Stable Escherichia coli-Clostridium acetobutylicum Shuttle Vector for Secretion of Murine Tumor Necrosis Factor Alpha

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Applied and Environmental Microbiology, October 1999, p. 4295-4300, Vol. 65, No. 10
0099-2240/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Stable Escherichia coli-Clostridium acetobutylicum Shuttle Vector for Secretion of Murine Tumor Necrosis Factor Alpha

J. Theys,¹ S. Nuyts,² W. Landuyt,² L. Van Mellaert,¹ C. Dillen,³ M. Böhringer,⁴ P. Dürre,⁴ P. Lambin,² and J. Anné¹^,^*

Laboratories of Bacteriology¹ and Immunobiology,³ Rega Institute, Katholieke Universiteit Leuven, and Experimental Radiobiology, University Hospital Gasthuisberg,² Leuven, Belgium, and Microbiology and Biotechnology, University Ulm, Ulm, Germany⁴

Received 30 April 1999/Accepted 29 July 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Recombinant plasmids were constructed to secrete mouse tumor necrosis factor alpha (mTNF- $alpha$ ) from Clostridium acetobutylicum.The shuttle plasmids contained the clostridial endo- $beta$ 1,4-glucanase(eglA) promoter and signal sequence that was fused in frame tothe mTNF- $alpha$ cDNA. The construction was first tested in Escherichiacoli and then introduced in C. acetobutylicum DSM792 by electroporation.Controls confirmed the presence and stability of the recombinantplasmids in this organism. Sodium dodecyl sulfate-polyacrylamidegel electrophoresis and an in vitro cytotoxic assay were usedto monitor expression and secretion of mTNF- $alpha$ during growth. Significantlevels of biologically active mTNF- $alpha$ were measured in both lysatesand supernatants. The present report deals with investigationson the elaboration of a gene transfer system for cancer treatmentusing anaerobicbacteria.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The genus Clostridium comprises a heterogeneous group of rod-shaped, anaerobic, gram-positive, endospore-forming bacteria.Understanding the molecular biology of clostridia brings withit improved prospects for biotechnological exploitation. The developmentof suitable molecular tools, especially transformation proceduresand specialized shuttle vectors, made it possible to introduceand express both homologous and heterologous genes in these microorganisms(20). Recently, attention has been paid to the use of nonpathogenic(24) or avirulent bacteria (18, 27) as delivery systemsof therapeutic genes in anticancer therapy. These strategies havebeen shown to be safe in use. Colonization occurs selectivelyin tumors, not in normal tissues (12), and treatment can bestopped with suitable antibiotics (11).

Taken together, these technologies provide a new approach to use genetically engineered bacteria in the treatment of cancer.So far, constructs based on the pMTL500F shuttle vector with theEscherichia coli genes cytosine deaminase and nitroreductase havebeen developed (4, 17). The expression of the cloned geneshas been evaluated in Clostridium beijerinckii, but the therapeuticvalue of these achievements has yet to be realized. In this context,the present investigations were aimed at the establishment ofa recombinant Clostridium acetobutylicum that secretes mouse tumornecrosis factor alpha (mTNF- $alpha$ ). This therapeutic agent was selectedbecause it is a cytokine with multiple antitumor effects (28).These include selective action on the neovasculature of tumors,stimulation of T-cell-mediated immunity, and direct cytotoxicityto tumor cells, mainly through induction of apoptosis (3, 15,16, 40). Moreover, enhancement of the antiproliferative effectof tumor cells was demonstrated in vivo when TNF- $alpha$ was combinedwith irradiation (6, 31). However, systemic toxicity hampersits straight use. Therefore, innovative strategies are requiredto increase the therapeutic efficacy of TNF- $alpha$ treatment. One approachis to increase the effective concentration to which the tumoris exposed by using local treatment as proposed with the bacterialgene transfer system. Since we are specifically interested instudying the effects of introducing mTNF- $alpha$ in the tumor microenvironment,it was necessary to construct a vector which after introductionin Clostridium provoked the secretion of the therapeuticagent.

