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A convenient cloning vector containing the GAL4 DNA-binding domain
Getw, 118 (1992) 14sI44
0 1992 Elwvier
GENE
065X5
Brief
Notes
Science Publishers
B.V. All rights reserved.
A convenient
cloning vector containing
(Recombinant
fusion proteins;
DNA;
Loretta Raycroft
Reccivcd
27 January
the GAL4 DNA-binding
domain
trans-activation)
and Guillermina
by R. Padmanabhan:
143
0378-I 119~92~905.00
Lozano
1992: Acccptcd:
I I March 1992: Received at publishers:
4 May 1992
SUMMARY
A DNA fragment encoding the yeast GAL4 DNA-binding domain (amino acids 3-147) was cloned into a convenient vector. This vector contains unique restriction sites at both the 5’ and 3’ ends and allows the generation of fusion proteins containing the GAL4 DNA-binding domain. These fusion proteins can be tested for their ability to activate transcription.
The function of the yeast transcription factor GAL4 has been studied in detail. Functionally, GAL4 consists of a DNA-binding domain (aa 1-147) and a transactivation domain (aa 148-881) (Keegan et al., 1986). Expression of GAL4 in mammalian cells will specifically transactivate a target gene containing the UAS to which GAL4 binds (Kakidani and Ptashnc, 1988). The DNA-binding domain of GAL4 has been extremely useful in the analysis of potential transcription factors in tissue culture. In particular, fusion proteins of the GAL4 DNA-binding domain and Myb or ElA have been important in defining transactivation domains (Weston and Bishop, 1989; Lillie and Green, 1989). Currently available plasmids encoding the GAL4 DNA-
C‘orre.vpor,tkrrc,r IO; Dr. G. Lozano, The University
Blvd., Box I I, Houston. Fax (713) 794-4295 Abbreviations: scription
factor:
Department
of Texas. M.D. Anderson
aa. amino
of Molecular
Cancer Center,
Genetics.
1515 Holcombe
TX 77030. USA. Tel. (713) 792-8945;
acid(s):
bp, base pair(s);
GAL4, gent encoding
GAL4:
G.4L4,
kb, kilobase
yeast tranor 1000 bp;
nt, nucleotidc(s); MCS, multlplc cloning site(s); PolIk, Klenow (large) fragment of E. co/i DNA polymerase I: UAS. upstream activating scqucnce.
binding domain allow the generation of fusion proteins in which GAL4 is placed only at the N terminus (Sadowski et al., 1988; 1992). Since the tumor suppressor ~53 contains a putative DNA-binding domain at the C terminus, we wished to generate a vector that would allow us to insert the GAL4 DNA-binding domain at the C-end of ~53. To do this, we digested pLK8. a yeast cloning vector containing the entire GAL4 sequence (a gift from P. Silver), with AccI, which cuts 55 bp upstream from the GAL4 start codon, and treated it with BAL 31 followed by Pollk. Subsequent digestion with CkrI, which cuts DNA at the site corresponding to aa 147 of GAL4, was used to clone this fragment into a pBluescript SK(-) plasmid (Stratagcne, La Jolla, CA) cut with Sinai + ClrlI. The resulting plasmid. pLR310, contained two TAG stop codons in the 5’ linker in frame with the GAL4 aa sequence. We linearized pLR3 10 with BarnHI, blunt-ended it with PolIk, and religated it to generate pLR60 (Fig. 1). This procedure shifted the two stop codons to a different reading frame and generated a new ClcrI site at the 5’ end of GAL4 which is sensitive to dutn methylation and is not cleaved by C/t/I. The nt sequences of both 5’ and 3’ ends of this GAL4 insert are shown in Fig. 1B. Since MCS are present at both ends of GAL4, this plasmid can bc used to gcncrate inframe fusion proteins to the GAL4 DNA-binding domain,
B 5' end T3 primer ATT
AAC
CCT
CAC
SacI
TAA
AGA
ACT
4
AGT
Not1
AGG GAA CAA AAG CTG GAG CTC CAC CGC GGT GGC GGC CGC
SpeI TCT
Sac11
5
6
7
8
9
10
11
12
GGA TCG ATC CCC CTG TCT TCT ATC GAA CAA GCA TGC GAT
XbaI
SphI
3' end xinc11 AccI
ApaI DraII
SalI
ACT GTA TCG ATA CCG TCG ACC TCG AGG GGG GGC CCG GTA CCC AAT TCG CCC ClaI
XhoI
XprrI
TAT AGT GAG TCG TAT T T7 primer Fig.
I. Maps of pLR60 and GAL4. (A) Some of the restriction
arrow indicates
the 5’.to-3’
direction
of the GAL4 sequcnccs.
sites in the MCS and the location
of T3 and T7 promoters
(boxes) arc shown. The long
The mtcrnal XhoI site in GAL4 occurs at aa 73. The C&I site marks the end of GAL4 (an
117). The C/u1 site in parentheses is sensitive to &rn mcthylation. (B) Scquencc of 5’ and 3’ ends of GAL4 (see A). Scquencc was determined usmg the didcoxy chain-termination method. T7 or T3 primers. and Scquenasc (USB, Cleveland. OH). Codons arc drawn in frame with the G11L-I acqucncc.
