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Vectors that facilitate the expression and purification of foreign peptides in Escherichia coli by fusion to maltose-binding protein
21
Gene, 67 (1988) 21-30 Elsevier GEN 02422
Vectors that facilitate the expression and purification of foreign peptides in EscRericRia coli by fusion to maltose-binding protein (Recombinant
DNA;
plasmids;
cross-linked
amylose
affinity chromatography;
starch)
Chu di Guana, Ping Lib*, Paul D. Riggs” and Hiroshi Inouyeb+ “New England BioLabs, Beverly, MA 01915 (U.S.A.) and bDepartment of Biology, Temple University,Philadelphia, PA 19122 (U.S.A.) Tel. (215) 787-8877 Received
31 August
Accepted
31 October
Revised Received
1987
25 February
1987 1988
by publisher
11 March
1988
SUMMARY
Vectors were constructed that allow foreign peptides to be expressed in Escherichia coli as fusion proteins. The peptides are fused to the C terminus of maltose-binding protein (MBP), which allows them to be purified by the MBP’s affinity to cross-linked amylose (starch). The fusion protein can be directed to the periplasm by including the leader sequence from the phoA gene on the vector.
INTRODUCTION
some-binding site and translation start of the 1ac.Z gene. Such hybrid proteins can be purified by affinity chromatography using antibody to /I-galactosidase. An alternative approach to the expression and puriti-
Gene fusions have been used successfully to facilitate the expression and purification of peptides produced from recombinant DNA molecules (Lowenadler et al., 1986; Shuman et al., 1980; Shuman and Silhavy, 1981; Sugita et al., 1985). Most commonly, target peptides have been fused to j&galactosidase, so that the peptide is expressed in Escherichia coli as a fusion protein using the ribo-
cation of foreign peptides is to fuse them to a specific binding protein. The hybrid protein can then be purified by affinity chromatography using the binding protein’s substrate. In the present study, we chose for this purpose MBP, the product of the malE gene of E. coli K-12.
Correspondence to: Dr. P.D. Riggs, New England
phosphates;
Tozer Road,
Beverly,
MA 01915 (U.S.A.)
* Present
address:
Department
Genetics,
Harvard
University
02115 (U.S.A.)
of Microbiology Medical
Biolabs,
32
Tel. (617) 927-5054. School,
and Molecular Boston,
MA
Tel. (617) 732-1921.
maltose
buffer, see MATERIALS
MBP, maltose-binding
Ap, ampicillin; dNTP,
bp, base pair(s); d, deletion;
any of the four deoxynucleotide
Cm,
pyranoside;
tri-
0378-l 119/X8/$03.50 0 1988 El sevier Science Publishers B.V. (Biomedical
Division)
XGal,
liquid chromatography; kb,
kilobases
AND METHODS,
protein; phoA,,
PolIk, Klenow (large) fragment tetracycline;
chloramphenicol;
high-performance
isopropyl-/l-D-galactoside;
gene that codes for the alkaline
t Deceased. Abbreviations:
HPLC,
IPTG,
1000 bp; section c;
, the portion of the phoA
phosphatase of6.
or
signal sequence;
coli DNA polymerase
I; Tc,
5-chloro-4-bromo-3-indolyl$-o-galacto-
[ 1,designates
plasmid-carrier
state; :: , novel joint.
22
Some advantages express and purify
of using fusions to MBP to foreign peptides are outlined
below.
proteins
First, hybrid
single chromatography
can be isolated
step. MBP binds
1982). Second, the materials for aftlnity chromatography are inexpensive and easy to prepare, making large-scale purification simple and feasible. Third, unlike antibody affinity resins, the whole purification takes place under physiological conditions, and protein denaturation upon elution from the affinity matrix should not occur. Fourth, the fused protein can potentially be directed into different cellular compartments by varying the leader sequence of MBP. Finally, MBP does not contain any cysteine residues that could interfere with disulfide bond formation within the target peptide.
AND METHODS
(a) Bacterial strains and culture conditions Bacterial strains are listed in Table I. Bacteria were grown in rich medium containing (per liter) 10 g tryptone, 5 g yeast extract and 5 g NaCl. Antibiotics were purchased from Sigma, and were added when required as follows: 100 pg Ap/ml, 20 pg Cm/ml, 20 pg Tc/ml. The /I-galactosidase indicator, XGal, was added at 20 pg/ml, and the gratuitous inducer IPTG was added to a final concentration of 1 mM
TABLE
and IPTG
were
(b) Expression of the gene fusions and preparation of crude cellular extracts
results in a high yield and a high degree
of purity, as has been demonstrated for MBP itself (Ferenci and Klotz, 1978; Kellerman and Ferenci,
MATERIALS
XGal
in a
with high
affinity to a cross-linked amylose matrix, and is released from the matrix by 10 mM maltose. This purification
to induce the lac promoter. purchased from Sigma.
Cells containing proteins
plasmids
under lac promoter
that coded control
for fusion
were grown to
5 x lo8 cells/ml at 37°C with shaking in rich medium, IPTG was added to a final concentration of 1 mM, and the culture was grown for an additional 2 h. All subsequent steps were carried out at 4’ C or on ice. The cells were harvested by low-speed centrifugation, resuspended in l/l0 vol. of 10 mM Tris - HCl pH 7.2, and lysed by sonication. Cellular debris was then pelleted by high-speed centrifugation, and the supernatant was saved as crude cellular extract. Crude cellular extracts of cells bearing for pCG828 were prepared as described above, except that 1 y0 Triton X- 100 was included in the extraction buffer in case the signal sequence in this construct leads to the association of the hybrid protein with the membrane. For the phoA ss : : malE: :phoA fusion, the strain MZ20 (A phoA A malB phoR [ pPL-6A’ 1) was grown to 5 x log/ml in rich medium and the cells were harvested. A periplasmic fraction was prepared by cold osmotic shock and by spheroplast formation as described by Neu and Heppel (1964; 1965). (c) Cbromatographic teins
purification of the hybrid pro-
Preparation of cross-linked amylose from amylose (Sigma Cat. No. A-9262) and its use as an afI?nity
I
Escherichia coli strains Strain
Genotype
RR1
hsdS20
CG864
RR1 AmalB zjc::Tn5
Source/Reference ara-14proA2
lacy 1 galK2 rpsL20 xyl-5 mtl-1 supE44
Maniatis
lon::TnlOAl6All
this work
SF1362
A(lac)X74
MZ20
A(Iac)X74 phoA20 phoR hpam
araD 139 A(araABC-leu)7679
JM83
ara A(lac-proAB)
71-18
A(lac-proAB)
rpsL (480lacZAM
thi supE [F’
galU galK rpsL thi AmalB zjc::TnS
AmalB rpsL 15)
proA+B+ IacP lacZAM151
et al. (1982)
S. Froshauer J. Beckwith Yanisch-Perron
et al. (1985)
Yanisch-Perron
et al. (1985)
23
chromatography
matrix was performed
as described
by Kellerman
and Ferenci
(1962). Hybrid
were purified
from
extracts
crude
proteins
by binding
to
cross-linked amylose in a 3 cm x 6 cm column, and were eluted with 10 mM Tris - HCl buffer containing 10 mM maltose
(maltose
plasm.
pCG806
sequence,
contains
and potentially
the normal
maZE signal
allows the export
hybrid protein into the periplasm.