This report describes the cloning of mTNF- $alpha$ cDNA in a stable E. coli-Clostridium shuttle vector. As a proof of principle thatmTNF- $alpha$ can be produced by C. acetobutylicum DSM792, mTNF- $alpha$ cDNAwas placed under transcriptional control of the endo- $beta$ 1,4-glucanase(eglA) promoter of C. acetobutylicum P262 and fused to the eglAsignal sequence. Data on mTNF- $alpha$ production by recombinant C. acetobutylicumDSM792 arepresented.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacterial strains, plasmids, and culture conditions. C. acetobutylicum DSM792 was obtained from the Deutsche Sammlung von Mikroorganismen und Zellkulturen GmbH (Braunschweig,Germany). The strain was grown in 2× YT medium (26) or reinforcedclostridial medium (Difco Laboratories, Detroit, Mich.) at 37°Cin an anaerobic system (model 1024; Forma Scientific, Marietta,Ohio) with 90% N₂ and 10% H₂ with palladium as the catalyst. Foranalysis of mTNF- $alpha$ production, Clostridium was cultivated in 5-mlaliquots of 2× YT medium after 1/10 inoculation with an overnightculture. The medium was buffered at pH 7.2 with filter-sterilizedmorpholinepropanesulfonic acid (MOPS) (Sigma) added at a finalconcentration of 50mM.

For primary vector constructions, E. coli TG1 (29) was used. In vitro mutagenesis was carried out with E. coli JM109 (29)and E. coli BMH 71-18mut S (37). These strains were regularlygrown in Luria-Bertani broth at 37°C (300 rpm). Prior to electroporation,plasmids were methylated in vivo in E. coli ER2275(pAN1) (22).After isolation, plasmid DNA preparations were desalted by twospins in Microcon 100 microconcentrators (Amicon, Inc., Beverly,Mass.) as recommended by themanufacturer.

Media were supplemented, when applicable, with erythromycin (25 µg/ml), ampicillin (50 µg/ml), chloramphenicol (35 µg/ml),isopropyl- $beta$ -thiogalactopyranoside (IPTG; 50 µg/ml), or 5-bromo-4-chloro-3-indolyl- $beta$ -galactoside(X-Gal; 40 µg/ml).

Shuttle vectors used in this study are listed in Table 1. Plasmid pHZ117, containing the eglA gene of C. acetobutylicum P262,was a gift from H. Zappe (39). The mTNF- $alpha$ cDNA was availableon plasmid pIG2mTNF (Innogenetics, Ghent, Belgium).

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TABLE 1. Shuttle vectors used in this study

Transformation procedures and DNA manipulations. E. coli was transformed by using chemically competent cells obtained with the RbCl method. Transformation of C. acetobutylicumwas carried out by electroporation as recently published (25).In brief, cells were grown in 50 ml of reinforced clostridialmedium until mid-log phase, washed with ice-cold electrotransformationbuffer (270 mM sucrose, 0.6 mM Na₂HPO₄, 4.4 mM NaH₂PO₄, 10 mMMgCl₂ [pH 6]), and finally resuspended in 2 ml of electrotransformationbuffer without MgCl₂. A 0.6-ml sample of the cell suspension wastransferred to a 0.4-cm electroporation cuvette containing 1 to5 µl of methylated plasmid DNA (0.1 to 1.5 µg). After the pulse(1.8 kV, 600 $Omega$ , 50 µF), cell suspensions were diluted with 1.4ml of 2× YT medium and incubated for 4 h at 37°C, before the cellswere spread on selective plates and incubated for 3 to 5 daysat 37°C.

All general DNA manipulations in E. coli were carried out essentially as described by Sambrook et al. (29). Restrictionendonucleases and DNA-modifying enzymes were purchased from RocheDiagnostics (Brussels, Belgium), GIBCO BRL (Gaithersburg, Md.),and Eurogentec (Seraing, Belgium) and used as indicated by thesuppliers.

DNA plasmid isolation from E. coli was performed with the Wizard Plus SV miniprep kit (Promega Inc., Madison, Wis.). PlasmidDNA was isolated from C. acetobutylicum by the alkaline lysisprocedure described by Nakotte et al. (25).

