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Rabies glycoprotein fused with B subunit of cholera toxin expressed
in tobacco plants folds into biologically active pentameric protein
Sribash Roy, Antariksh Tyagi, Siddharth Tiwari, Ankit Singh, Samir V. Sawant,Pradhyumna K. Singh, Rakesh Tuli *
National Botanical Research Institute, Council for Scientific and Industrial Research, Rana Pratap Marg, UP, Lucknow 226001, India
a r t i c l e i n f o
Article history:
Received 26 August 2009
and in revised form 2 October 2009
Available online 8 October 2009
Keywords:
Cholera toxin
Edible vaccine
Mucosal carrier
Rabies glycoprotein
a b s t r a c t
The pentameric B subunit of cholera toxin (CtxB) is an efficient mucosal adjuvant for vaccines. We report
the expression of a chimeric protein comprising the synthetic cholera toxin B subunit fused at its C-ter-
minal with rabies surface glycoprotein (G protein) in tobacco plants. The 80.3 kDa fusion polypeptide
expressed at 0.4% of the total soluble protein in leaves of the selected transgenic lines. The fusion protein
formed a 403 kDa pentameric protein which was functionally active in binding to GM1 receptor. The
plant-made protein had a higher affinity for GM1 receptor than the native bacterial CtxB. The pentameric
fusion protein was recognized by the anti-cholera toxin as well as anti-rabies antibodies. Its immuno-
protective ability against rabies remains to be examined.
2009 Elsevier Inc. All rights reserved.
Introduction
Transgenic plants expressing foreign proteins of industrial and
pharmaceutical value are suggested to be economically viable alter-
natives to fermentation-based production systems. However, there
is a need to evaluate plants for the expression of a variety of func-
tionally active eukaryotic proteins that undergo complex folding
and post translational modifications. One such group of pharma-
ceutically important proteins is the subunit vaccine antigens. When
expressed in edible plant parts, these have been reported to be
effective as oral and mucosal antigens [1–3]. The expression level
of these antigens expressed in plants, as nuclear genes is often
low, ranging from 0.001% to 0.3% of total soluble protein (TSP)1
[4]. The low level expression limits the extent of immune response
and the development of an effective plant-based oral vaccine. Strate-gies like co-administration with an adjuvant [5] and fusion of anti-
gens with an effective carrier molecule, either chemically or
genetically, can increase the immunogenicity of antigens [6,7].
In several studies, cholera toxin B subunit (CtxB) has been used
as a carrier for antigens [8–11]. CtxB is a homopentameric
(Mr 58,000) protein comprising the polypeptides (Mr 11,600)
arranged in a ring-like configuration. The native pentameric struc-
ture of CtxB and its binding to GM1 receptors are crucial for its
function as mucosal carrier and the resultant immunological re-
sponse. Conjugation of antigens with CtxB can reduce the dose re-
quired for T-cell activation by more than 10,000-fold as compared
to the free antigen [12]. Rabies virus genome encodes five major
proteins- nucleoprotein (N), phosphoprotein (P), matrix protein
(M), glycoprotein (G) and RNA-dependent RNA polymerase (L)
[13,14]. The surface glycoprotein (G) plays an important role in vir-
al pathogenesis and functions as a protective antigen [15]. One of
the strategies to control rabies in wild animals is to develop oral
vaccine that can be given as bait in the wild. This requires enhanc-
ing immunogenicity and expression of the G protein at high level
in plant tissue. With an aim to enhance immune response and
achieve high level expression of the G protein, plant codon opti-
mized synthetic ctxB and G protein (rgp) genes were fused and
transformed into tobacco plants. The plants expressed the chimeric
CtxB-G protein which was purified from leaves of the transgenictobacco plants and analyzed for functional integrity.
Materials and methods
Construction of ctxB and rgp fusion and cloning into plant expression
cassette
We have earlier reported designing and cloning of plant codon
optimized synthetic ctxB gene of Vibrio cholerae O139 strain 1854
[16] and rgp gene of rabies virus glycoprotein [17] and their
expression in tobacco leaves. In this study, a glycine–proline hinge
was used at the point of fusion of translational frames of the CtxB
and G proteins. The signal sequence PR-S, of the pathogenesis
induced tobacco protein PR-1a was used to facilitate transport of
1046-5928/$ - see front matter 2009 Elsevier Inc. All rights reserved.
doi:10.1016/j.pep.2009.10.002
* Corresponding author. Fax: +91 0522 2205836/2205839.