High-level
sion of the hybrid protein can be induced IPTG or lactose to the culture medium.
of the expres-
by adding
buffer). (b) Construction of the malE: : 1ac.Z gene fusions
(d) Immunodiffusion A malE : : IacZ gene fusion containing Reagents
for two-dimensional
were purchased was performed
from BioRad, according
and the procedure
to the manufacturer’s
in-
structions. Antiserum directed against MBP was kindly provided by Dr. P. Bassford. Antibody directed against PstI endonuclease was kindly provided by Dr. M. Philipp. Antibody directed against /I-galactosidase was purchased from Promega Biotec.
RESULTS
AND DISCUSSION
(a) Maltose-binding
almost all of
the ZacZ gene (and thus coding for fl-galactosidase
immunodiffusion
protein fusion vectors
To facilitate the construction and expression of protein fusions to MBP, two fusion vectors, pCG150 and pCG806, have been constructed (Fig. 1). Both plasmids are derivatives of pUC18 (Yanisch-Perron et al., 1985) and contain a portion of the maZE gene with (pCG806) or without (pCG150) its signal sequence, fused to the lacZcl coding sequence. The fusion protein is expressed from the lac promoter and confers a Lac + phenotype on strains containing the ZacZdMlS deletion (cr-complementation; e.g., see Yanisch-Perron et al., 1985). The insertion of cloned sequences into the polylinker of pCG150 or pCG806, which is located between malE and lacZa, abolishes the a-complementation. Any peptidecoding sequence can be cloned into the polylinker regions of these two plasmids. If the cloned insert is not in the proper translational reading frame to produce a hybrid protein, modifications to shift it inframe can be carried out at other sites in the polylinker. Thus, on plates containing XGal and IPTG, colonies of JM83 cells containing the vector alone are blue while recombinants are white. The malE region on pCG150 lacks a signal sequence, and is designed to produce the hybrid protein in the cyto-
activity without
requiring
a-complementation)
was
constructed as follows. Plasmid pCG150 was cleaved with BamHI + PvuII and a 1.2-kb DNA fragment was purified by gel electrophoresis. This fragment contains the lac promoter and the lacZ translation start fused to codons 28-392 of the malE gene (mature MBP is coded for by codons 27-396). This fragment was inserted into plasmid pMLB 1034 (Silhavy et al., 1984) that had been cleaved with EcoRI, tilled in with PolIk and dNTPs, then cleaved with BamHI. pMLB1034 contains the whole ZacZ gene except for the- promoter and the first eight codons. The resulting plasmid, pCG325, codes for an in-frame malE: : ZacZ-coded hybrid protein that produces P-galactosidase activity without a-complementation (Fig. 2). (c) Construction
of the maZE:: PstI endonuclease
gene fusion The maIE: : PstI endonuclease gene fusion was constructed as illustrated in Fig. 3. The PstI restriction system is comprised of two divergently transcribed genes, one coding for the endonuclease PstI and the other for the modification methylase (M *PstI). It has been cloned on a 4-kb DNA fragment inserted into the Hind111 site of pBR322 (pGW4400, provided by G. Wilson; also see Walder was excised with et al., 1984). This fragment HindIII, purified, circularized by ligation with T4 DNA ligase, and then cleaved with HincII to invert the two divergent genes and to separate the PstI endonuclease gene from its promoter. The fragment was then inserted into the HincII site of pUC18, creating plasmid pCG228. A BamHI-Hind111 fragment containing the endonuclease gene without the promoter and the first eight codons was cut from pCG228, purified, and then inserted into pCG150 and pCG806 in place of the small BamHI-Hind111
pCG150 y%oRI~
y&c11
[--KpIfiSmal~
~SUCI-J
rK@Il
. . . ATGACCATGATTACGAATTCGAGCTCGGTACCCGGGCGAGCTCGGTACCCA
TTCGAAGAA --PstI-,
rBamHIl
mdE sequence ------------
[- ,SphI 1
rHindIII
rXbuI-~
r.SalI
1
r
GCGCAGACTGGGGATCCTCTAGAGTCGACC
1
CacZ
TGC AGG CAT GCA AGC TTG -
. . .
pCG806 CAGACTAATTCGAGCTCGGTACCC
. malE sequence-
.
~BamHI1
r X&z17 r--- SalI -J r- PstI --q rSphI~
rHindII1
1
GGG GAT CCT CTA GAG TCG ACC TGC AGG CAT GCA AGC TTG w Fig. 1. Structure restriction
of MBP fusion vectors.
sites present
as described
by Maniatis
(Yanisch-Perron
EcoRI-J$i&I
is the 1.2-kb Hid portion
et al. (1982); restriction
it is the normal
(filled-in) fragment fragment
1977). Double-stranded pCGI50,
enzymes
All plasmids
translation
initiation
corresponds
the signal sequence
of the polylinker
regions.
DNA was used as a template.
37.5-383 (the region of malE just preceding to the 392nd codon
Ap-resistance
of malE. For pCG806,
lac promoter.
Both plasmids
To sequence
manuscript sequencing
including
are based
on pUC18 translation
The malE region of pCG150
out as described
(Sanger
the gene fusion joint region, a primer corresponding
and LeZcr) was used (provided MBP),
by New England
et al., to the
Biolabs).
For
and the ACT codon in bold print
the ACT codon in bold print once again refers to the 392nd codon that the gene is truncated
is the
the malE region ofpCG806
see Duplay et al., 1984). The lower
was carried
aa of mature
the
DNA techniques
this site is the lacZa
in preparation);
of malE (C. Lee, unpubl.;
Nucleotide
the polylinker
before or after the name of a gene indicates
gene; P,,,
Biolabs.
sites; on pCG150
. .
and pCG806,
using recombinant
start followed by the mdE signal sequence.
the GAA codon in bold print is the 28th codon of m&E (the second
A prime notation
of pCG150
were constructed
were from New England
from pPL-5A (P.L., H.I. and J. Beckwith,
from pmalE, and includes
plasmid
of the figure shows the structure
circles represent
m&E translation
of the figure shows the sequence
maZE codons
The upper portion
regions of these plasmids.
et al., 1985). The blackened
start and on pCG806 l.l-kb
in the polylinker
k&5?
at the N or C terminus,
of malE.
respectively.
Ap,
25
methylase,
codonof malE
t
strain
was cotransformed nuclease pCG1001, methylase
CG864
(RR1 AmaZE Zen: : TnlO)
with a plasmid bearing the endo-
gene (either pCG410
or pCG828)
and with
a plasmid bearing the modification gene. pCGlOO1 is a pACYC184-based
plasmid (Chang and Cohen, 1978), and is compatible with the pUC18-based
\ +o plylinker
2-3 “4
0
.P
plylinker
.
pPL-6A’
% 0 %
. -----
PstI endonuclease
(4 MA ss: : malE: :phoA gene
plasmids.
fusion
AphoA ss : : maZE: :phoA fusion was constructed to test whether MBP hybrid proteins could be directed to the periplasmic space. The structure of the plasmid bearing this fusion, pPL-6A’, is shown in Fig. 2. The details of this construction will be presented elsewhere (P.L., H.I. and J. Beckwith, manuscript in preparation). As described in section e, below, and in Table II, thephoA,, signal peptide could direct the hybrid protein to the periplasmic space. Although thephoA signal sequence was used in this example, the generalized vector pCG806 was constructed with the maZE signal sequence. It is anticipated that the MBP signal peptide would direct hybrid proteins to the periplasm in the same manner.