Mutations were carried out with the Altered Sites in vitro mutagenesis kit from Promega. Oligonucleotides for mutagenesiswere purchased from Eurogentec or Amersham Pharmacia Biotech.Oligonucleotides used were 5'-GCTGAAGCTTCAACAACATC-3' (for introductionof the HindIII site in eglA) and 5'-GACTACTTGATCTTACGTAGATTTAAACCTCCTG-3'(for introduction of the SnaBI site in mTNF- $alpha$ cDNA). The DNA fragmentscontaining the introduced mutations were subcloned in pUC19 toverify the mutations by DNA sequencing with an automated laserfluorescent ALF DNA sequencer (Amersham Pharmacia Biotech). Primersused for sequencing were the fluorolabeled M13 universal and reverseprimer.

DNA probes for Southern blotting experiments were labeled with digoxigenin. Labeling efficiency was checked by using chemiluminescentdetection as recommended by the manufacturer (Roche Diagnostics).Southern blotting was performed with an optimized hybridizationprotocol (9).

Vector construction. pHZ117 was digested with HindIII/SacI. The resulting 1.2-kb eglA fragment was isolated and subcloned in pSelect. A HindIIIsite was introduced four codons upstream of the signal sequence.A SnaBI site was created at the first codon of the mTNF- $alpha$ cDNA,available on the pIG2mTNF plasmid, resulting in pIG2mTNFSnaBI(13). A 0.5-kb EcoRI/HindIII fragment containing the eglA promoter,ribosome binding site, and signal sequence was next cloned inpBR322. Restriction digestion with HindII and HindIII, followedby Klenow polymerase treatment, resulted in a 0.9-kb blunt-endedfragment. This fragment was isolated and ligated in the pIG2mTNFSnaBIvector that was previously digested with SnaBI. The obtained constructwas designated pIG2eglAmTNF. Subsequently, the eglAmTNF fragmentwas digested from the pIG2eglAmTNF plasmid by EcoRI and insertedinto the EcoRI site of the different shuttle vectors (Fig. 1).

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FIG. 1. Schematic representation of the construction of the pIMP1eglATNF and the pKNT19eglATNF shuttle vector and of the mutations introduced in the original eglA sequence and the mTNF- $alpha$ cDNA. P_eglA, promoter region of eglA; SS_eglA, signal sequence of eglA; SD, Shine-Dalgarno sequence; SPase, signal peptidase cleavage site (indicated by $up-arrow$ ).

Determination of segregational plasmid stability. Five milliliters of fresh 2× YT medium containing erythromycin was inoculated with 0.5 ml of late-exponential-growth-phasecultures of recombinant C. acetobutylicum DSM792 strains. Cultureswere subsequently subcultivated every day into 5 ml of fresh 2×YT medium without erythromycin pressure over a 6-day period. Thesecultures were diluted and subsequently plated onto both selectiveand nonselective 2× YT plates. The numbers of colonies on selectiveand nonselective growth media were compared to determine plasmidstability [expressed as a percentage; (number of Em^r colonies on selective plates)/(total number of colonies on nonselectiveplates) × 100]. Randomly isolated colonies from selective plateswere examined for the presence of plasmidDNA.

Detection and quantification of mTNF- $alpha$ . For mTNF- $alpha$ quantification, cells were harvested at various time periods during growth. At each interval, 0.5 ml of cell suspensionwas pelleted by centrifugation (Sorvall MC; 12 V, 12,000 rpm,2 min). The supernatant was removed and immediately stored at $-$ 80°C. The cell pellet was resuspended in 0.5 ml of 100 mM Tris-HCl(pH 7.4), and the cells were lysed by sonication with two pulsesof 20 s. Cellular debris was thereafter pelleted by centrifugation(12,000 rpm, 2 min), and the cleared lysate was stored at $-$ 80°C.Subsequently, the amount of biologically active mTNF- $alpha$ in lysatesand supernatants was determined as described by Heremans et al.(8) by using recombinant mTNF- $alpha$ (specific activity, 2.5 × 10⁸ U mg¹) produced in E. coli as the standard. Briefly, cytotoxicity ofmTNF- $alpha$ towards WEH164 clone 13 cells was spectrophotometricallyevaluated via the in situ reduction of 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazoliumbromide (MTT), measuring the percentage of deadcells.

