Inhibitory activities of Typhonium trilobatum (L.) Schott on virulence potential of multi-drug resistant toxigenic Vibrio cholerae.

Cholera is a serious epidemic disease caused by the toxigenic strains of Vibrio cholerae belonged to O1 or O139 serogroups. The emergence of antibacterial resistance in V. cholerae is an increasing concern. Natural product drug invention and Ethnopharmacology may demonstrate a considerable expectation under this circumstance. Traditionally, leaves of Typhonium trilobatum (L.) Schott (locally known as Ghatkanchu or Bengal Arum) are employed for treatment of gastrointestinal disorder in different region of India. The objective of the present study was to evaluate the antibacterial, and antibiofilm activities of methanol extract of T. trilobatum leaves (METTL) against the strains of multi-drug resistant (MDR) Vibrio cholerae (serotypes O1, O139, non-O1, and non-O139) which are responsible for watery diarrhea such as cholera. MIC, MBC and time-kill kinetic studies were used for evaluation of In vitro antibacterial activity of METTL. Microdilution method and Confocal laser scanning microscopy were used to evaluate biofilm-inhibitory activities. The gene expression was analyzed by performing Quantitative real-time PCR (qRT-PCR). METTL showed antibacterial activity with MIC and MBC at 1-32 mg/mL and 8-32 mg/mL, respectively against the clinical strains of Vibrio cholerae belonged to different serogroups. METTL showed significant (P < 0.05) inhibitory activity on the formation of biofilm by V. cholerae SG24, with 81.3, 75.8, and 69.6% of inhibition at MIC, ½ MIC and » MIC, respectively. METTL showed also significant (P < 0.05) inhibitory activity on the formation of extracellular polymeric substances (EPS) formation by V. cholerae SG24, with 89.41, and 99.26% of inhibition of EPS protein and EPS carbohydrate at MIC, respectively. METTL significantly (p < 0.01) inhibited the Cholera toxin (CT) production by the V. cholerae strain SG24 evaluated by the CT - ELISA assay. The cholera toxin production was reduced by 76.26%, 48.76% and 29.93 at MIC (8 mg/mL), ½ MIC (4 mg/mL) and » MIC (2 mg/mL), respectively. METTL was shown to repress ctxAB gene transcription 1.76 fold (p < 0.05) at sub-bactericidal concentration (» MIC). We also found that the expression of cholera toxin activator genes, toxT and tcpP was reduced by 11.56- fold (p < 0.001) and 23.52- fold (p < 0.001), respectively, at sub-bactericidal concentration (» MIC). Transcription of the following genes was repressed: vpsR (1.8-fold; p < 0.05), Bap1 (1.53-fold; p ≤ 0.05), and rmbA (2.89-fold) by METTL at sub-bactericidal concentration. The expression of vpsT was also repressed by 1.5-fold (p < 0.01) at sub-bactericidal concentration. The active Typhonium trilobatum (L.) leaves extract may be suggested as an substitute for the treatment of MDR V. cholerae infection and could be used as prospective source for the development of novel antimicrobial compound/s and biofilm-inhibitory drug/s useful for the treatment of cholera and diarrheal patients. The results obtained here also validate scientifically the traditional uses of Typhonium trilobatum (L.) in India employed for the treatment of gastrointestinal disorder. Further studies should be directed at purifying and characterizing these antibacterial principles against Vibrio cholerae.

Nisin-induced expression of recombinant T cell epitopes of major Japanese cedar pollen allergens in Lactococcus lactis.