K”
Fig. 2. Structure
of pCG325
the figure shows constructed pCG150
by inserting between
pMLB1034
28-392.
This plasmid
the 1.2-kb PvuII-BamHI
the EcoRI
shows the structure
plasmid
The upper portion
of pCG325.
fragment
(filled in) and BamHI
(Silhavy et al., 1984). The lower portion
of this plasmid Beckwith,
and pPL-6A’.
the structure
of pPL-6A’.
is identical
elsewhere
in preparation). to that
of pCG325,
The region 5’ to ma/E contains
the first 21 codons
ofphoA (phoA,,),
phatase
signal
contains
most of the remainder
(corresponding This plasmid
peptide.
1985). Solid and dashed the indicated
Solid circles
represent
notations
are as in Fig. 1.
and
3’ to the malE sequence alkaline
from pHI28
genes; arrowheads
scription.
in this codons
the alkaline phos-
lines indicate
indicate
at codon 33 phosphatase).
(H.I., unpublished),
and pCH2 (Hoffman
concentric
and J.
the phoA promoter
of phoA, starting
to the 12th aa of mature was constructed
(P.L., HI. comprising
encoding
The region
pm&E (C. Lee., unpublished)
of the figure
The malE sequence
and Wright, the extent of
the direction
translation
start
(e) Purification
of the hybrid proteins by affinity
chromatography
from
sites of
The details of the construction
will be presented
manuscript
of
was
of tran-
sites. Other
fragment. The resulting plasmids, pCG410 and pCG828, respectively, contain in-frame m&E : : PstI endonuclease gene fusions. Since the PstI restriction gene is lethal to E. coli K-12 in the absence its cognate
The MBP-/3-galactosidase hybrid protein was purified from SF1362[pCG325] by cross-linked amylose affinity chromatography as described in MATERIALS AND METHODS, section d. Crude extract from 1 liter of cells contained approx. 350 mg total protein and 760 000 units of /?-galactosidase activity (Miller, 1972). Using a theoretical specific activity for the hybrid protein of 225 000 units/mg (the specific activity of native /?-galactosidase corrected for the M, of the hybrid protein), it is estimated that the hybrid protein represents about 1% of the total protein. More than 70% of the fi-galactosidase enzymatic activity present in the crude extracts bound to the cross-linked column and was eluted with maltose buffer. This fraction contained 540 000 units of /I-galactosidase, and SDS-polyacrylamide gel analysis (see below) revealed that 90% of the protein was the size predicted for the hybrid protein. The /I-galactosidase activity that did not bind to the column could not be accounted for by a limitation of the capacity of the column; when this fraction was
26
r( Hind111
HindIII
Hind111 purified fragment
1
t Him11 T4Ligase
I
HincII
HincII
Ap
HincII
.-
Fig. 3. Construction in RESULTS
of MBP::PstI
(MBP-endonuclease)
AND DISCUSSION,
The solid circles represent
translation
coding region. The Hind111 fragment
fusion plasmids.
Details of the construction
section c. M and R refer to the PstI modification start sites, with the dashed ofpGW4400
arrows
was purified, circularized
indicating
methylase the direction
of pCG410
and endonuclease of transcription
and pCG828
are given
genes, respectively. and the extent of the
by ligation with T4 DNA ligase, and then cleaved with HincII
21
TABLE II Localization of alkaline phosphatase activity produced by the phoA,:
:malE: :phoA fusion
Alkaline phosphatase activitya
Cold osmotic shockb Released from spheroplasts”
In periplasm
In cytoplasm + membranes
% periplasmic
0.22 0.13
0.028 0.021
89 86
a Alkaline phosphatase activity was assayed as described by Brickman and Beckwith (1975). 2.5-ml cultures of MZ20[pPL-6A’] were harvested and washed as described, and the alkaline phosphatase assays were performed on 10 pl of 200 ~1 periplasmic and cellular fractions. Activity is expressed as the change in A,,,/min. b Periplasmic and shocked-cell fractions were prepared as described by Neu and Heppel (1965). c Periplasmic and spheroplast fractions were prepared as described by Neu and Heppel(1964).
all of the b-galactosidase activity still passed through the column. The fraction of the fi-galactosidase activity that originally was eluted with maltose buffer was dialyzed against 10 mM Tris * HCl, pH 7.2, and applied to a fresh column; all of the /I-galactosidase activity once again bound to the column and could be eluted with maltose buffer. These results suggest that the /I-galactosidase activity present in the flow-through represents a fraction of the hybrid protein that is cleaved to give an active /I-galactosidase fragment lacking the maltose-binding activity. The MBP-PstI fusion protein was purified as follows. The crude extracts from strains containing pCG410 and pCG828 were applied to a cross-linked amylose column and chromatography was performed as described in MATERIALS AND METHODS,
ases (not shown). From 1 liter of culture, approx. 100000 units of PstI activity could reproducibly be recovered from the affinity purification. Since native PstI endonuclease exists as a dimer, and the MBPPstI hybrid protein appears to be cleaved at the joint
section d. In both cases, 90-95 y0 of the total restriction enzyme activity in the crude extracts passed through the column. The remaining 5-10% of the PstI activity could be eluted from the column by maltose buffer. As judged by restriction assays using 1 DNA, the protein that was purified from the amylose column had the same site specificity as native PstI, and was free from contaminating nucle-
d. As shown in Table II, SS-90% of the alkaline phosphatase activity produced was present in the periplasm; of this fraction, 90 y0 of the activity was retained on the amylose column and eluted with maltose buffer. This demonstrates that the presence of a signal peptide can direct this hybrid protein to the periplasmic space.
applied
to a fresh amylose column,
region
in
ViVO
(See
RESULTS
AND
DISCUSSION,
section f), it is not known whether the hybrid protein accounts for all of this endonuclease activity; for example, some of the activity could arise from mixed dimers of the hybrid protein and the PstI portion of the cleaved hybrid. The hybrid protein produced by the phoA,,: : maIE: :phoA fusion was purified as follows. The osmotic shock fluid from cells bearing pPL-6A’ was dialyzed against 10 mM Tris +HCl, pH 7.2, and applied to a cross-linked amylose column, and chromatography was performed as described in MATERIALS AND METHODS, section
to invert the two divergent genes and to separate the PstI endonuclease gene from its promoter. The fragment was then inserted into the HincII site ofpUC18, creating plasmid pCG228. A BarnHI-Hind111 fragment containing the endonuclease gene without the promoter and the first eight codons was cut from pCG228, purified, and then inserted into pCGl50 and pCG806 in place of the small BamHI-Hind111 fragment. The resulting plasmids, pCG410 and pCG828, respectively, contain in-frame malE_PstI endonuclease gene fusions. pCG410 lacks the malE signal sequence (‘malE’) while pCG828 includes the normal malE translation start and signal sequence (malE’).