Immunoblot analysis with polyclonal rabbit anti-mTNF- $alpha$ antibodies was carried out by the method of Van Mellaert et al. (35).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Construction of shuttle vectors containing the mTNF- $alpha$ cDNA and Clostridium transformation. The vectors used to construct recombinant plasmids containing the mTNF- $alpha$ cDNA are listed in Table 1. To investigate the possibilityof expressing and secreting mTNF- $alpha$ in Clostridium, the promoterand signal sequence of the endo- $beta$ 1,4-glucanase (eglA) gene ofC. acetobutylicum P262 were chosen as a model. As outlined inFig. 1, to obtain in-frame fusions between the eglA signal sequenceand the mTNF- $alpha$ coding sequence, restriction sites were createdin the 3' end of eglA as well as in the 5' end of the mTNF- $alpha$ cDNA.The introduction of the mutated restriction sites to fuse theregulatory sequence with the region at the start of the codingsequence ensured that the authenticity of the nucleotide sequenceremained. Correct in-frame fusion was controlled by restrictiondigestion and by DNA sequence analysis. The eglA promoter is activein E. coli. As a consequence, it was possible to test lysatesfor the production of mTNF- $alpha$ . Immunoblotting of the proteins ofthe cell lysates clearly demonstrated the presence of mTNF- $alpha$ (datanotshown).

Verification of the recombinant constructs in C. acetobutylicum DSM792. The recombinant constructs were methylated in vivo before they were introduced into Clostridium by electroporation. The obtainedelectroporation efficiency was ~10² transformants µg of DNA¹. The recombinant plasmids were isolated from C. acetobutylicumby using a modified plasmid isolation protocol and visualizedafter electrophoresis on a 1% agarose gel and staining with ethidiumbromide (Fig. 2). The pIMP1eglATNF and pKNT19eglATNF constructswere stably maintained in the clostridial host. This was confirmedby restriction digestion analysis and by transformation of E.coli with the isolated plasmid DNA. Southern blotting of isolatedplasmid DNA either from Clostridium or from the transformed E.coli cultures with a digoxigenin-labeled specific mTNF- $alpha$ proberesulted in the expected signal for the construct with pIMP1 andpKNT19 but not for the construct with pMTL500E (data not shown).

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FIG. 2. Photograph of isolated plasmids pIMP1eglATNF and pKNT19eglATNF after gel electrophoresis on a 1% agarose gel stained with ethidium bromide. (A) Lanes: 1, $lambda$ DNA digested with EcoRI and HindIII; 2, pIMP1eglATNF isolated from recombinant E. coli TG1; 3 and 4, pIMP1eglATNF isolated from recombinant C. acetobutylicum DSM792. (B) Lanes: 1, $lambda$ DNA digested with EcoRI and HindIII; 3, pKNT19eglATNF isolated from recombinant E. coli TG1; 2 and 4, pKNT19eglATNF isolated from recombinant C. acetobutylicum DSM792.

The segregational stability of both the pIMP1eglATNF and the pKNT19eglATNF construct was examined. Both plasmids were stablymaintained following repeated culture transfer over a 6-day periodin the absence of antibiotic pressure. The presence of plasmidDNA isolated from randomly selected colonies was confirmed byagarose gel electrophoresis (data notshown).

Immunoblot detection of mTNF- $alpha$ in C. acetobutylicum(pIMP1eglATNF) and C. acetobutylicum(pKNT19eglATNF) cultures was carriedout as described previously (35). Cultures of C. acetobutylicum(pIMP1),C. acetobutylicum(pKNT19), and plasmid-free C. acetobutylicumwere taken as a control. Lysates and supernatants from overnightcultures were assessed for mTNF- $alpha$ production. mTNF- $alpha$ was detectedin lysates of the recombinant cultures both as a preprotein (21kDa) and as the mature, processed form (17 kDa). In the supernatant,however, only the mature form was present (data not shown). NomTNF- $alpha$ was detected in lysates or supernatants of the Clostridiumcontrol cultures. These results clearly showed the functionalityof the promoter and signal sequence preceding the mTNF- $alpha$ cDNA.

Biological activity of produced mTNF. Samples of growing recombinant bacteria containing the pIMP1eglATNF or pKNT19eglATNF construct were taken at various stagesof growth (Fig. 3A), and the biological activity of mTNF- $alpha$ inlysates and supernatants was measured. Bacteria without a plasmidand bacteria with the pIMP1 or the pKNT19 vector alone were selectedfor controls. The activity was quantified by titration with themTNF- $alpha$ standard of known concentration (0.9 µg ml¹). Several independent experiments were performed, and the resultswere normalized towards the titer of the first experiment so thatthe data could be pooled. The normalization also allowed the interexperimentcomparison, showing confirmation for quantitative reproducibility.