Japanese cedar pollinosis is a seasonal allergic disease caused by two major pollen allergens: Cry j 1 and Cry j 2 antigens. To develop an oral vaccine to treat pollinosis, we constructed recombinant Lactococcus lactis harboring the gene encoding fused T cell epitopes from the Cry j 1 and Cry j 2 antigens. The recombinant T cell epitope peptide was designed to contain the fused cholera toxin B subunit as an adjuvant and a FLAG tag at the C-terminus. An expression plasmid was constructed by inserting the T cell epitope peptide gene into the multiple cloning sites of plasmid pNZ8148, an Escherichia coli-L. lactis shuttle vector. The constructed plasmid was transformed into L. lactis NZ9000 for expression induced by nisin, an antibacterial peptide from L. lactis. The expression of the epitope peptide was induced with 10-40 ng/mL nisin, and the expressed T cell epitope peptide was detected by western blot analysis using an anti-FLAG antibody and an antibody against the T cell epitopes. The concentration of the epitope peptide was estimated to be ~ 22 mg/L of culture in the presence of 40 ng/mL nisin, although it varied depending on the nisin concentration, the culture time, and the bacterial concentration when nisin was added. The expression of the recombinant epitope peptide in L. lactis, an organism generally recognized as safe, as demonstrated in this study, may contribute to the development of an oral vaccine for the treatment of pollinosis.

Expression and assembly of cholera toxin B subunit and domain III of dengue virus 2 envelope fusion protein in transgenic potatoes.

The rates of mosquito-transmitted dengue virus infection in humans have increased in tropical and sub-tropical areas. Domain III of dengue envelope protein (EDIII) is involved in cellular receptor binding and induces serotype-specific neutralizing antibodies. EDIII fused to the B subunit of Vibrio cholera (CTB-EDIII) was expressed in potatoes to develop a plant-based vaccine against dengue virus type 2. CTB-EDIII fused to an endoplasmic reticulum (ER) retention signal, SEKDEL, was introduced into potatoes by A. tumefaciens-mediated gene transformation. The integration of the CTB-EDIII fusion gene into the nuclear genome of transgenic plants was confirmed by genomic DNA polymerase chain reaction (PCR), and mRNA transcripts of CTB-EDIII were detected. CTB-EDIII fusion protein was expressed in potato tubers and assembled into a pentameric form capable of binding monosialotetrahexosylganglioside (GM1). The level of expression was determined to be ∼0.005% of total soluble protein in potato tubers. These results suggest that dengue virus antigen could be produced in potatoes, raising the possibility that edible plants are employed in mucosal vaccines for protection against dengue infection.

Conjugated Linoleic Acid Reduces Cholera Toxin Production In Vitro and In Vivo by Inhibiting Vibrio cholerae ToxT Activity.

The severe diarrheal disease cholera is endemic in over 50 countries. Current therapies for cholera patients involve oral and/or intravenous rehydration, often combined with the use of antibiotics to shorten the duration and intensity of the disease. However, as antibiotic resistance increases, treatment options will become limited. Linoleic acid has been shown to be a potent negative effector of V. cholerae virulence that acts on the major virulence transcription regulator protein, ToxT, to inhibit virulence gene expression. ToxT activates transcription of the two major virulence factors required for disease, cholera toxin (CT) and toxin-coregulated pilus (TCP). A conjugated form of linoleic acid (CLA) is currently sold over the counter as a dietary supplement and is generally recognized as safe by the U.S. Food and Drug Administration. This study examined whether CLA could be used as a new therapy to reduce CT production, which, in turn, would decrease disease duration and intensity in cholera patients. CLA could be used in place of traditional antibiotics and would be very unlikely to generate resistance, as it affects only virulence factor production and not bacterial growth or survival.

Simultaneous visualization of extrinsic and intrinsic axon collaterals in Golgi-like detail for mouse corticothalamic and corticocortical cells: a double viral infection method.

Here we present a novel tracing technique to stain projection neurons in Golgi-like detail by double viral infection. We used retrograde lentiviral vectors and adeno-associated viral vectors (AAV) to drive "TET-ON/TET-OFF system" in neurons connecting two regions. Using this method, we successfully labeled the corticothalamic (CT) cells of the mouse somatosensory barrel field (S1BF) and motor cortex (M1) in their entirety. We also labeled contra- and ipsilaterally-projecting corticocortical (CC) cells of M1 by targeting contralateral M1 or ipsilateral S1 for retrograde infection. The strength of this method is that we can observe the morphology of specific projection neuron subtypes en masse. We found that the group of CT cells extends their dendrites and intrinsic axons extensively below but not within the thalamorecipient layer in both S1BF and M1, suggesting that the primary target of this cell type is not layer 4. We also found that both ipsi- and contralateral targeting CC cells in M1 commonly exhibit widespread collateral extensions to contralateral M1 (layers 1-6), bilateral S1 and S2 (layers 1, 5 and 6), perirhinal cortex (layers 1, 2/3, 5, and 6), striatum and claustrum. These findings not only strengthened the previous findings of single cell tracings but also extended them by enabling cross-area comparison of CT cells or comparison of CC cells of two different labeling.

