2pm 2-fold
significantly
fact
in high
described
the
hand,
no consistent
expression
are
with
of gene
other
seemed
the most
vectors
stabilization
significant
In our
the
the
for
as selection
gene
present
produced
With
however,
due to the
extrachromosomal
YRp7-SllT
On the
terminator
showed that
2pm-based
vectors
the
or 1~2
and therefore
stability
pSM-SllT
strains.
were,
thpl
therefore
stability
with
the presence
For any plasmid,
different
plasmids
of HBsAg.
between
on plasmid
with
in
HBsAg gene.
higher
with
strains.
The plasmid
is relatively
was
stable
host
average.
do exist.
sequence
reduced
of the
on the
COMMUNICATIONS
more
or no HBsAg while
some variations
of p2~-SllT
ences
expression
HBsAg gene
are observed
utrnl
different
was greatly
plasmids
differences
higher
among the
little
other
of the
plasmids
the
produced
HBsAg than
the
as shown by pSM-SllT.
in
transformants
RESEARCH
carrying
2urn plasmid
sequences
BIOPHYSICAL
were relatively
stability
of the
am1
YRp7-SllT
2pm plasmids
in
The stability
AND
codon to the Thus,
may be the
of foreign
of
genes
the
gene besides
more in
yeast.
Vol. 140, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
ACKNOWLEDGMENT
from
This work was supported by research the National Science Council of the
grant NSC75-0609-B075-01 Republic of China.
REFERENCES 1.
2. 3. 4. 5. 6. 7. a. 9. 10.
11. 12. 13.
:;: 16. 17.
Hinnen, A., Hicks, J-B., Fink, G.R. (1978) Proc. Natl. Acad. Sci. USA 75 1929-1938. Ito, H., Ekuda, Y., Murata, K., Kimura, A. (1983) 5. Bacterial. 153, 163-168. Miyanohara, A., Toh-e, A., Nozaki, C., Hamada F., Ohtoms, N., Matsubara, K. (1983) Proc. Natl. Sci. USA 80, l-5. Hitzeman, R.A., Chan, C. Y., Haige, F.K. et UL. (1983) Nucl Acids Res. I.& 2745-2763. Bitter, G., Chen, K.K., Banks, A.R., Lai, P.H. (1984) Proc. Nacl. Acad. Sci. USA 81, 5330-5334. D., Sherer, S., Davis, R. (1979) Proc. Struhl, K., Stinchcom6; Natl. Acad. Sci. USA 76, 1035-1039. Hollenberg, C.P. (1982) Curr. Topics Microbial. Immunol. 96, 119-114. Maniatis, T., Fritsch, E.F., Sambrook, J. (1982) Molecular Cloning: A Laboratory Manual. Cold Spring Harbor Laboratory, Cold Spring Harbor. Hahanan, D. (1985) In: "DNA Cloning: A Practical Approach" (D.M. Glover, Ed.) IRL Press, Oxford, pp109-136. Choo, K.B., Wu S.M., Lee, H.H., Lo, S.J. (1985) Biochem. Biophys Res. Commun. 131, 160-166. (1980) Proc. Natl. Acad. Sci. USA -77 Kramer, R.A., Andersen, N. 6541-6545. Arima, K., Oshima, T., Kubota, I., Nakamura, N., Mizunaga, T., Toh-e, A. (1983) Nucl. Acids Res. ll-, 1657-1672. 2. lichel, M-L., Sorigo, P., Tiollais, P., Dejean, A., Brechot, C., Michel, Wain-Hobson, S. (1984) In: "Viral Hepatitis and Liver Diseases" (G.N. Vyas, J.L. Dienstag, J.H. Hoofnagle, fnagle, Eds) Grunt Fr Stratton, Inc., N&w York, ~~49-66.~ Beggs J.D. (1978) Nature 275, 104-109. Stinchcomb, D.T., Struhl, K., Davis, R.W. (1979) Nature E, 39-43, Dani, G-M., Zakian, V.A. (1983) Proc. Natl. Acad. Sci. USA Q 3406-3410. Larionov, V.,Kouprina, N., Karpova, T. (1984) Gene 28, 229-235.
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