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FIG. 3. Amount of biologically active mTNF- $alpha$ in supernatant ( $diamond$ ) and lysates (

) of C. acetobutylicum DSM792 transformed with pIMP1eglATNF and evolution of pH ( $black-triangle$ ) in nonbuffered (B) and buffered (C) medium as a function of growth time ( $black-lozenge$ ) (A). Error bars represent standard deviations.

The mTNF- $alpha$ concentration in lysates and supernatants of recombinant clostridia containing the pIMP1eglATNF plasmid increaseduntil the growing cells reached mid-log phase (optical densityat 600 nm, $congruent$ 0.6). Thereafter, the amount of the mTNF- $alpha$ presentin the supernatant decreased below the detection limit (3.1 Uml¹) after 12 h, whereas there was still biologically active mTNF- $alpha$ in lysates for up to 20 h. Both in lysate and supernatant, a maximumof ~10³ U of mTNF- $alpha$ activity ml¹ was found (Fig. 3B). Very similar time-related mTNF- $alpha$ activitymeasurements were obtained with the pKNT19eglATNF construct. Insupernatants and lysates of cultures without the plasmid or withthe plasmid not containing the mTNF- $alpha$ gene, no mTNF- $alpha$ activitywasdetected.

To test whether the decrease in activity was due to the action of proteases or due to the formation of acidic fermentationproducts from the recombinant clostridia, causing a pH decreasein the medium, MOPS (pH 7.2) was added to buffer the culture medium.This resulted in an elevated level of biologically active mTNF- $alpha$ (Fig. 3C) in both lysates and supernatants (measured within afollow-up period of 24 h). From these data, we can conclude thatthe higher amount of active mTNF- $alpha$ clearly corresponds with theslower decrease in pH in the buffered medium. This is completelyin accordance with the literature describing the stability ofTNF- $alpha$ within a pH region of 10 to 5.5 (36).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The present experiments were carried out in the context of a tumor-specific gene transfer system using apathogenic clostridia(11, 12). We assessed whether the eukaryotic mTNF- $alpha$ cDNA couldbe expressed in Clostridium and whether mTNF- $alpha$ could subsequentlybe secreted. The mTNF- $alpha$ production from the colonizing recombinantbacteria may lead to an improved in vivo antitumor response. Thiswould likely occur in the absence of systemic toxicity becauseof the selective intratumoral deposition of thecytokine.

Therefore, C. acetobutylicum DSM792 was genetically engineered to produce mTNF- $alpha$ . With these experiments, the presence ofbiologically active mTNF- $alpha$ in culture supernatants and cell lysatesof C. acetobutylicum DSM792(pIMP1eglATNF) and C. acetobutylicumDSM792(pKNT19eglATNF), containing the mTNF- $alpha$ cDNA fused to thesignal sequence of eglA and preceded by the eglA promoter, wasclearly demonstrated both by Western blotting with mTNF- $alpha$ antibodiesand in a bioassay using WEH164 clone 13 cells. Notwithstandingthat the mTNF- $alpha$ gene was preceded by a signal sequence originatingfrom Clostridium, not all of the mTNF- $alpha$ expressed was also secreted.Secretion efficiency might possibly be improved by using a differentsignal peptide or by modifying, e.g., the number of positive chargesin the signal peptide, as shown for other organisms (13).

Our experiments showed that the pIMP1 and pKNT19 derivatives were segregationally stable in C. acetobutylicum DSM792. Bothconstructs were structurally more stable than the construct withpMTL500E. It has been suggested that vectors based on the pAM $beta$ 1replicon such as pMTL500E would be structurally more stable andthus more suitable for general use in Clostridium (38). Thishypothesis relies on the absence of highly recombinogenic single-strandedDNA intermediates that would interfere with the structural stabilityof the plasmid. Our experiments, however, do not confirm thisgeneral hypothesis. Since other derivatives of pMTL500E have beenshown in vitro to be stably maintained in C. beijerinckii (4,17), these findings and our data considered together possiblyreflect a strain- and/or sequence-specific character of vectorstability.