Expression of the cholera toxin B subunit (CT-B) in maize seeds and a combined mucosal treatment against cholera and traveler's diarrhea.

The non-toxic B subunit (CT-B) of cholera toxin from Vibrio cholerae is a strong immunogen and amplifies the immune reaction to conjugated antigens. In this work, a synthetic gene encoding for CT-B was expressed under control of a γ-zein promoter in maize seeds. Levels of CT-B in maize plants were determined via ganglioside dependent ELISA. The highest expression level recorded in T(1) generation seeds was 0.0014% of total aqueous soluble protein (TASP). Expression level of the same event in the T(2) generation was significantly increased to 0.0197% of TASP. Immunogenicity of maize derived CT-B was evaluated in mice with an oral immunization trial. Anti-CTB IgG and anti-CTB IgA were detected in the sera and fecal samples of the orally immunized mice, respectively. The mice were protected against holotoxin challenge with CT. An additional group of mice was administrated with an equal amount (5 µg per dose each) of mixed maize-derived CT-B and LT-B (B subunit of E. coli heat labile toxin). In the sera and fecal samples obtained from this group, the specific antibody levels were enhanced compared to either the same or a higher amount of CT-B alone. These results suggest that a synergistic action may be achieved using a CT-B and LT-B mixture that can lead to a more efficacious combined vaccine to target diarrhea induced by both cholera and enterotoxigenic strains of Escherichia coli.

Greenhouse and field cultivations of antigen-expressing potatoes focusing on the variability in plant constituents and antigen expression.

The production of plant-derived pharmaceuticals essentially requires stable concentrations of plant constituents, especially recombinant proteins; nonetheless, soil and seasonal variations might drastically interfere with this stability. In addition, variability might depend on the plant organ used for production. Therefore, we investigated the variability in plant constituents and antigen expression in potato plants under greenhouse and field growth conditions and in leaves compared to tubers. Using potatoes expressing VP60, the only structural capsid protein of the rabbit haemorrhagic disease virus (RHDV), CTB, the non-toxic B subunit (CTB) of the cholera toxin (CTA-CTB(5)) and the marker protein NPTII (neomycinphosphotransferase) as a model, we compare greenhouse and field production of potato-derived antigens. The influence of the production organ turned out to be transgene specific. In general, yield, plant quality and transgene expression levels in the field were higher than or similar to those observed in the greenhouse. The variation (CV) of major plant constituents and the amount of transgene-encoded protein was not influenced by the higher variation of soil properties observed in the field. Amazingly, for specific events, the variability in the model protein concentrations was often lower under field than under greenhouse conditions. The changes in gene expression under environmental stress conditions in the field observed in another event do not reduce the positive influence on variability since events like these should excluded from production. Hence, it can be concluded that for specific applications, field production of transgenic plants producing pharmaceuticals is superior to greenhouse production, even concerning the stability of transgene expression over different years. On the basis of our results, we expect equal or even higher expression levels with lower variability of recombinant pharmaceuticals in the field compared to greenhouse production combined with approximately 10 times higher tuber yield in the field.

Expression of truncated CTB::VP60 in tobacco exhibited no immunogenicity in rabbits.

Despite several optimizations, the production of CTB::VP60 antigen fusion proteins in tobacco is still very low. This might be due to the size of the fusion partner VP60 (579 aa). Hence, two different N-terminal truncations of VP60 were fused to CTB, either with or without an ER retention signal. CTB::VP60 expression levels, in vitro and in vivo antigenicity and immunogenicity were analyzed in plants carrying one of four different transgenes. Only one of the truncated CTB::VP60 fusions (365 aa) directed to the endoplasmic reticulum led to similar but not enhanced expression levels as compared to the complete protein in tobacco and possessed similar in vitro antigenicity. In contrast to the complete protein, no anti-VP60-specific antibodies were induced in rabbits after the intramuscular application of plant extracts containing the truncated protein.