E-mail address: [email protected] (R. Tuli).1
Abbreviations used: TSP, total soluble protein; PVDF, polyvinylidene fluoride; HRP,
horseradish peroxidase; ALP, alkaline-phosphatase.
Protein Expression and Purification 70 (2010) 184–190
Contents lists available at ScienceDirect
Protein Expression and Purification
j o u r n a l h o m e p a g e : w w w . e l s e v i e r . c o m / l o c a t e / y p r e p
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the fusion protein to endoplasmic reticulum [18]. The pr-s-ctxB
was PCR amplified using a forward primer (50ACTCTAGAA
TGAACTTCCTCAAGTCCTTC30) with XbaI and a reverse primer
(50AGGCC CGGGACCGTTAGCCATGGAGATAG30) with SmaI site
using pSM31 [16] as the template DNA. The reverse primer was de-
signed to include codons for the glycine-proline hinge at the 30
endof ctxB. The synthetic G protein gene was PCR amplified using pSA5
[17] as template DNA and a forward primer (50GGTCCCG
GGCCTAAGTTCCC TATCTACAC30) with SmaI site including codons
for the glycine–proline of the hinge region. The reverse primer
(50ACGAGCTCTCATCACAACTCATCCTTCTC30) carried a SacI site.
Amplified PCR fragments were digested with the respective
enzymes and triply ligated in the vector, pBI101 containing the
enhanced CaMV35S promoter to obtain pSR1241 with two gly-
cine-proline repeats as hinge at the 3‘end of ctxB (Fig. 1).
Plant transformation and analysis
Agrobacterium tumefaciens LBA4404 was transformed with
pSR1241 by electroporation and used for tobacco (Nicotiana tabac-
cum cv. Petit Havana) transformation using the leaf disc method
[19]. The kanamycin resistant T0 plantlets were transferred to soil
in the green house and grown to maturity. Transgenic plants were
screened for the presence of the ctxB-rgp gene by PCR, using for-
ward 50ATCGATGTCGACTAACAACTTCCTCAAGTCTT30 and reverse
50AGATCGTCGACTCATCACAACTCATCCCTCTCGGAC30 primers. Sta-
ble integration and copy number of the transgene were established
by Southern hybridization as described in [17]. Hybridization was
performed at 65 C for 16 h, using [aP32] dCTP labeled probe, com-
prising 570 bp XhoI– AgeI fragment at 30 end of the gene. The mem-
brane was exposed to Fuji screen for 24 h and scanned on phosphor
imager (Molecular Imager FX, Bio-Rad, and Hercules, USA).
Quantitative analysis of ctxB-rgp transcript by real-time PCR
Total RNA was prepared from the leaves of T 0 transgenic plants
in TRIZOL LS reagent (Invitrogen Life Technologies, USA) according
to manufacturer’s instructions. One lg RNA was used for the first-
strand cDNA synthesis using c-DNA synthesis kit (PE BiosystemsInc., USA). PCR on cDNA was performed using the forward
50CCAAGCTTTCTAGATAAACAATGAACTTCCTCAAGTCATT 30 and re-
verse 50GGATATAATCTTTCCGGACTGTGGAGT AACGGAGTCCACCC-
TACCGGT 30 primers. Expression of the ctxB-rgp transcript in
different transgenic lines was quantified by real-time PCR using
TaqMan probe (50FAM TCCCAGA GATGCAGTCC-NFQ30) on ABI
Prism 7700 sequence detection system (TaqMan, PE Biosystems
Inc., USA). The ctxB-rgp transcript was normalized with respect to
ubiquitin transcript as internal control in the same sample. The rel-
ative fold expression of the ctxB-rgp gene was estimated in terms of
2DDC T [20]. The DCT was determined by subtracting ubiquitin C Tvalue from ctxB-rgp C T value in a given sample. The DDC T value
was determined by subtracting the lowest expressing plant (cali-
brator)D
C T from the D
C T of each plant.