Clostridium is characterized by a low G+C content with a strongly biased codon usage towards codons in which A and U predominate.However, since biologically active mTNF- $alpha$ was detected in ourexperiments, the low G+C content of the host organism (28 to 29mol%) seemingly has no implications for the expression of thecloned mTNF- $alpha$ gene, at least in the strain used. Moreover, functionalmTNF- $alpha$ was secreted. Secretion was possible because of the presenceof a clostridial signal sequence (39). To our knowledge, thisis the first report describing the secretion of a eukaryotic proteinfrom Clostridium.

Anaerobic bacteria selectively colonize the hypoxic-necrotic areas of solid tumors. This has been demonstrated with rodenttumor models (11, 19) and is documented for some cancer patients(10, 32). Since these hypoxic-necrotic regions are not presentin normal tissues, this transfer system is very tumor specific(12). As a consequence, it should be possible to increase thelocal concentration of therapeutic agents by using geneticallymodified anaerobic bacteria expressing and secreting these compounds.The antitumor effectiveness will obviously depend on the stabilityof the recombinant constructs and on the expression of the therapeuticgenes in an in vivo tumor system. In vivo results described byMinton et al., using the EMT6 mouse tumor model, indicated thedifficulty in obtaining sufficient amounts of therapeutic proteins(24). This might relate to the stability of the constructs and/orto the insufficient Clostridium colonization of the tumor. Usinganother tumor model and different therapeutic gene products, weaim to improve the therapeutic efficiency in vivo. Separately,the ameliorated tumor colonization of rat rhabdomyosarcomas usinga vascular targeting compound has recently been demonstrated inour laboratories (14).

The clinical usefulness of systemically administered mTNF- $alpha$ is limited due to hepatotoxicity and hypotension as major dose-limitingside effects (28, 30). The strategy introduced in the presentinvestigations aims to restrict the antitumor potential of thiscytokine solely in the tumor site, thereby bypassing the systemictoxicity.

TNF- $alpha$ has been shown to be cytotoxic towards many transformed cell lines in vitro (5, 33). Antitumor activity againsta variety of murine as well as human tumors has also been documentedwith in vivo investigations (1, 7, 34). Experiments arein progress to analyze in vivo the qualitative and quantitativeeffects of mTNF- $alpha$ expression in rodent tumormodels.

	ACKNOWLEDGMENTS

We appreciate the fruitful discussions with Elke Lammertyn on the presentresearch.

We acknowledge financial support from Het Fonds voor Wetenschappelijk Onderzoek-Vlaanderen, De Vlaamse Kankerliga, VerkennendeInternationale Samenwerking, Het K.U.Leuven Onderzoeksfonds, andSportvereniging tegen Kanker of Belgium. Jan Theys and SandraNuyts are research fellows of I.W.T. (Vlaams Instituut voor debevordering van het Wetenschappelijk-Technologisch onderzoek indeindustrie).

	FOOTNOTES

^* Corresponding author. Mailing address: Laboratory of Bacteriology, Rega Instituut, K. U. Leuven, Minderbroedersstraat 10,B-3000 Leuven, Belgium. Phone: 3216337371. Fax: 3216337340. E-mail:Jozef.Anne{at}rega.kuleuven.ac.be.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
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22. Mermelstein, L. D., and E. T. Papoutsakis. 1993. In vivo methylation in Escherichia coli by the Bacillus subtilis phage $phi$ 3T I methyltransferase to protect plasmids from restriction upon transformation of Clostridium acetobutylicum ATCC824. Appl. Environ. Microbiol. 59:1077-1081[Abstract/Free Full Text].

23. Minton, N. P., and J. D. Oultram. 1988. Host:vector systems for gene cloning in Clostridium. Microbiol. Sci. 5:310-315[Medline].

24. Minton, N. P., M. L. Mauchline, M. J. Lemmon, J. K. Brehm, M. Fox, N. P. Michael, A. Giaccia, and J. M. Brown. 1995. Chemotherapeutic tumor targeting using clostridial spores. FEMS Microbiol. Rev. 17:357-364[Medline].

25. Nakotte, S., S. Schaffer, M. Böhringer, and P. Dürre. 1998. Electroporation of plasmid isolation from and plasmid conservation in Clostridium acetobutylicum DSM792. Appl. Microbiol. Biotechnol. 50:564-567[Medline].