Cholera toxin B subunit-domain III of dengue virus envelope glycoprotein E fusion protein production in transgenic plants.

Envelope glycoprotein E of the dengue virus, which plays a crucial role in its entry into host cells, has an immunogenic domain III (EIII, amino acids 297-394), which is capable of inducing neutralizing antibodies. However, mice immunized with EIII protein without adjuvant elicited low immune responses. To improve low immune responses, a DNA fragment, consisting of cholera toxin B subunit and EIII gene (CTB-EIII), was constructed and introduced into tobacco plant cells (Nicotiana tabacum L. cv. MD609) by Agrobacterium tumefaciens-mediated transformation methods. The integration and transcription of CTB-EIII fusion gene were confirmed in transgenic plants by genomic DNA PCR amplification and Northern blot analysis, respectively. The results of immunoblot analysis with anti-CTB and anti-dengue virus antibodies showed the expression of the CTB-EIII fusion protein in transgenic plant extracts. Based on the G(M1)-ELISA results, the CTB-EIII protein expressed in plants showed the biological activity for intestinal epithelial cell membrane glycolipid receptor, G(M1)-ganglioside, and its expression level was up to about 0.019% of total soluble protein in transgenic plant leaf tissues. The feasibility of using a plant-produced CTB-EIII fusion protein to generate immunogenicity against domain III will be tested in future animal experiments.

Role of CTA1R7K-COL-DD as a novel therapeutic mucosal tolerance-inducing vector for treatment of collagen-induced arthritis.

OBJECTIVE: To determine whether a cholera toxin-derived, novel immunomodulating fusion protein, CTA1R7K-COL-DD, carrying the class II major histocompatibility complex H-2q-restricted type II collagen peptide aa 259-274, can induce therapeutic tolerance and prevent collagen-induced arthritis (CIA) when administered intranasally in DBA/1 mice, and to assess whether ADP-ribosylation at the mucosal membranes exerts a regulatory function such that the outcome of tolerance or immune enhancement can be controlled. METHODS: DBA/1 mice with CIA were treated intranasally with CTA1R7K-COL-DD. The therapeutic effect was monitored for 46 days after the onset of disease. Clinical scoring of disease, histologic examination of inflammation, and bone erosion were assessed, and cytokine levels were determined in the serum or supernatants from splenocytes stimulated with recall antigen. RESULTS: The protective effect of CTA1R7K-COL-DD resulted in roughly 60% of the mice having no clinical signs or histologic evidence of disease after treatment, and those with CIA had significantly milder disease with less bone erosion. The protective status was associated with lower serum titers of IgG1, IgG2a, IgG2b, and IgG3 anticollagen and a substantial decrease in the production of interleukin-6 (IL-6), IL-17, and interferon-gamma, while levels of IL-10 were markedly up-regulated both in the serum and at the T cell level. CONCLUSION: The enzymatically inactive mutant fusion protein CTA1R7K-COL-DD provided substantial therapeutic protection against CIA following intranasal administration. The mechanism behind the effect appears to be mediated by peptide-specific regulatory T cells induced by mucosal exposure to the peptide containing CTA1R7K-COL-DD vector. In addition, ADP-ribosylation at the mucosal membranes acts as a key regulator controlling mucosal tolerance or immunity.

Expression and assembly of cholera toxin B subunit (CTB) in transgenic carrot (Daucus carota L.).

We expressed the cholera toxin B subunit (CTB) fused to an endoplasmic reticulum retention signal (SEKDEL) in carrot roots using an Agrobacterium-mediated transformation method. Fourteen independent transgenic lines were regenerated via somatic embryogenesis after 6 months of culture. The sCTB gene was detected in the genomic DNA of transgenic carrot by PCR amplification. Expressions and assembly of sCTB protein into oligomeric structures of pentameric size were observed in transgenic plant extracts by Western blot analysis. The sCTB produced by transgenic carrot roots demonstrated strong affinity for GM1-ganglioside, suggesting that the sCTB conserved the antigenic sites for binding and proper folding of the pentameric sCTB structure. The expression level of sCTB comprised approximately 0.48% of total soluble protein (TSP) in root of transgenic carrot.