Polyacrylamide gel electrophoresis and immunoblot analysis
Transgenic tobacco leaves were analyzed for the presence of
CtxB-G protein by immunoblot analysis. Leaf material (1 g) was
ground in liquid nitrogen and homogenized in 2 ml extraction buf-
fer (50 mM sodium phosphate pH 7.5, 150 mM NaCl, 150 mM sor-
bitol, 2 mM dithiothreitol, 1 mM phenylmethylsulfonyl fluoride,
2 mM plant protease inhibitors cocktail from Sigma, USA and
0.08% Triton-X 100. Total soluble protein content was determined
by Bradford assay [21]. Thirty lg TSP of transgenic and non-trans-
genic plants was electrophoresed on 10% denaturing SDS gel and
transferred to polyvinylidene fluoride (PVDF) membrane. The
Hinge of GPGP SEKDEL
XbaI BglII SacI ApaI
2040bp
Hind III
SEKDEL
XbaI BglII SacIRB LB
TnosnptII PECaMV35S Pnos pr-s ctxB Tnos
Hind IIIRB
TnosnptII PECaMV35S PnospSA5
pSM31
Tnosrgp pr-s
SacI XhoI Apa1 Hind III
SEKDEL
Hind IIIRB
TnosnptII PECaMV35S PnospSR1241
LB
Tnosrgp pr-s
XhoI
ctxB
LB
AgeI
Fig. 1. Gene constructs showing cloning of the fusion gene ctxB-rgp in pBI101. The pr-s-ctxB and rgp fragments were PCR amplified from pSM31 and pSA5, respectively.
Amplified PCR fragments were digested with respective enzymes and triple ligated in pBI101 to obtain pSR1241 with two glycine-proline repeats as hinge at the 30 end of
ctxB.
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membranes were incubated with anti-cholera antibody (Sigma,
USA) and equine anti-rabies serum (Haffkine Bio-pharmaceutical
Corporation Ltd, India) for 2 h. After three washes with TBST, the
membranes were further incubated with horseradish peroxidase
(HRP) conjugated anti-rabbit IgG and alkaline-phosphatase (ALP)
conjugated anti-horse IgG (Sigma, USA) for 2 h at room tempera-ture for CtxB and G proteins, respectively, and developed by HRP
(Promega life science, USA) or ALP (Bio-Rad, USA) color develop-
ment kit. For detection of the pentameric form of CtxB-G protein,
6% SDS–PAGE gel was used and the un-boiled samples were loaded
without adding DTT in sample-loading buffer [22]. The gel was run
at constant 30 V, blotted into PVDF membrane for at least 5 h and
developed as described above.
Quantification of CtxB-G protein in plant and assay of immunological
activity
GM1-ELISA was performed to quantify the expression level of
pentameric form of the CtxB-G protein in tobacco leaves as re-
ported in Mishra et al. [16] with minor modifications. The 96-wellmicrotiter plates (Greiner, Germany) were coated with 3.0 lg/ml
GM1 made in sodium bicarbonate coating buffer pH 9.6 (15 mM
Na2CO3, 35 mM NaHCO3) and incubated over night at 4 C. As con-
trol, BSA (3.0 lg/ml) in bicarbonate buffer was coated in some
wells. The wells were blocked with 300 ll of 1% BSA in phosphate
buffered saline Tween 20 (PBST; 0.01 M Na2HPO4, 0.003 M
KH2PO4, 0.1 M NaCl, pH 7.4, 0.05% Tween 20, v/v) for 1 h. Total sol-
uble leaf protein and bacterial CtxB (Sigma, USA) were diluted seri-
ally, added into the wells in triplicate and incubated for 1 h,
followed by 2 h incubation with rabbit anti-cholera toxin antibody
at 1:4000 dilution in PBST containing 0.25% BSA followed by 2 h
incubation with mouse anti-rabbit IgG alkaline-phosphatase con-
jugate at 1:30,000 dilution in PBST containing 0.25% BSA. The
plates were developed with p-nitrophenyl phosphate substrate.
The reaction was terminated by the addition of 3 M NaOH. The
plates were read at 405 nm and the CtxB expression level was
quantified on a linear standard curve. All estimates were made
on the basis of three independent experiments.
Assay of the immunological activity of CtxB-G protein against
rabies was performed as described above except that the antibody
against a custom synthesized G peptide was used as the primary
antibody in 1:4000 dilution. Indirect ELISA was performed to check
immunological activity against rabies antibody. Microtiter plates
were coated with plant-CtxB–G protein crude extract and incu-
bated at 4 C overnight. The plates were blocked with 1% BSA in
PBST for 1 h at 37 C. After washing three times with PBST, the pep-
tide antibody against G protein and equine anti-rabies antibody
were added at 1:4000 dilution and incubated for 2 h at 37 C.