26. Oultram, J. D., M. Loughlin, T. J. Swinfield, J. K. Brehm, D. E. Thompson, and N. P. Minton. 1988. Introduction of plasmids into whole cells of Clostridium acetobutylicum by electroporation. FEMS Microbiol. Lett. 56:83-88.

27. Pawelek, J. M., K. B. Low, and D. Bermudes. 1997. Tumor-targeted Salmonella as a novel anticancer vector. Cancer Res. 57:4537-4544[Abstract/Free Full Text].

28. Raijinder, S. S., and A. P. Bollon. 1993. Tumor necrosis factor activities and cancer therapy $---$ a perspective. Pharmacol. Ther. 57:79-128[Medline].

29. Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

30. Schiller, J. H., B. E. Storer, P. L. Witt, D. Alberti, M. B. Tombes, R. Arzoomanian, R. A. Proctor, D. McCarthy, R. R. Brown, S. D. Voss, S. C. Remick, J. L. Grem, E. C. Borden, and D. L. Trump. 1991. Biological and clinical effects of intravenous tumor necrosis factor $alpha$ administered three times weekly. Cancer Res. 51:1651-1658[Abstract/Free Full Text].

31. Sersa, G., V. Willingham, and L. Milas. 1988. Anti-tumor effects of tumor necrosis factor alone or combined with radiotherapy. Int. J. Cancer 42:129-134[Medline].

32. Sjöstedt, J., L. Kager, A. Heimdahl, and C. E. Nord. 1988. Microbial colonization of tumors in relation to the upper gastrointestinal tract in patients with gastric carcinoma. Ann. Surg. 207:341-346[Medline].

33. Sugarman, B. J., B. B. Aggarwal, P. E. Hass, I. S. Figari, M. A. Palladino, and H. M. Shepard. 1985. Recombinant human tumor necrosis factor $alpha$ : effects on proliferation of normal and transformed cells in vitro. Science 230:943-948[Abstract/Free Full Text].

34. Teng, M. N., B. H. Park, H. K. W. Koeppen, K. J. Tracey, B. M. Fendly, and H. Schreiber. 1991. Long-term inhibition of tumor growth by tumor necrosis factor in the absence of cachexia or T-cell immunity. Proc. Natl. Acad. Sci. USA 88:3535-3539[Abstract/Free Full Text].

35. Van Mellaert, L., C. Dillen, P. Proost, E. Sablon, R. Deleys, A. Van Broekhoven, H. Heremans, J. Van Damme, H. Eyssen, and J. Anné. 1994. Efficient secretion of biologically active mouse tumor necrosis factor $alpha$ by Streptomyces lividans. Gene 150:153-158[Medline].

36. Van Ostade, X., J. Tavernier, and W. Fiers. 1994. Structure-activity studies of human tumor necrosis factors. Protein Eng. 7:5-22[Abstract/Free Full Text].

37. Wallace, R. B., M. J. Johnson, S. V. Suggs, K. Miyoshi, R. Bhatt, and K. Itakura. 1981. A set of synthetic oligodeoxyribonucleotide primers for DNA sequencing in the plasmid vector pBR322. Gene 16:21-26[Medline].

38. Young, M., N. P. Minton, and W. L. Staudenbauer. 1989. Recent advances in the genetics of the clostridia. FEMS Microbiol. Rev. 63:301-326.

39. Zappe, H., W. A. Jones, D. T. Jones, and D. R. Woods. 1988. Structure of an endo- $beta$ -1,4-glucanase gene from Clostridium acetobutylicum P262 showing homology with endoglucanase genes from Bacillus spp. Appl. Environ. Microbiol. 54:1289-1292[Abstract/Free Full Text].

40. Zheng, L. X., G. Fisher, R. E. Miller, J. Peschon, D. H. Lynch, and M. J. Lenardo. 1995. Induction of apoptosis in mature T cells by tumour necrosis factor. Nature 377:348-351[Medline].