28
gel anal-
ysis of the hybrid proteins
scribed in MATERIALS AND METHODS, section f, and in Fig. 4. For the MBP-P-galactosidase hybrid protein, the major band on the gel had an apparent M,
The fractions that were eluted with maltose buffer were pooled, concentrated and analyzed by SDS-polyacrylamide gel electrophoresis as de-
of 156 x 103, as predicted by the sequence of the gene fusion. Minor bands, which are presumed to be degradation products of the hybrid protein, were also
(f) Sodium dodecyl sulfate-polyacrylamide
205K 205K 116K 97.4K
116K 97.4K
45K
45K
29K 29K
B
A Fig. 4. SDS-polyacrylamide acrylamide Centricon
g&l electrophoresis microconcentrators
gel analysis of MBP$-galactosidase as described (Amicon)
(Laemmli,
according
to the gel. Gels were run at 30 mA (constant MW-SDS-200) B (97.4 kDa), phoresis
carried
were bovine carbonic b-galactosidase
(116 kDa),
out on protein fractions
eluted from the cross-linked 1, purified MBP.
protein
instructions.
and stained with Coomassie
and myosin
(205 kDa).
from cells bearing
polyacrylamide
eluted from the cross-linked
Proteins
were concentrated A 5-lo-pg
brilliant
were analysed lo-20
by SDS-poly-
x by ultrafiltration
sample of each protein
blue. Proteins
in
was applied
used as M, markers
(Sigma
(29 kDa), egg albumin (45 kDa), bovine serum albumin (66 kDa), rabbit phosphorylase pCG325.
(K = kDa). Lanes:
gel electrophoresis amylose
(Panel A) 0.1 y0 SDS-7%
1, M, markers;
amylose column with maltose buffer; 4, flow-through
extract. (Panel B)0.1 y0 SDS-lo%
hybrid proteins.
to be analyzed
to the manufacturer’s
current)
anhydrase
and MBP-PstI
1970). Samples
from the cross-linked
carried out on protein fractions
column with maltose
polyacrylamide
gel electro-
2, purified MBP; 3, purified hybrid protein
buffer; 2, purified
amylose column;
5, crude cellular
Tom cells bearing pCG410.
native PstI endonuclease;
Lanes:
3, purified
29
present.
HPLC
fraction
indicated
retained
fl-galactosidase
SDS-gel hybrid
separation that
analysis
protein
signal sequence) to that predicted
156-kDa
species
of maltose-eluted by PCG410
showed three bands.
a
The top-most
A4, of 78 x 103, corresponding The
two lower bands corresponded to 40 kDa and 45 kDa (mature MBP runs at about 40 kDa), and comprised 90% of the total protein in the maltoseeluted fraction. This indicates
that the hybrid protein
is sensitive to one or more host proteases, which cleave with some specificity at the joint region of the fusion. The identical analysis with the maltose-eluted fraction prepared from cells bearing pCG828 (with a malE signal sequence) showed three bands in the same relative positions, with the position of the two lower bands indicating a slightly higher M, (not shown). Only 20 y0 of the PstI enzymatic activity was released in the shock fluid of cells bearing pCG828, indicating that the hybrid protein was not efficiently secreted into the periplasmic space. (g) Immunological
in turn facilitate
This purification
MBP-PstI (lacking
from the gene fusion sequence.
using the vectors pCG1.50 and pCG806;
these fusions hybrid protein
activity (not shown).
produced
band had a apparent
to construct
of the maltose-eluted
only the
analysis of the hybrid proteins
Two-dimensional immunodiffusion analysis was performed on the maltose-eluted fraction from cells bearing pCG325. This fraction formed a single precipitin line both with antiserum directed against MBP and with antiserum directed against /?-galactosidase (not shown). Native P-galactosidase formed a precipitin line only with the anti+galactosidase antiserum and native MBP formed a precipitin line only with the anti-MBP antiserum. Monoclonal antibody directed against PstI strongly inhibited the activity of both the native PstI enzyme and the MBP-PstI hybrid protein (not shown). Remarkably, the antiMBP antiserum also inhibited the restriction activity of the MBP-PstI hybrid protein present in the maltose-eluted fraction. This inhibition could be released by adding excess MBP, whereas the inhibition by anti&t1 monoclonal antibody could not. (h) Conclusions The technique outlined here is a simple and powerful tool for expressing and purifying foreign peptides in a hybrid protein form. Fusions to MBP are easy
by binding
the purification
to cross-linked
of a
amylose.
gives a high yield and degree of
purity in a single step, carried out under nondenaturing conditions at neutral pH. The procedure can be used in a small-scale
purification,
for example
the expression and purification of a target protein suitable for preparing antisera. It can also be easily adapted to a large-scale purification of a commercially valuable
protein.
In addition,
fusions
con-
structed with pCG806 produce a hybrid protein containing the MBP signal sequence; the results with the PhoA,,-MBP-PhoA fusion indicate that in at least some cases, a signal peptide can direct an MBP fusion protein to the periplasm (see RESULTS AND DISCUSSION, section
d and e, and Table II).
Two drawbacks of the approach as described here are: (i) the stability of the hybrid protein in vivo is variable and hard to predict, as illustrated by the examples presented in this study, and (ii) the hybrid protein includes a carrier peptide (MBP) which may not be acceptable in some applications. ,Possible solutions to these problems are now being investigated.
ACKNOWLEDGEMENTS
This work was supported by a grant from New England Biolabs. We would like to thank L. Moran and B. Slatko for performing the nucleotide sequencing, and Ira Schildkraut, Elisabeth Raleigh and Jon Beckwith for helpful discussion. This paper is dedicated by C.G., P.L. and P.D.R. to the memory of Hiroshi Inouye, who died on July 24, 1986.
REFERENCES Brickman, E. and Beckwith, J.: Analysis of the regulation of Escherichia coli alkaline phosphatase synthesis using deletions and $80 transducing phages. J. Mol. Biol. 96 (1975) 307-3 16. Chang, A.C.Y. and Cohen, S.N.: Construction and characterization of amplifiable multicopy DNA cloning vehicles derived from the P15A cryptic miniplasmid. J. Bacterial. 134 (1978) 1141-l 156.
30
Duplay,
P., Bedouelle,
Hofnung,
H., Fowler, A., Zabin,
the maltose-binding
I., Saurin, W. and
protein
of Escherichia coli K-12. J. Biol.
Chem. 259 (1984) 10606-10613. Ferenci, T. and Klotz, U.: Afftnity chromatographic the periplasmic
maltose-binding
of
FEBS Lett. 94 (1978) 213-217. Hoffman,
C.S. and Wright,
alkaline phosphatase:
an approach
Kellerman,
O.K. and Ferenci,
Laemmli, U.K.: Cleavage bly of the head
of secreted
proteins
to
for studying protein secre-
Sci. USA 82 (1985) 5107-5111.
Escherichia coli. Methods
T.: Maltose Enzymol.
of structural
binding
protein
from
227 (1970)
680-685. B.,
Ljundqvist, and Uhlen, protein Maniatis,
Nolsson,
B.,
L., Holmgren, M.: Production
A fusion proteins. T., Fritsch,
A Laboratory Spring Harbor,
Abrahmsen,
Manual.
L.,
S.P., Josephson, of specific
Moks,
T.,
S., Philipson, antibodies
L.
against
EMBO J. 5 (1986) 2393-2398.
E.F. and Sambrook,
J.: Molecular
Cold Spring Harbor
Cloning.
Laboratory,
Cold
NY, 1982.
Miller, J.H.: Experiments Harbor
inhibitors.