Stable expression of foot-and-mouth disease virus protein VP1 fused with cholera toxin B subunit in the potato (Solanum tuberosum).

The expression vector, pBI121CTBVP1, containing the fusion of the foot and mouth disease virus (FMDV) VP1 gene and the cholera toxin B subunit (CTB) gene was constructed by fused PCR and transferred into potato (Solanum tuberosum L.) by Agrobacterium-mediated transformation. Transformed plants were obtained by selecting on kanamycin-resistant medium strictly and regenerated. The transgenic plantlets were identified by PCR, Southern-blot and the production of fused protein was confirmed and quantified by Western-blot and ELISA assays. The results showed that the fused genes were expressed stablely under the control of specific-tuber patatin promoter. The expressed fused proteins have a certain degree of immunogenicity.

Antibodies enhance interaction of Vibrio cholerae with intestinal M-like cells.

Intestinal M cells bear a receptor for secretory immunoglobulin A (IgA) (sIgA) facing the lumen of the epithelial surfaces. Cells bearing this receptor are also found throughout an experimental monolayer consisting of polarized Caco-2 cells, a colon adenocarcinoma cell line. The presence of antibodies (mainly sIgA) in the lumen of the small intestine led us to explore the participation of the sIgA receptor and antibodies in the interaction of Caco-2-associated M-like cells with the mucosal pathogen Vibrio cholerae. Here, we demonstrate that sIgA antibodies isolated from pooled healthy human colostrums, as well as IgG from pooled healthy human serum, can recognize V. cholerae. Furthermore, opsonization enhances M-like-cell transcytosis of V. cholerae strains. We also show that the cholera toxin (CT) receptor ganglioside GM(1) colocalizes with the sIgA receptor in cells of the epithelial monolayer. Both sIgA and IgG antibodies compete for the attachment of soluble CT subunit B to immobilized GM(1). Our results indicate that in this in vitro model system of intestinal epithelia, human sIgA and IgG contribute to the uptake of V. cholerae by M-like cells, probably through an interaction with GM(1). Our results support previous findings of others showing that sIgA can act as an endogenous adjuvant and that sIgA is important for the antigen-sampling function of M cells.

Synthesis and assembly of an adjuvanted Porphyromonas gingivalis fimbrial antigen fusion protein in plants.

The gram-negative anaerobic oral bacterium Porphyromonas gingivalis initiates periodontal disease by binding to saliva-coated oral surfaces. To assess whether edible plants can synthesize biologically active P. gingivalis fimbrial antigen, for application as an oral vaccine, a cDNA fragment encoding the C-terminal binding portion of P. gingivalis fimbrial protein (FimA), was cloned into a plant expression vector immediately downstream of a cDNA fragment encoding the cholera toxin B subunit (CTB). The chimeric plasmid was transferred into potato (Solanum tuberosum) cells and the ctb-fimA cDNA fragment detected in transformed leaf genomic DNA by PCR amplification methods. A novel protein band of 21 kDa was detected in transformed potato tuber extracts by immunoblot analysis. Oligomeric CTB-FimA (266-337) fusion protein was identified in the extracts through the binding of anti-CTX and anti-native fimbriae antibodies. The pentameric structure of CTB-FimA fusion protein was confirmed by ELISA measurements of GM1 ganglioside receptor binding. Quantification of the CTB-FimA fusion protein by ELISA indicated that the chimeric protein made up about 0.33% of total soluble tuber protein. The biosynthesis of immunologically detectable CTB-FimA fusion proteins and the assembly of fusion protein monomers into biologically active pentamers in transformed potato tuber tissues demonstrate the feasibility of synthesizing adjuvanted fimbrial protein in edible plants for development of adjuvanted mucosal vaccines against P. gingivalis generated periodontal disease.

Synthesis and assembly of a cholera toxin B subunit-rotavirus VP7 fusion protein in transgenic potato.