The plates were further incubated with ALP conjugated anti-rabbitand anti-horse IgG in 1:8000 dilution for 2 h at 37 C and devel-
oped as described above.
In order to assess relative binding affinity of CtxB-G protein for
GM1 receptors, microtiter plates were coated with various concen-
trations of GM1 and incubated at 4 C overnight. The plant derived
CtxB, CtxB-G leaf extract, bacterial CtxB (Sigma, USA) or BSA (neg-
ative control) were added to the wells at 3lg/ml and incubated
overnight at 4 or 37 C. The plates were developed following Mish-
ra et al. [16].
Purification of CtxB-G protein and pentamerization
Purification of CtxB-G protein was carried out as described in
Mishra et al. [16]. Briefly, Rabbit anti-CtxB IgG was coupled toCNBr-activated Sepharose 4B following manufacturer’s instruc-
tions (Amersham Biosciences, Sweden). The rabibit anti-CtxB IgG
(20 mg) was dissolved in coupling buffer (0.1 M NaHCO3 pH 8.3
containing 0.5 M NaCl). Two grams of CNBr- activated Sepharose
4B was suspended in 1 mM HCl and washed for 15 min on a sin-
tered glass filter. Approximately 200 ml of 1 mM HCl was added
in several aliquots per g of dried powder. The coupling solution
containing the rabbit anti-CtxB IgG was mixed with the medium
in a stoppered vessel and rotated over night at 4 C. Excess ligandwas washed away with five volumes (w/v) of the coupling buffer.
The slurry was transferred to 0.1 M Tris–Cl buffer, pH 8.0, allowed
to stand for 2 h and then, washed with at least three cycles of five
volumes of each buffers with alternating pH (0.1 M acetate buffer,
pH 4.0 containing 0.5 M NaCl followed by a wash with 0.1 M Tris–
Cl, pH 8.0 containing 0.5 M NaCl). The Sepharose coupled with the
anti-CtxB IgG was loaded onto a column and pre-equilibrated with
buffer (50 mM sodium phosphate pH 7.5, 150 mM NaCl, 2 mM
dithiothreitol, 1 mM phenylmethylsulfonyl fluoride, 0.08% Triton-
X 100). Tobacco leaf (10 g) was grounded in liquid nitrogen and
homogenized in 20 ml extraction buffer as described above. The
extract was centrifuged for 10 min at 5000 g . The supernatant
was again centrifuged for 15 min at 13,000 g. The clarified tobacco
leaf extract (22 ml) was loaded onto the column. The wash throughwas re-loaded for maximum binding of the CtxB-G protein. The
column was washed with six volumes of wash buffer (50 mM so-
dium phosphate pH 7.5, 150 mM NaCl, and 2 mM dithiothreitol).
The CtxB-G protein was eluted with glycine–Cl buffer pH 2.8 and
neutralized to pH 7.4 by collection of the drops in 1/10th volume
of 1 M tris–Cl pH 9.5. The eluted CtxB-G protein fraction (20 ml)
was dialyzed against buffer (0.1 M tris–Cl pH 7.5, 0.4 M NaCl and
2 mM EDTA). The dialysis bag containing the protein was kept on
sucrose bed for concentrating the protein, with intermittent
changes of sucrose. The concentrated CtxB-G protein (1lg/ll)
was incubated overnight at 37 C to allow pentamerization.
Results
Insertion events and the expression of CtxB-G in transgenic tobacco
Six independently transformed kanamycin resistant tobacco
plants were verified for the presence of ctxB-rgp gene by PCR
amplification of the genomic DNA (Fig. 2A). The expected DNA
fragment of 1.9 kb was observed in all the six plants (lanes 1–
6) whereas genomic DNA of the non-transgenic plant gave no
amplification (lane NT). The quantitative analysis of ctxB-rgp tran-
script carried out by real-time PCR showed the highest transcript
level (1600-fold) in plant #1 as compare to that in the least
expressing transgenic plant #6 (Fig. 3). The transgenic plant #1
showing the highest expression of ctxB-rgp was further analyzed
by Southern hybridization for determining the copy number of
the transgene insertion. The transgenic plant #1 contained singlecopy of the transgene inserted into its genome (Fig. 2B).