Laboratory,
in Molecular Cold
Spring
Genetics. Harbor,
Cold Spring NY,
1972, pp.
when Escherichia coli cells are converted
Shuman,
H.A.,
Silhavy,
T.J. and Beckwith,
with #I-galactosidase
plasts. J. Biol. Chem. 239 (1964) 3893-3900.
with
Sci. USA 74
of the malK gene J.R.: Labeling
of
by gene fusion. J. Biol. Chem.
255 (1980) 168-174. T.J., Berman,
M.L. and Enquist,
With Gene Fusions. Spring Harbor,
against
H., Makino,
K. and Nakata,
to determine
of the PhoB protein
the protein.
modification
J. Biochem.
nucleotide
and to prepare
97 (1985) 1247-1250.
sequence
J.E.: The organization of the PstI restriction-
C., Vieira, J. and Messing,
M13mp18
Communicated
amino
antiserum
system. J. Biol. Chem. 259 (1984) 8015-8026.
phage cloning vectors of the
Cold
A.: Use of
the N-terminal
Walder, R.Y., Walder, J.A. and Donelson, and complete
Laboratory,
NY, 1984, p. 250.
aphoB’-‘ZacZ msiongene acid sequence
L.W.: Experiments
Cold Spring Harbor
and host strains:
and
pUC19
into the to sphero-
of
J. Biol. Chem. 256 (1981) 560-562.
103-l 19.
Neu, H.C. and Heppel, L.A.: The release of ribonuclease
from
A.R.: DNA sequencing
Proc. Natl. Acad.
H.A. and Silhavy, T.J.: Identification
product.
Yanisch-Perron,
352-355. medium
S. and Coulson,
Sugita, T., Shinagawa,
Lowenadler,
of enzymes
(1977) 5463-5467.
Silhavy,
proteins during the assemT4. Nature
L.A.: The release
J. Biol. Chem. 240 (1965) 3685-3692.
chain terminating
proteins
90 (1982) 459-467.
of bacteriophage
and Heppel,
spheroplasts.
Shuman,
A.: Fusions
tion. Proc. Natl. Acad.
H.C.
Sanger, F., Nicklen, isolation
of Escherichia coli.
protein
Neu,
Escherichia coli by osmotic shock and during the formation
of the malE gene and of its product,
M.: Sequences
by G. Wilcox.
J.: Improved
nucleotide
vectors.
Gene
Ml3
sequences 33 (1985)
Gene, 67 (1988) 21-30 Elsevier GEN 02422
Vectors that facilitate the expression and purification of foreign peptides in EscRericRia coli by fusion to maltose-binding protein (Recombinant
DNA;
plasmids;
cross-linked
amylose
affinity chromatography;
starch)
Chu di Guana, Ping Lib*, Paul D. Riggs” and Hiroshi Inouyeb+ “New England BioLabs, Beverly, MA 01915 (U.S.A.) and bDepartment of Biology, Temple University,Philadelphia, PA 19122 (U.S.A.) Tel. (215) 787-8877 Received
31 August
Accepted
31 October
Revised Received
1987
25 February
1987 1988
by publisher
11 March
1988
SUMMARY
Vectors were constructed that allow foreign peptides to be expressed in Escherichia coli as fusion proteins. The peptides are fused to the C terminus of maltose-binding protein (MBP), which allows them to be purified by the MBP’s affinity to cross-linked amylose (starch). The fusion protein can be directed to the periplasm by including the leader sequence from the phoA gene on the vector.
INTRODUCTION
some-binding site and translation start of the 1ac.Z gene. Such hybrid proteins can be purified by affinity chromatography using antibody to /I-galactosidase. An alternative approach to the expression and puriti-
Gene fusions have been used successfully to facilitate the expression and purification of peptides produced from recombinant DNA molecules (Lowenadler et al., 1986; Shuman et al., 1980; Shuman and Silhavy, 1981; Sugita et al., 1985). Most commonly, target peptides have been fused to j&galactosidase, so that the peptide is expressed in Escherichia coli as a fusion protein using the ribo-
cation of foreign peptides is to fuse them to a specific binding protein. The hybrid protein can then be purified by affinity chromatography using the binding protein’s substrate. In the present study, we chose for this purpose MBP, the product of the malE gene of E. coli K-12.
Correspondence to: Dr. P.D. Riggs, New England
phosphates;
Tozer Road,
Beverly,
MA 01915 (U.S.A.)
* Present
address:
Department
Genetics,
Harvard
University
02115 (U.S.A.)
of Microbiology Medical
Biolabs,
32
Tel. (617) 927-5054. School,
and Molecular Boston,
MA
Tel. (617) 732-1921.
maltose
buffer, see MATERIALS
MBP, maltose-binding
Ap, ampicillin; dNTP,
bp, base pair(s); d, deletion;
any of the four deoxynucleotide
Cm,
pyranoside;
tri-
0378-l 119/X8/$03.50 0 1988 El sevier Science Publishers B.V. (Biomedical
Division)
XGal,
liquid chromatography; kb,
kilobases
AND METHODS,
protein; phoA,,
PolIk, Klenow (large) fragment tetracycline;
chloramphenicol;
high-performance
isopropyl-/l-D-galactoside;
gene that codes for the alkaline
t Deceased. Abbreviations:
HPLC,
IPTG,
1000 bp; section c;
, the portion of the phoA
phosphatase of6.
or
signal sequence;
coli DNA polymerase
I; Tc,
5-chloro-4-bromo-3-indolyl$-o-galacto-
[ 1,designates
plasmid-carrier
state; :: , novel joint.
22
Some advantages express and purify
of using fusions to MBP to foreign peptides are outlined
below.
proteins
First, hybrid
single chromatography
can be isolated
step. MBP binds
1982). Second, the materials for aftlnity chromatography are inexpensive and easy to prepare, making large-scale purification simple and feasible. Third, unlike antibody affinity resins, the whole purification takes place under physiological conditions, and protein denaturation upon elution from the affinity matrix should not occur. Fourth, the fused protein can potentially be directed into different cellular compartments by varying the leader sequence of MBP. Finally, MBP does not contain any cysteine residues that could interfere with disulfide bond formation within the target peptide.
AND METHODS
(a) Bacterial strains and culture conditions Bacterial strains are listed in Table I. Bacteria were grown in rich medium containing (per liter) 10 g tryptone, 5 g yeast extract and 5 g NaCl. Antibiotics were purchased from Sigma, and were added when required as follows: 100 pg Ap/ml, 20 pg Cm/ml, 20 pg Tc/ml. The /I-galactosidase indicator, XGal, was added at 20 pg/ml, and the gratuitous inducer IPTG was added to a final concentration of 1 mM
TABLE
and IPTG
were
(b) Expression of the gene fusions and preparation of crude cellular extracts
results in a high yield and a high degree
of purity, as has been demonstrated for MBP itself (Ferenci and Klotz, 1978; Kellerman and Ferenci,
MATERIALS
XGal
in a
with high
affinity to a cross-linked amylose matrix, and is released from the matrix by 10 mM maltose. This purification
to induce the lac promoter. purchased from Sigma.