Numbers primers
above the nt sequcncc
refer to GALJ-encoding
aa [see Laughon
and Gestcland
(19X4) for GnL4
scqucncc].
Restriction
sites and T3 and T7
arc underlined.
in the middle, or at the C terminus of another protein. Plasmid pLR60 has been used successfully to generate p53GAL4 fusion proteins and to test the function of p53 as a transcription factor (Raycroft et al., 1990; 1991). Support
was provided
Laughon.
A. and Gcstcland.
c~ere~i.~icrr GAL4
gent.
Lillic, J.W. and Green, Ela protein. Raycroft,
Raycroft.
L.. Wu H. and Lozano,
L.. Schmidt.
Sadou-ski, in mam-
Keegan, L.. Gill, G. and Ptaahne, M.: Separation of DN.4 binding from the transcription-activating function of a cukaryotic regulator> protcin. Science 23 1 (1986) 699-704.
Sadowski,
activation
b> the adenovti-us
G.: Transcriptional
mutants
acti\sation
b) wild-
of the p53 anti-oncogenc.
J.R.. Yeas. K.. Hao, M. and LoLano, for transcriptional
acitivity.
Scicncc G:
Ana-
Mol. Cell. Biol.
II
1.. Bell. B.. Broad, P. and Hollis, M.: G,4L4 fusion vectors fat
expression gent expression
of the S~c.c~hrrw~iir~c~c~~
338 (1989) 39-44.
)sis of p53 mutants (1991) 6067-6074. REFERENCES
structure
M.R.: Transcription
Nature
type but not transforming 249 (1990) 1049-1051.
by NIH grant CA47296
Kakidani. H. and Ptashne. M.: GAL4 activates malian cells. Cell 52 (1988) 161-167.
R.F. Primnr)
Mol. Cell. Biol. 4 (1984) 260-267.
in least
or mammalian
I., Ma. J., Triezcnberg,
unusually 564.
potent
transcriptional
Vt’cston. K. and Bishop,
cells. Gcnc
11X (1992) 137-141.
S. and Ptashne,
M.: GAL4-VP16
activator.
335
J.M.: Transcriptional
oncogcnc and its cellular progenitor. c-r,rth
Nature
activation
is an
(I 988) 563bq the \-fit)+)
Cell SX (19X9) X5-93.
0 1992 Elwvier
GENE
065X5
Brief
Notes
Science Publishers
B.V. All rights reserved.
A convenient
cloning vector containing
(Recombinant
fusion proteins;
DNA;
Loretta Raycroft
Reccivcd
27 January
the GAL4 DNA-binding
domain
trans-activation)
and Guillermina
by R. Padmanabhan:
143
0378-I 119~92~905.00
Lozano
1992: Acccptcd:
I I March 1992: Received at publishers:
4 May 1992
SUMMARY
A DNA fragment encoding the yeast GAL4 DNA-binding domain (amino acids 3-147) was cloned into a convenient vector. This vector contains unique restriction sites at both the 5’ and 3’ ends and allows the generation of fusion proteins containing the GAL4 DNA-binding domain. These fusion proteins can be tested for their ability to activate transcription.
The function of the yeast transcription factor GAL4 has been studied in detail. Functionally, GAL4 consists of a DNA-binding domain (aa 1-147) and a transactivation domain (aa 148-881) (Keegan et al., 1986). Expression of GAL4 in mammalian cells will specifically transactivate a target gene containing the UAS to which GAL4 binds (Kakidani and Ptashnc, 1988). The DNA-binding domain of GAL4 has been extremely useful in the analysis of potential transcription factors in tissue culture. In particular, fusion proteins of the GAL4 DNA-binding domain and Myb or ElA have been important in defining transactivation domains (Weston and Bishop, 1989; Lillie and Green, 1989). Currently available plasmids encoding the GAL4 DNA-
C‘orre.vpor,tkrrc,r IO; Dr. G. Lozano, The University
Blvd., Box I I, Houston. Fax (713) 794-4295 Abbreviations: scription
factor:
Department
of Texas. M.D. Anderson
aa. amino
of Molecular
Cancer Center,
Genetics.