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23.	Minton, N. P., and J. D. Oultram. 1988. Host:vector systems for gene cloning in Clostridium. Microbiol. Sci. 5:310-315[Medline].
24.	Minton, N. P., M. L. Mauchline, M. J. Lemmon, J. K. Brehm, M. Fox, N. P. Michael, A. Giaccia, and J. M. Brown. 1995. Chemotherapeutic tumor targeting using clostridial spores. FEMS Microbiol. Rev. 17:357-364[Medline].
25.	Nakotte, S., S. Schaffer, M. Böhringer, and P. Dürre. 1998. Electroporation of plasmid isolation from and plasmid conservation in Clostridium acetobutylicum DSM792. Appl. Microbiol. Biotechnol. 50:564-567[Medline].
26.	Oultram, J. D., M. Loughlin, T. J. Swinfield, J. K. Brehm, D. E. Thompson, and N. P. Minton. 1988. Introduction of plasmids into whole cells of Clostridium acetobutylicum by electroporation. FEMS Microbiol. Lett. 56:83-88.
27.	Pawelek, J. M., K. B. Low, and D. Bermudes. 1997. Tumor-targeted Salmonella as a novel anticancer vector. Cancer Res. 57:4537-4544[Abstract/Free Full Text].
28.	Raijinder, S. S., and A. P. Bollon. 1993. Tumor necrosis factor activities and cancer therapy $---$ a perspective. Pharmacol. Ther. 57:79-128[Medline].
29.	Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
30.	Schiller, J. H., B. E. Storer, P. L. Witt, D. Alberti, M. B. Tombes, R. Arzoomanian, R. A. Proctor, D. McCarthy, R. R. Brown, S. D. Voss, S. C. Remick, J. L. Grem, E. C. Borden, and D. L. Trump. 1991. Biological and clinical effects of intravenous tumor necrosis factor $alpha$ administered three times weekly. Cancer Res. 51:1651-1658[Abstract/Free Full Text].
31.	Sersa, G., V. Willingham, and L. Milas. 1988. Anti-tumor effects of tumor necrosis factor alone or combined with radiotherapy. Int. J. Cancer 42:129-134[Medline].
32.	Sjöstedt, J., L. Kager, A. Heimdahl, and C. E. Nord. 1988. Microbial colonization of tumors in relation to the upper gastrointestinal tract in patients with gastric carcinoma. Ann. Surg. 207:341-346[Medline].
33.	Sugarman, B. J., B. B. Aggarwal, P. E. Hass, I. S. Figari, M. A. Palladino, and H. M. Shepard. 1985. Recombinant human tumor necrosis factor $alpha$ : effects on proliferation of normal and transformed cells in vitro. Science 230:943-948[Abstract/Free Full Text].
34.	Teng, M. N., B. H. Park, H. K. W. Koeppen, K. J. Tracey, B. M. Fendly, and H. Schreiber. 1991. Long-term inhibition of tumor growth by tumor necrosis factor in the absence of cachexia or T-cell immunity. Proc. Natl. Acad. Sci. USA 88:3535-3539[Abstract/Free Full Text].
35.	Van Mellaert, L., C. Dillen, P. Proost, E. Sablon, R. Deleys, A. Van Broekhoven, H. Heremans, J. Van Damme, H. Eyssen, and J. Anné. 1994. Efficient secretion of biologically active mouse tumor necrosis factor $alpha$ by Streptomyces lividans. Gene 150:153-158[Medline].
36.	Van Ostade, X., J. Tavernier, and W. Fiers. 1994. Structure-activity studies of human tumor necrosis factors. Protein Eng. 7:5-22[Abstract/Free Full Text].
37.	Wallace, R. B., M. J. Johnson, S. V. Suggs, K. Miyoshi, R. Bhatt, and K. Itakura. 1981. A set of synthetic oligodeoxyribonucleotide primers for DNA sequencing in the plasmid vector pBR322. Gene 16:21-26[Medline].
38.	Young, M., N. P. Minton, and W. L. Staudenbauer. 1989. Recent advances in the genetics of the clostridia. FEMS Microbiol. Rev. 63:301-326.
39.	Zappe, H., W. A. Jones, D. T. Jones, and D. R. Woods. 1988. Structure of an endo- $beta$ -1,4-glucanase gene from Clostridium acetobutylicum P262 showing homology with endoglucanase genes from Bacillus spp. Appl. Environ. Microbiol. 54:1289-1292[Abstract/Free Full Text].
40.	Zheng, L. X., G. Fisher, R. E. Miller, J. Peschon, D. H. Lynch, and M. J. Lenardo. 1995. Induction of apoptosis in mature T cells by tumour necrosis factor. Nature 377:348-351[Medline].