Cells containing proteins
plasmids
under lac promoter
that coded control
for fusion
were grown to
5 x lo8 cells/ml at 37°C with shaking in rich medium, IPTG was added to a final concentration of 1 mM, and the culture was grown for an additional 2 h. All subsequent steps were carried out at 4’ C or on ice. The cells were harvested by low-speed centrifugation, resuspended in l/l0 vol. of 10 mM Tris - HCl pH 7.2, and lysed by sonication. Cellular debris was then pelleted by high-speed centrifugation, and the supernatant was saved as crude cellular extract. Crude cellular extracts of cells bearing for pCG828 were prepared as described above, except that 1 y0 Triton X- 100 was included in the extraction buffer in case the signal sequence in this construct leads to the association of the hybrid protein with the membrane. For the phoA ss : : malE: :phoA fusion, the strain MZ20 (A phoA A malB phoR [ pPL-6A’ 1) was grown to 5 x log/ml in rich medium and the cells were harvested. A periplasmic fraction was prepared by cold osmotic shock and by spheroplast formation as described by Neu and Heppel (1964; 1965). (c) Cbromatographic teins
purification of the hybrid pro-
Preparation of cross-linked amylose from amylose (Sigma Cat. No. A-9262) and its use as an afI?nity
I
Escherichia coli strains Strain
Genotype
RR1
hsdS20
CG864
RR1 AmalB zjc::Tn5
Source/Reference ara-14proA2
lacy 1 galK2 rpsL20 xyl-5 mtl-1 supE44
Maniatis
lon::TnlOAl6All
this work
SF1362
A(lac)X74
MZ20
A(Iac)X74 phoA20 phoR hpam
araD 139 A(araABC-leu)7679
JM83
ara A(lac-proAB)
71-18
A(lac-proAB)
rpsL (480lacZAM
thi supE [F’
galU galK rpsL thi AmalB zjc::TnS
AmalB rpsL 15)
proA+B+ IacP lacZAM151
et al. (1982)
S. Froshauer J. Beckwith Yanisch-Perron
et al. (1985)
Yanisch-Perron
et al. (1985)
23
chromatography
matrix was performed
as described
by Kellerman
and Ferenci
(1962). Hybrid
were purified
from
extracts
crude
proteins
by binding
to
cross-linked amylose in a 3 cm x 6 cm column, and were eluted with 10 mM Tris - HCl buffer containing 10 mM maltose
(maltose
plasm.
pCG806
sequence,
contains
and potentially
the normal
maZE signal
allows the export
hybrid protein into the periplasm.
High-level
sion of the hybrid protein can be induced IPTG or lactose to the culture medium.
of the expres-
by adding
buffer). (b) Construction of the malE: : 1ac.Z gene fusions
(d) Immunodiffusion A malE : : IacZ gene fusion containing Reagents
for two-dimensional
were purchased was performed
from BioRad, according
and the procedure
to the manufacturer’s
in-
structions. Antiserum directed against MBP was kindly provided by Dr. P. Bassford. Antibody directed against PstI endonuclease was kindly provided by Dr. M. Philipp. Antibody directed against /I-galactosidase was purchased from Promega Biotec.
RESULTS
AND DISCUSSION
(a) Maltose-binding
almost all of
the ZacZ gene (and thus coding for fl-galactosidase
immunodiffusion
protein fusion vectors
To facilitate the construction and expression of protein fusions to MBP, two fusion vectors, pCG150 and pCG806, have been constructed (Fig. 1). Both plasmids are derivatives of pUC18 (Yanisch-Perron et al., 1985) and contain a portion of the maZE gene with (pCG806) or without (pCG150) its signal sequence, fused to the lacZcl coding sequence. The fusion protein is expressed from the lac promoter and confers a Lac + phenotype on strains containing the ZacZdMlS deletion (cr-complementation; e.g., see Yanisch-Perron et al., 1985). The insertion of cloned sequences into the polylinker of pCG150 or pCG806, which is located between malE and lacZa, abolishes the a-complementation. Any peptidecoding sequence can be cloned into the polylinker regions of these two plasmids. If the cloned insert is not in the proper translational reading frame to produce a hybrid protein, modifications to shift it inframe can be carried out at other sites in the polylinker. Thus, on plates containing XGal and IPTG, colonies of JM83 cells containing the vector alone are blue while recombinants are white. The malE region on pCG150 lacks a signal sequence, and is designed to produce the hybrid protein in the cyto-
activity without
requiring
a-complementation)
was
constructed as follows. Plasmid pCG150 was cleaved with BamHI + PvuII and a 1.2-kb DNA fragment was purified by gel electrophoresis. This fragment contains the lac promoter and the lacZ translation start fused to codons 28-392 of the malE gene (mature MBP is coded for by codons 27-396). This fragment was inserted into plasmid pMLB 1034 (Silhavy et al., 1984) that had been cleaved with EcoRI, tilled in with PolIk and dNTPs, then cleaved with BamHI. pMLB1034 contains the whole ZacZ gene except for the- promoter and the first eight codons. The resulting plasmid, pCG325, codes for an in-frame malE: : ZacZ-coded hybrid protein that produces P-galactosidase activity without a-complementation (Fig. 2). (c) Construction
of the maZE:: PstI endonuclease
gene fusion The maIE: : PstI endonuclease gene fusion was constructed as illustrated in Fig. 3. The PstI restriction system is comprised of two divergently transcribed genes, one coding for the endonuclease PstI and the other for the modification methylase (M *PstI). It has been cloned on a 4-kb DNA fragment inserted into the Hind111 site of pBR322 (pGW4400, provided by G. Wilson; also see Walder was excised with et al., 1984). This fragment HindIII, purified, circularized by ligation with T4 DNA ligase, and then cleaved with HincII to invert the two divergent genes and to separate the PstI endonuclease gene from its promoter. The fragment was then inserted into the HincII site of pUC18, creating plasmid pCG228. A BamHI-Hind111 fragment containing the endonuclease gene without the promoter and the first eight codons was cut from pCG228, purified, and then inserted into pCG150 and pCG806 in place of the small BamHI-Hind111
pCG150 y%oRI~
y&c11
[--KpIfiSmal~
~SUCI-J
rK@Il
. . . ATGACCATGATTACGAATTCGAGCTCGGTACCCGGGCGAGCTCGGTACCCA
TTCGAAGAA --PstI-,
rBamHIl
mdE sequence ------------
[- ,SphI 1
rHindIII
rXbuI-~
r.SalI
1
r
GCGCAGACTGGGGATCCTCTAGAGTCGACC
1
CacZ
TGC AGG CAT GCA AGC TTG -
. . .
pCG806 CAGACTAATTCGAGCTCGGTACCC
. malE sequence-
.
~BamHI1
r X&z17 r--- SalI -J r- PstI --q rSphI~
rHindII1
1
GGG GAT CCT CTA GAG TCG ACC TGC AGG CAT GCA AGC TTG w Fig. 1. Structure restriction
of MBP fusion vectors.
sites present
as described
by Maniatis
(Yanisch-Perron
EcoRI-J$i&I
is the 1.2-kb Hid portion
et al. (1982); restriction
it is the normal
(filled-in) fragment fragment
1977). Double-stranded pCGI50,
enzymes
All plasmids
translation
initiation
corresponds
the signal sequence
of the polylinker
regions.
DNA was used as a template.
37.5-383 (the region of malE just preceding to the 392nd codon
Ap-resistance
of malE. For pCG806,
lac promoter.
Both plasmids
To sequence
manuscript sequencing
including
are based
on pUC18 translation
The malE region of pCG150
out as described
(Sanger
the gene fusion joint region, a primer corresponding
and LeZcr) was used (provided MBP),
by New England
et al., to the
Biolabs).