1515 Holcombe
TX 77030. USA. Tel. (713) 792-8945;
acid(s):
bp, base pair(s);
GAL4, gent encoding
GAL4:
G.4L4,
kb, kilobase
yeast tranor 1000 bp;
nt, nucleotidc(s); MCS, multlplc cloning site(s); PolIk, Klenow (large) fragment of E. co/i DNA polymerase I: UAS. upstream activating scqucnce.
binding domain allow the generation of fusion proteins in which GAL4 is placed only at the N terminus (Sadowski et al., 1988; 1992). Since the tumor suppressor ~53 contains a putative DNA-binding domain at the C terminus, we wished to generate a vector that would allow us to insert the GAL4 DNA-binding domain at the C-end of ~53. To do this, we digested pLK8. a yeast cloning vector containing the entire GAL4 sequence (a gift from P. Silver), with AccI, which cuts 55 bp upstream from the GAL4 start codon, and treated it with BAL 31 followed by Pollk. Subsequent digestion with CkrI, which cuts DNA at the site corresponding to aa 147 of GAL4, was used to clone this fragment into a pBluescript SK(-) plasmid (Stratagcne, La Jolla, CA) cut with Sinai + ClrlI. The resulting plasmid. pLR310, contained two TAG stop codons in the 5’ linker in frame with the GAL4 aa sequence. We linearized pLR3 10 with BarnHI, blunt-ended it with PolIk, and religated it to generate pLR60 (Fig. 1). This procedure shifted the two stop codons to a different reading frame and generated a new ClcrI site at the 5’ end of GAL4 which is sensitive to dutn methylation and is not cleaved by C/t/I. The nt sequences of both 5’ and 3’ ends of this GAL4 insert are shown in Fig. 1B. Since MCS are present at both ends of GAL4, this plasmid can bc used to gcncrate inframe fusion proteins to the GAL4 DNA-binding domain,
B 5' end T3 primer ATT
AAC
CCT
CAC
SacI
TAA
AGA
ACT
4
AGT
Not1
AGG GAA CAA AAG CTG GAG CTC CAC CGC GGT GGC GGC CGC
SpeI TCT
Sac11
5
6
7
8
9
10
11
12
GGA TCG ATC CCC CTG TCT TCT ATC GAA CAA GCA TGC GAT
XbaI
SphI
3' end xinc11 AccI
ApaI DraII
SalI
ACT GTA TCG ATA CCG TCG ACC TCG AGG GGG GGC CCG GTA CCC AAT TCG CCC ClaI
XhoI
XprrI
TAT AGT GAG TCG TAT T T7 primer Fig.
I. Maps of pLR60 and GAL4. (A) Some of the restriction
arrow indicates
the 5’.to-3’
direction
of the GAL4 sequcnccs.
sites in the MCS and the location
of T3 and T7 promoters
(boxes) arc shown. The long
The mtcrnal XhoI site in GAL4 occurs at aa 73. The C&I site marks the end of GAL4 (an
117). The C/u1 site in parentheses is sensitive to &rn mcthylation. (B) Scquencc of 5’ and 3’ ends of GAL4 (see A). Scquencc was determined usmg the didcoxy chain-termination method. T7 or T3 primers. and Scquenasc (USB, Cleveland. OH). Codons arc drawn in frame with the G11L-I acqucncc.
Numbers primers
above the nt sequcncc
refer to GALJ-encoding
aa [see Laughon
and Gestcland
(19X4) for GnL4
scqucncc].
Restriction
sites and T3 and T7
arc underlined.
in the middle, or at the C terminus of another protein. Plasmid pLR60 has been used successfully to generate p53GAL4 fusion proteins and to test the function of p53 as a transcription factor (Raycroft et al., 1990; 1991). Support
was provided
Laughon.
A. and Gcstcland.
c~ere~i.~icrr GAL4
gent.
Lillic, J.W. and Green, Ela protein. Raycroft,
Raycroft.
L.. Wu H. and Lozano,
L.. Schmidt.
Sadou-ski, in mam-
Keegan, L.. Gill, G. and Ptaahne, M.: Separation of DN.4 binding from the transcription-activating function of a cukaryotic regulator> protcin. Science 23 1 (1986) 699-704.
Sadowski,
activation
b> the adenovti-us
G.: Transcriptional
mutants
acti\sation
b) wild-
of the p53 anti-oncogenc.
J.R.. Yeas. K.. Hao, M. and LoLano, for transcriptional
acitivity.
Scicncc G:
Ana-
Mol. Cell. Biol.
II
1.. Bell. B.. Broad, P. and Hollis, M.: G,4L4 fusion vectors fat
expression gent expression
of the S~c.c~hrrw~iir~c~c~~
338 (1989) 39-44.
)sis of p53 mutants (1991) 6067-6074. REFERENCES
structure
M.R.: Transcription
Nature
type but not transforming 249 (1990) 1049-1051.
by NIH grant CA47296
Kakidani. H. and Ptashne. M.: GAL4 activates malian cells. Cell 52 (1988) 161-167.
R.F. Primnr)
Mol. Cell. Biol. 4 (1984) 260-267.
in least
or mammalian
I., Ma. J., Triezcnberg,
unusually 564.
potent
transcriptional
Vt’cston. K. and Bishop,
cells. Gcnc
11X (1992) 137-141.
S. and Ptashne,
M.: GAL4-VP16
activator.
335
J.M.: Transcriptional
oncogcnc and its cellular progenitor. c-r,rth
Nature
activation
is an
(I 988) 563bq the \-fit)+)
Cell SX (19X9) X5-93.