Expression of functional CtxB-G protein in plant leaves
The level of pentameric form of CtxB-G protein expressed in
transgenic tobacco lines was determined by monosialoganglio-
side-dependent enzyme linked immunosorbent assay (GM1-ELISA)
of total leaf protein. The highest expression level was observed in
plant #1 where the CtxB-G expressed at 0.4% of TSP in leaves. This
was followed by expression at 0.21% in the plant #3 (Fig. 4A).
Immunological activity of the fusion protein CtxB-G was checked
by performing both GM1-ELISA and indirect ELISA (Fig. 4B). Pep-
tide antibodies against the G protein as well as equine anti-rabies
antibodies were used as primary antibodies in both the assays. Thebinding of the CtxB-G protein to GM1 receptors in GM1-ELISA
established that the chimeric protein expressed in tobacco leaves
was in pentameric form. That the chimeric protein was immuno-
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logically active against both CtxB and the rabies antibodies was
established by indirect ELISA using both the antibodies.
The transgenic plants (#1, 2 and 3) showing high expression of
the CtxB-G protein were selected for analysis on immunoblot. As
expected, a 403 kDa (66 kDa glycosylated G + 14.6 kDa glycos-ylated CtxB polypeptide pentamer) protein was observed in the
non-reduced and un-boiled sample when detected by both CtxB
(Fig. 5A) and G protein antibodies (Fig. 5B). No band was detected
in the non-transgenic plants. The highest expression of CtxB-G pro-
tein was noticed in plant #1 (Fig. 6A, lane1 and Fig. 6B, lane 1).This
is consistent with the results of real-time PCR and ELISA. Under the
denaturing conditions, a band of 80.6 kDa, representing the
monomeric fusion polypeptide was detected using equine anti-ra-
bies antibodies (Fig. 5C).
Binding affinity of the tobacco-expressed proteins to GM1 receptors
Functionality of CtxB and its fusion derivatives was correlated
with the ability to bind to GM1 ganglioside.The binding affinityof the plant derived CtxB, CtxB-G and bacterial CtxB to GM1 was
determined by GM1-ELISA carried out at 4 or 37 C (Fig. 6). Within
the linear range of binding at variable molar concentrations of
GM1, the order of binding affinity was: plant-CtxB > CtxB-G > bac-
terial CtxB at both the temperatures. Thus, the plant-expressedCtxB showed higher affinity towards GM1 as compared to the bac-
terial CtxB and CtxB-G. The CtxB-G showed higher affinity towards
GM1 as compared to bacterial CtxB but lower affinity than plant-
expressed CtxB at both the temperatures.
Purification of CtxB-G protein and pentamerization
The CtxB-G protein expressed in transgenic tobacco lines was
purified using immunoaffinity column. The summary of recovery
at different steps of purification of CtxB-G is shown in Table 1.
Quantification of the eluted protein by ELISA showed that about
31% of CtxB-G was recovered using single step affinity purification.
The recovery suggested 93% purity (Table 1), which is also evident
on the denaturing gel electrophoresis (Fig. 7A). The pentamericnature of CtxB-G was evident from its receptor binding in GM1-
ELISA, as explained earlier. It was further substantiated by non-
denaturing SDS–PAGE analysis. The protein was suspended in buf-
fer without DTT and loaded onto a 6% denaturing SDS gel. In the
non-reduced and un-boiled samples, one major protein band was
formed at position corresponding to molecular mass of 403 kDa
(Fig. 7B). This agreed with the predicted size of the pentameric
form of CtxB-G protein. No major bands corresponding to lower
multimeric forms were noticed even when the gel was run for
2 h instead of 5 h (data not shown).
Discussion
Rabies virus surface glycoprotein (G protein) is immuno-protec-tive against rabies [15]. In an earlier study from our group, a syn-
thetic gene coding the G protein was expressed in tobacco plants.