For
and the ACT codon in bold print
the ACT codon in bold print once again refers to the 392nd codon that the gene is truncated
is the
the malE region ofpCG806
see Duplay et al., 1984). The lower
was carried
aa of mature
the
DNA techniques
this site is the lacZa
in preparation);
of malE (C. Lee, unpubl.;
Nucleotide
the polylinker
before or after the name of a gene indicates
gene; P,,,
Biolabs.
sites; on pCG150
. .
and pCG806,
using recombinant
start followed by the mdE signal sequence.
the GAA codon in bold print is the 28th codon of m&E (the second
A prime notation
of pCG150
were constructed
were from New England
from pPL-5A (P.L., H.I. and J. Beckwith,
from pmalE, and includes
plasmid
of the figure shows the structure
circles represent
m&E translation
of the figure shows the sequence
maZE codons
The upper portion
regions of these plasmids.
et al., 1985). The blackened
start and on pCG806 l.l-kb
in the polylinker
k&5?
at the N or C terminus,
of malE.
respectively.
Ap,
25
methylase,
codonof malE
t
strain
was cotransformed nuclease pCG1001, methylase
CG864
(RR1 AmaZE Zen: : TnlO)
with a plasmid bearing the endo-
gene (either pCG410
or pCG828)
and with
a plasmid bearing the modification gene. pCGlOO1 is a pACYC184-based
plasmid (Chang and Cohen, 1978), and is compatible with the pUC18-based
\ +o plylinker
2-3 “4
0
.P
plylinker
.
pPL-6A’
% 0 %
. -----
PstI endonuclease
(4 MA ss: : malE: :phoA gene
plasmids.
fusion
AphoA ss : : maZE: :phoA fusion was constructed to test whether MBP hybrid proteins could be directed to the periplasmic space. The structure of the plasmid bearing this fusion, pPL-6A’, is shown in Fig. 2. The details of this construction will be presented elsewhere (P.L., H.I. and J. Beckwith, manuscript in preparation). As described in section e, below, and in Table II, thephoA,, signal peptide could direct the hybrid protein to the periplasmic space. Although thephoA signal sequence was used in this example, the generalized vector pCG806 was constructed with the maZE signal sequence. It is anticipated that the MBP signal peptide would direct hybrid proteins to the periplasm in the same manner.
K”
Fig. 2. Structure
of pCG325
the figure shows constructed pCG150
by inserting between
pMLB1034
28-392.
This plasmid
the 1.2-kb PvuII-BamHI
the EcoRI
shows the structure
plasmid
The upper portion
of pCG325.
fragment
(filled in) and BamHI
(Silhavy et al., 1984). The lower portion
of this plasmid Beckwith,
and pPL-6A’.
the structure
of pPL-6A’.
is identical
elsewhere
in preparation). to that
of pCG325,
The region 5’ to ma/E contains
the first 21 codons
ofphoA (phoA,,),
phatase
signal
contains
most of the remainder
(corresponding This plasmid
peptide.
1985). Solid and dashed the indicated
Solid circles
represent
notations
are as in Fig. 1.
and
3’ to the malE sequence alkaline
from pHI28
genes; arrowheads
scription.
in this codons
the alkaline phos-
lines indicate
indicate
at codon 33 phosphatase).
(H.I., unpublished),
and pCH2 (Hoffman
concentric
and J.
the phoA promoter
of phoA, starting
to the 12th aa of mature was constructed
(P.L., HI. comprising
encoding
The region
pm&E (C. Lee., unpublished)
of the figure
The malE sequence
and Wright, the extent of
the direction
translation
start
(e) Purification
of the hybrid proteins by affinity
chromatography
from
sites of
The details of the construction
will be presented
manuscript
of
was
of tran-
sites. Other
fragment. The resulting plasmids, pCG410 and pCG828, respectively, contain in-frame m&E : : PstI endonuclease gene fusions. Since the PstI restriction gene is lethal to E. coli K-12 in the absence its cognate
The MBP-/3-galactosidase hybrid protein was purified from SF1362[pCG325] by cross-linked amylose affinity chromatography as described in MATERIALS AND METHODS, section d. Crude extract from 1 liter of cells contained approx. 350 mg total protein and 760 000 units of /?-galactosidase activity (Miller, 1972). Using a theoretical specific activity for the hybrid protein of 225 000 units/mg (the specific activity of native /?-galactosidase corrected for the M, of the hybrid protein), it is estimated that the hybrid protein represents about 1% of the total protein. More than 70% of the fi-galactosidase enzymatic activity present in the crude extracts bound to the cross-linked column and was eluted with maltose buffer. This fraction contained 540 000 units of /I-galactosidase, and SDS-polyacrylamide gel analysis (see below) revealed that 90% of the protein was the size predicted for the hybrid protein. The /I-galactosidase activity that did not bind to the column could not be accounted for by a limitation of the capacity of the column; when this fraction was
26
r( Hind111
HindIII
Hind111 purified fragment
1
t Him11 T4Ligase
I
HincII
HincII
Ap
HincII
.-
Fig. 3. Construction in RESULTS
of MBP::PstI
(MBP-endonuclease)
AND DISCUSSION,
The solid circles represent
translation
coding region. The Hind111 fragment
fusion plasmids.
Details of the construction
section c. M and R refer to the PstI modification start sites, with the dashed ofpGW4400
arrows
was purified, circularized
indicating
methylase the direction
of pCG410
and endonuclease of transcription
and pCG828
are given
genes, respectively. and the extent of the
by ligation with T4 DNA ligase, and then cleaved with HincII
21
TABLE II Localization of alkaline phosphatase activity produced by the phoA,:
:malE: :phoA fusion
Alkaline phosphatase activitya
Cold osmotic shockb Released from spheroplasts”
In periplasm
In cytoplasm + membranes
% periplasmic
0.22 0.13
0.028 0.021
89 86
a Alkaline phosphatase activity was assayed as described by Brickman and Beckwith (1975). 2.5-ml cultures of MZ20[pPL-6A’] were harvested and washed as described, and the alkaline phosphatase assays were performed on 10 pl of 200 ~1 periplasmic and cellular fractions. Activity is expressed as the change in A,,,/min. b Periplasmic and shocked-cell fractions were prepared as described by Neu and Heppel (1965). c Periplasmic and spheroplast fractions were prepared as described by Neu and Heppel(1964).
all of the b-galactosidase activity still passed through the column. The fraction of the fi-galactosidase activity that originally was eluted with maltose buffer was dialyzed against 10 mM Tris * HCl, pH 7.2, and applied to a fresh column; all of the /I-galactosidase activity once again bound to the column and could be eluted with maltose buffer. These results suggest that the /I-galactosidase activity present in the flow-through represents a fraction of the hybrid protein that is cleaved to give an active /I-galactosidase fragment lacking the maltose-binding activity. The MBP-PstI fusion protein was purified as follows. The crude extracts from strains containing pCG410 and pCG828 were applied to a cross-linked amylose column and chromatography was performed as described in MATERIALS AND METHODS,
ases (not shown). From 1 liter of culture, approx. 100000 units of PstI activity could reproducibly be recovered from the affinity purification. Since native PstI endonuclease exists as a dimer, and the MBPPstI hybrid protein appears to be cleaved at the joint
section d. In both cases, 90-95 y0 of the total restriction enzyme activity in the crude extracts passed through the column. The remaining 5-10% of the PstI activity could be eluted from the column by maltose buffer. As judged by restriction assays using 1 DNA, the protein that was purified from the amylose column had the same site specificity as native PstI, and was free from contaminating nucle-
d. As shown in Table II, SS-90% of the alkaline phosphatase activity produced was present in the periplasm; of this fraction, 90 y0 of the activity was retained on the amylose column and eluted with maltose buffer. This demonstrates that the presence of a signal peptide can direct this hybrid protein to the periplasmic space.