A gene encoding VP7, the outer capsid protein of simian rotavirus SA11, was fused to the carboxyl terminus of the cholera toxin B subunit gene. A plant expression vector containing the fusion gene under control of the mannopine synthase P2 promoter was introduced into Solanum tuberosum cells by Agrobacterium tumefaciens-mediated transformation. The CTB::VP7 fusion gene was detected in the genomic DNA of transformed potato leaf cells by polymerase chain reaction (PCR) amplification methods. Immunoblot analysis of transformed potato tuber tissue extracts showed that synthesis and assembly of the CTB::VP7 fusion protein into oligomers of pentameric size occurred in the transformed plant cells. The binding of CTB::VP7 fusion protein pentamers to sialo-sugar containing GM1 ganglioside receptors on the intestinal epithelial cell membrane was quantified by enzyme-linked immunosorbent assay (ELISA). The ELISA results showed that the CTB::VP7 fusion protein made up approx 0.01% of the total soluble tuber protein. Synthesis and assembly of CTB::VP7 monomers into biologically active pentamers in transformed potato tubers demonstrates the feasibility of using edible plants as a mucosal vaccine for the production and delivery system for rotavirus capsid protein antigens.

Enterotoxin-based mucosal adjuvants alter antigen trafficking and induce inflammatory responses in the nasal tract.

The safety of nasal vaccines containing enterotoxin-based mucosal adjuvants has not been studied in detail. Previous studies have indicated that native cholera toxin (nCT) can alter antigen trafficking when applied nasally. In this study, we determined the enterotoxin-based variables that alter antigen trafficking. To measure the influence of enterotoxin-based mucosal adjuvants on antigen trafficking in the nasal tract, native and mutant enterotoxins were coadministered with radiolabeled tetanus toxoid (TT). The nCT and heat-labile enterotoxin type 1 (LTh-1) redirected TT into the olfactory neuroepithelium (ON/E). Antigen redirection occurred mainly across the nasal epithelium without subsequent transport along olfactory neurons into the olfactory bulbs (OB). Thus, no significant accumulation of the vaccine antigen TT was observed in the OB when coadministered with nCT. In contrast, neither mutant CT nor mutant LTh-1, which lack ADP-ribosyltransferase activity, redirected TT antigen into the ON/E. Thus, ADP-ribosyltransferase activity was essential for antigen trafficking across the olfactory epithelium. Accumulation of TT in the ON/E was also due to B-subunit binding to GM1 gangliosides, as was demonstrated (i) by redirection of TT by LTh-1 in a dose-dependent manner, (ii) by ganglioside inhibition of the antigen redirection by LTh-1 and nCT, and (iii) by the use of LT-IIb, a toxin that binds to gangliosides other than GM1. Redirection of TT into the ON/E coincided with elevated production of interleukin 6 (IL-6) but not IL-1beta or tumor necrosis factor alpha in the nasal mucosa. Thus, redirection of TT is dependent on ADP-ribosyltransferase activity and GM1 binding and is associated with production of the inflammatory cytokine IL-6.

Synthesis and assembly of SIVmac Gag p27 capsid protein cholera toxin B subunit fusion protein in transgenic potato.

A deoxyribonucleic acid (DNA) fragment encoding the cholera toxin B subunit (CTB) was linked 5' to the simian immunodeficiency virus (SIVmac) Gag p27 capsid gene (CTB-Gag). The fusion gene was transferred into Solanum tuberosum cells by Agrobacterium tumefaciens-mediated transformation methods and transformed plants regenerated. The CTB-Gag gene fusion was detected in transformed potato leaf genomic DNA by polymerase chain reaction-mediated DNA amplification. The results of immunoblot analysis with anti-CTB and anti-Gag antibodies verified the synthesis of biologically active CTB-Gag fusion protein in transformed leaf and tuber tissues. Synthesis and assembly of the CTB-Gag fusion protein into oligomeric structures of pentamer size was confirmed by GM1-ganglioside-enzyme-linked immunosorbent assay (GM1-ELISA) of transformed potato tuber tissue extracts. The binding of CTB-Gag fusion protein oligomers to intestinal epithelial cell membrane receptors quantified by GM1-ELISA showed that CTB-Gag fusion protein made up approx 0.016-0.022% of the total soluble tuber protein. The synthesis of CTB-Gag monomers and their assembly into biologically active CTB-Gag fusion protein oligomers in potato tuber tissues provides the opportunity for employment of the carrier and adjuvant properties of CTB for the development of edible plant-based subunit mucosal vaccines for enhanced mucosal immunity against SIV in macaques.