The plant derived G protein, given by intra-peritoneal route, in-
duced protective immunity in mice against intracerebral lethal
challenge with live rabies virus [17]. The non-glycosylated G pro-
tein prepared from bacterial cells does not give protective immu-
nity [23,24]. The G protein expressed in yeast is glycosylated but
gives protection only against intra-muscular and not intracerebral
virus challenge [25]. This may be due to difference in glycosylation
of G protein expressed in Saccharomyces cerevisiae from those
required for effective protection against the viral challenge. In an-
other study, a chimeric peptide containing antigenic determinants
from the rabies virus G protein (amino acids 253–275) and the
nucleoprotein (amino acids 404–418) was expressed in tobaccoplants as translational fusions with alfalfa mosaic virus (AlMV)
coat protein. The recombinant A1MV virus particles purified from
the transiently infected plants gave protective immunity in mice
M 1 2 3 4 5 6 NT
bp
2027
1584
1375
A B
Fig. 2. Detection of synthetic ctxB-rgp gene in T0 transgenic tobacco plants by PCR (A) and Southern hybridization analysis of the transgenic (lane 1) and non-transgenic (lane
2) plants (B). Genomic DNA was isolated from transgenic and wild-type plant leaf. PCR was performed using gene specific primers. The PCR products were separated on 1.0%
agarose gel. M, EcoR1/HindIII digested k DNA markers, PCR products with DNA template from six independent T0 transgenic (lanes 1–6) and non-transgenic (NT) plants. For
Southern hybridization, genomic DNA from T0 transgenic plant #1 was digested with XhoI, electrophoresed in 0.8% agarose gel and blotted onto Hybond N+ membrane. Since
the fragment between T-borders has one XhoI site, the number of fragments hybridizing with 570 bp rgp probe from 30 region of the gene represents copy number of the
insert. A single band (lane 1) indicates the presence of single copy in the genome.
Fig. 3. Quantitative analysis of ctxB-G transcript in transgenic lines by real-time
PCR. The relative levels of the transcript (Y -axis) with respect to the least expressing
plant (#6) in ( X -axis) are shown. Error bar represents SD values based on the three
replicates.
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after intra-muscular challenge with the rabies virus [26]. The fu-
sion of CtxB with G protein studied here is expected to provide
CtxB as a receptor specific carrier. This may reduce the dose re-
quired for oral mucosal uptake of CtxB-G. The approach may en-
C t x B - G ( % T S P )
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
0.45
#1 # 3
T0 plants
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
C t x B - G ( A b s o r b a n c e )
Plant # 1NT plants
Ab1 Ab2 Ab1 Ab2
Indirect ELISA GM1-ELISA
A B
Fig. 4. CtxB-G protein expression in leaf in T0 transgenic tobacco plants #1 and #3 by GM1-ELISA (A) and assay of immunological activity of CtxB-G protein against rabies
antibodies by indirect and GM1-ELISA (B). The expression level of CtxB-G protein is given as %TSP. In indirect ELISA and GM1-ELISA for plant # 1, the plates were developed
using peptide anti-G (Ab1) and equine anti-rabies (Ab2) antibody. NT, non-transgenic plants.
A B
1 2 3 NT
403
250
kDa M 1 2 3 NT M 1 2 3 NT
7295
55
kDa205130
36
28
C
80.6 kDa
Fig. 5. Western blot analysis of transgenic plants under non-denaturing conditions using anti-cholera antibody (A), anti-rabies antibody (B) and under denaturing condition
using anti-rabies antibody (C). Crude protein (30 lg) prepared from the leaves of non-transgenic (NT) and transgenic T 0 plants #1, 2 and 3 was loaded along with molecular
weight markers (M).
at 370C
at 40C
GM1 concentration (µM)
A 4 0 5 n m
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
0.45
0.5
0 2 4 6 8 10
Bacterial CtxB
plant CtxB
CtxB-G
BSACtxB-G
plant CtxB
bacterial CtxB
BSA
Fig. 6. GM1 binding analysis of the plant-CtxB, CtxB-G and the bacterial CtxB. Binding affinity of the proteins to GM1 was determined by GM1-ELISA at 4 or 37 C. Microtiter
plates, precoated with different concentrations of GM1, were treated with different proteins at 3 lg/ml concentration. BSA was taken as negative control. To detect the
amount of the bound proteins, the wells were incubated with anti-CtxB antibody and ALP conjugated secondary antibody, followed by the addition of substrate. The
absorbance at 405 nm plotted on Y -axis shows the amount of CtxB bound at increasing concentrations of GM1 receptor.
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hance the immuno-protective ability of G protein given through
oral/mucosal epithelium or in the form of an edible vaccine.