applied
to a fresh amylose column,
region
in
ViVO
(See
RESULTS
AND
DISCUSSION,
section f), it is not known whether the hybrid protein accounts for all of this endonuclease activity; for example, some of the activity could arise from mixed dimers of the hybrid protein and the PstI portion of the cleaved hybrid. The hybrid protein produced by the phoA,,: : maIE: :phoA fusion was purified as follows. The osmotic shock fluid from cells bearing pPL-6A’ was dialyzed against 10 mM Tris +HCl, pH 7.2, and applied to a cross-linked amylose column, and chromatography was performed as described in MATERIALS AND METHODS, section
to invert the two divergent genes and to separate the PstI endonuclease gene from its promoter. The fragment was then inserted into the HincII site ofpUC18, creating plasmid pCG228. A BarnHI-Hind111 fragment containing the endonuclease gene without the promoter and the first eight codons was cut from pCG228, purified, and then inserted into pCGl50 and pCG806 in place of the small BamHI-Hind111 fragment. The resulting plasmids, pCG410 and pCG828, respectively, contain in-frame malE_PstI endonuclease gene fusions. pCG410 lacks the malE signal sequence (‘malE’) while pCG828 includes the normal malE translation start and signal sequence (malE’).
28
gel anal-
ysis of the hybrid proteins
scribed in MATERIALS AND METHODS, section f, and in Fig. 4. For the MBP-P-galactosidase hybrid protein, the major band on the gel had an apparent M,
The fractions that were eluted with maltose buffer were pooled, concentrated and analyzed by SDS-polyacrylamide gel electrophoresis as de-
of 156 x 103, as predicted by the sequence of the gene fusion. Minor bands, which are presumed to be degradation products of the hybrid protein, were also
(f) Sodium dodecyl sulfate-polyacrylamide
205K 205K 116K 97.4K
116K 97.4K
45K
45K
29K 29K
B
A Fig. 4. SDS-polyacrylamide acrylamide Centricon
g&l electrophoresis microconcentrators
gel analysis of MBP$-galactosidase as described (Amicon)
(Laemmli,
according
to the gel. Gels were run at 30 mA (constant MW-SDS-200) B (97.4 kDa), phoresis
carried
were bovine carbonic b-galactosidase
(116 kDa),
out on protein fractions
eluted from the cross-linked 1, purified MBP.
protein
instructions.
and stained with Coomassie
and myosin
(205 kDa).
from cells bearing
polyacrylamide
eluted from the cross-linked
Proteins
were concentrated A 5-lo-pg
brilliant
were analysed lo-20
by SDS-poly-
x by ultrafiltration
sample of each protein
blue. Proteins
in
was applied
used as M, markers
(Sigma
(29 kDa), egg albumin (45 kDa), bovine serum albumin (66 kDa), rabbit phosphorylase pCG325.
(K = kDa). Lanes:
gel electrophoresis amylose
(Panel A) 0.1 y0 SDS-7%
1, M, markers;
amylose column with maltose buffer; 4, flow-through
extract. (Panel B)0.1 y0 SDS-lo%
hybrid proteins.
to be analyzed
to the manufacturer’s
current)
anhydrase
and MBP-PstI
1970). Samples
from the cross-linked
carried out on protein fractions
column with maltose
polyacrylamide
gel electro-
2, purified MBP; 3, purified hybrid protein
buffer; 2, purified
amylose column;
5, crude cellular
Tom cells bearing pCG410.
native PstI endonuclease;
Lanes:
3, purified
29
present.
HPLC
fraction
indicated
retained
fl-galactosidase
SDS-gel hybrid
separation that
analysis
protein
signal sequence) to that predicted
156-kDa
species
of maltose-eluted by PCG410
showed three bands.
a
The top-most
A4, of 78 x 103, corresponding The
two lower bands corresponded to 40 kDa and 45 kDa (mature MBP runs at about 40 kDa), and comprised 90% of the total protein in the maltoseeluted fraction. This indicates
that the hybrid protein
is sensitive to one or more host proteases, which cleave with some specificity at the joint region of the fusion. The identical analysis with the maltose-eluted fraction prepared from cells bearing pCG828 (with a malE signal sequence) showed three bands in the same relative positions, with the position of the two lower bands indicating a slightly higher M, (not shown). Only 20 y0 of the PstI enzymatic activity was released in the shock fluid of cells bearing pCG828, indicating that the hybrid protein was not efficiently secreted into the periplasmic space. (g) Immunological
in turn facilitate
This purification
MBP-PstI (lacking
from the gene fusion sequence.
using the vectors pCG1.50 and pCG806;
these fusions hybrid protein
activity (not shown).
produced
band had a apparent
to construct
of the maltose-eluted
only the
analysis of the hybrid proteins
Two-dimensional immunodiffusion analysis was performed on the maltose-eluted fraction from cells bearing pCG325. This fraction formed a single precipitin line both with antiserum directed against MBP and with antiserum directed against /?-galactosidase (not shown). Native P-galactosidase formed a precipitin line only with the anti+galactosidase antiserum and native MBP formed a precipitin line only with the anti-MBP antiserum. Monoclonal antibody directed against PstI strongly inhibited the activity of both the native PstI enzyme and the MBP-PstI hybrid protein (not shown). Remarkably, the antiMBP antiserum also inhibited the restriction activity of the MBP-PstI hybrid protein present in the maltose-eluted fraction. This inhibition could be released by adding excess MBP, whereas the inhibition by anti&t1 monoclonal antibody could not. (h) Conclusions The technique outlined here is a simple and powerful tool for expressing and purifying foreign peptides in a hybrid protein form. Fusions to MBP are easy
by binding
the purification
to cross-linked
of a
amylose.
gives a high yield and degree of
purity in a single step, carried out under nondenaturing conditions at neutral pH. The procedure can be used in a small-scale
purification,
for example
the expression and purification of a target protein suitable for preparing antisera. It can also be easily adapted to a large-scale purification of a commercially valuable
protein.
In addition,
fusions
con-
structed with pCG806 produce a hybrid protein containing the MBP signal sequence; the results with the PhoA,,-MBP-PhoA fusion indicate that in at least some cases, a signal peptide can direct an MBP fusion protein to the periplasm (see RESULTS AND DISCUSSION, section
d and e, and Table II).
Two drawbacks of the approach as described here are: (i) the stability of the hybrid protein in vivo is variable and hard to predict, as illustrated by the examples presented in this study, and (ii) the hybrid protein includes a carrier peptide (MBP) which may not be acceptable in some applications. ,Possible solutions to these problems are now being investigated.
ACKNOWLEDGEMENTS
This work was supported by a grant from New England Biolabs. We would like to thank L. Moran and B. Slatko for performing the nucleotide sequencing, and Ira Schildkraut, Elisabeth Raleigh and Jon Beckwith for helpful discussion. This paper is dedicated by C.G., P.L. and P.D.R. to the memory of Hiroshi Inouye, who died on July 24, 1986.
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