HIV-1 gp120 V3 cholera toxin B subunit fusion gene expression in transgenic potato.

A cDNA fragment encoding the V3 loop of human immunodeficiency virus type-1 (HIV-1) envelope glycoprotein gp120 was fused to the cholera toxin B subunit gene (CTB-gp120) and transferred into Solanum tuberosum cells by Agrobacterium tumefaciens-mediated transformation. The CTB-gp120 fusion gene was detected in genomic DNA from transformed potato leaves by PCR DNA amplification. Synthesis and assembly of the CTB-gp120 fusion protein into oligomeric structures of pentamer size was detected in transformed tuber extracts by immunoblot analysis. The binding of CTB-gp120 fusion protein pentamers to intestinal epithelial cell membrane glycolipid receptors was quantified by GM1-ganglioside enzyme-linked immunosorbent assay (GM1-ELISA). The ELISA results indicated that CTB-gp120 fusion protein made up 0.002-0.004% of the total soluble tuber protein. Synthesis of CTB-gp120 monomers and their assembly into biologically active oligomers in transformed potato tuber tissues demonstrates for the first time the expression of HIV-1 gp120 in plants and emphasizes the feasibility of using edible plant-based vaccination for protection against HIV-1 infection.

Synthesis and assembly of a cholera toxin B subunit SHIV 89.6p Tat fusion protein in transgenic potato.

A cDNA encoding the simian-human immunodeficiency virus (SHIV 89.6p) Tat regulatory element protein was fused to the c-terminus of the cholera toxin B subunit gene (ctxB-tat) and introduced into Solanum tuberosum cells by Agrobacterium tumefaciens-mediated transformation methods. The fusion gene was detected in the genomic DNA of transformed potato leaf cells by PCR DNA amplification. Synthesis and assembly of the CTB-Tat fusion protein into oligomeric structures of pentamer size was detected in transformed tuber extracts by immunoblot analysis. The binding of CTB-Tat fusion protein pentamers to intestinal epithelial cell membrane glycolipid receptors was quantified by G(M1)-ganglioside enzyme-linked immunosorbent assay (G(M1)-ELISA). Based on the ELISA results, CTB-Tat fusion protein made up about 0.005-0.007% of total soluble tuber protein or approximately 4.6mg per 100g potato tuber tissue. The synthesis and assembly of CTB-Tat monomers into biologically active oligomers in transformed potato tuber tissues demonstrates the feasibility of using viral pathogen antigens synthesized in edible plants for mucosal immunization against HIV-1 infection.

Assembly of cholera toxin B subunit full-length rotavirus NSP4 fusion protein oligomers in transgenic potato.

A CTB-NSP4(175) fusion gene encoding the entire 175-aa murine rotavirus NSP4 enterotoxin protein was transferred into Solanum tuberosum cells by Agrobacterium tumefaciens-mediated transformation. The CTB-NSP4(175) enterotoxin fusion gene was detected in the genomic DNA of transformed leaves by PCR DNA amplification. Synthesis and assembly of the full-length CTB-NSP4(175) fusion protein into oligomeric structures of pentamer size was detected in transformed tuber extracts by immunoblot analysis. The binding of CTB-NSP4(175 )fusion protein pentamers to intestinal epithelial cell membrane receptors was quantified by G(M1)-ganglioside enzyme-linked immunosorbent assay (G(M1)-ELISA). The ELISA results showed that CTB-NSP4(175) fusion protein was 0.006-0.026% of the total soluble tuber protein. The synthesis of CTB-NSP4(175) monomers and their assembly into biologically active oligomers in transformed potato tubers demonstrates the feasibility of using edible plants for the synthesis of enterocyte-targeted full-length rotavirus enterotoxin antigens that retain all of their pathogenic epitopes for initiation of a maximum mucosal immune response.