In our study, the native signal peptide of CtxB was replaced by
the tobacco PR-S signal peptide [18], which efficiently transports
proteins into the endoplasmic reticulum of plant cells. The addition
of the ER retention signal at the C-terminus has been suggested to
enhance the accumulation of recombinant proteins in transgenic
plants [27,28]. The glycine–proline hinge provides flexibility to
independently folding domains of the chimeric protein and allows
their folding with little steric hindrance. The fusion proteins carry-
ing CtxB either at the N-terminus [29–31] or the C-terminus
[32,33] or even internally within the CtxB sequence [34,35] have
been produced and characterized earlier. Gonzalez et al. [31] re-
ported that a CtxB fusion protein carrying 18 amino acid N-termi-
nal extension retained activity with respect to pentamerization
and GM1 binding. In another study [29], it was shown that the
affinity of the chimeras for GM1 was inversely proportional to
the size of the peptide fused to the N-terminus of CtxB. Our resultsshow that the G- protein, in spite of being about five fold larger
than the CtxB, allowed the latter to pentemerize in the fusion
and bind to the GM1 receptors. The fusion protein retained antige-
nicity of both the component proteins.
The expression of CtxB-G protein in different transgenic plants
showed wide variation, i.e. 0.002–0.4% of TSP in leaf. This is consis-
tent with the transcript level noticed by real-time PCR. The varia-
tion in expression is understandably due to integration of the
transgene at different positions in the genome of independent
transgenic lines [36]. We have earlier reported a high level expres-
sion of synthetic G protein in the selected tobacco lines, i.e. at
0.38% of TSP [17]. In another study, the chimeric rabies virus pep-
tide fused to the N-terminus of AlMV CP was reported to accumu-
late at levels reaching 0.4 ± 0.07 mg/g of fresh spinach leaf tissue[26].
GM1-ELISA using the peptide antibody against the G protein
and the equine anti-rabies antibody established that the pentamer-
ic fusion protein maintained immunologically active G protein do-
mains. However, the absorbance values of CtxB-G protein in GM1-
ELISA were lower than the absorbance values in indirect ELISA for
the two antibodies. This is be due to higher binding of CtxB to GM1
receptors coated on the ELISA plates as compared to its binding to
the plates in indirect ELISA.The binding assay showed that a pentameric CtxB was formed
with functionally correct folding and assembly of the chimeric
CtxB-G expressed in tobacco leaves. These results suggest that
the folding of the fusion protein was driven by CtxB though this
is the smaller (14.6 kDa) partner in the 80.6 kDa chimeric protein.
Earlier, we reported that the plant-synthesized CtxB shows a high-
er affinity for binding to GM1 as compared to the bacterial CtxB
[16]. The glycosylation of the plant-expressed CtxB was predicted
to facilitate functionally more favorable folding of the CtxB in to-
bacco cells. Here we show that the binding affinity of CtxB-G pro-
tein to GM1 was lower than that of CtxB expressed in tobacco
leaves. This may be due to the bulky nature of the G protein in
CtxB-G protein pentamer (403 kDa) which may cause steric hin-
drance to the binding of CtxB to GM1 receptor as compared tothe binding of CtxB pentamer (73 kDa). The G protein has three po-
tential N-linked glycosylation sites at Asn37, Asn247 and Asn319
positions [37]. The chaperones, other folding enzymes [38,39]
and the glycosylation in plant cells may lead to an increase in affin-
ity of the CtxB for GM1 receptors as compared to the non-glycos-
ylated bacterial CtxB. The binding affinity of the three proteins to
GM1 was higher at 37 C than at 4 C. Maximum binding of the
cholera toxin to GM1 is reported to occur within 1 h at 370C
[40]. Though the binding assay was carried out using crude extract
of the proteins, binding curves, nevertheless, demonstrate that the
three pentemeric proteins bound GM1 with different affinities.
This study describes the expression and assembly of the CtxB-G
protein fusion in transgenic tobacco plants. The assembly of CtxB-
G protein monomers into biologically active pentamers in trans-
formed tobacco leaf tissue suggests that CtxB-G protein antigen ex-
pressed in plants may show efficient internalization through the
mucosal receptors. This may enhance immunogenic ability of the
CtxB-G protein fusion against rabies following oral and mucosal
immunization. Differences in binding constants of the CtxB ex-
pressed in different cellular systems suggest the need to examine
the folding and functional behavior of proteins obtained from het-
erologous expression systems.
Acknowledgments
We greatly acknowledge the financial support provided by
Council for Scientific and Industrial Research and to the Depart-
ment of Science and Technology for J.C. Bose Fellowship to RakeshTuli. We thank Shadma Ashraf for the construct of the rgp and S.
Mishra for the ctxB genes, reported earlier.
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M, molecular weight markers and S, purified protein sample.
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