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Development of a Novel Chloramphenicol Resistance Expression Plasmid Used for Genetic Complementation of a fliG Deletion Mutant in Treponema denticola

Linda L. Slivienski-Gebhardt, Jacques Izard, William A. Samsonoff, and Ronald J. Limberger^*

David Axelrod Institute for Public Health, Wadsworth Center, New York State, Department of Health, Albany, New York

Received 2 April 2004/ Returned for modification 4 May 2004/ Accepted 9 June 2004

	ABSTRACT

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A new expression plasmid containing the fla operon promoter and a staphylococcal chloramphenicol resistance gene, was constructed to help assess the role of fliG in Treponema denticola motility. Deletion of fliG resulted in a nonmotile mutant with a markedly decreased number of flagellar filaments. Wild-type fliG genes from T. denticola and from Treponema pallidum were cloned into this expression plasmid. In both cases, the gene restored the ability of the mutant to gyrate its cell ends and enabled colony spreading in agarose. This shuttle plasmid enables high-level expression of genes in T. denticola and possesses an efficient selectable marker that provides a new tool for treponemal genetics.

	TEXT

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Treponema denticola is an anaerobic, motile spirochete bacterium that is associated with periodontal disease (21, 29). T. denticola possesses four flagellar filaments, two of which are inserted at each end of the cell (2, 7). These complex filaments are composed of three FlaB core proteins and one FlaA sheath protein (26). Their unique periplasmic location allows the spirochete to locomote in high-viscosity environments, which is an important factor in pathogenesis (1, 12-14, 16, 27, 30).

Research on T. denticola has been hampered by a paucity of genetic tools and efficient selectable markers. An erythromycin resistance cassette has been used to generate a number of insertional mutants of T. denticola (15). More recently, a coumermycin-based shuttle plasmid was developed for complementation analysis (4). However, coumermycin-based selection suffers from a high background level of spontaneously resistant cells. Thus, there is a need to develop additional selectable markers for use in creating T. denticola shuttle plasmids that can be used for expression and complementation studies. Development of an efficient expression plasmid would enable the use of T. denticola as a surrogate system (3) to study homologous genes from Treponema pallidum, a pathogenic spirochete that is not cultivable in cell-free medium.

A motility-related operon in T. denticola is transcribed from a sigma 28-like promoter and encodes seven polypeptides that are homologous with components of the Salmonella flagellar basal body (FlgB, FlgC, FliE, FliF, and FliG), as well as three putative flagellar export proteins (FliH, FliI, and FliJ) (5, 6, 22-24). T. denticola FliG has a 31% amino acid sequence identity with Salmonella enterica serovar Typhimurium FliG, which is part of the flagellar switch complex (10, 22, 23, 32). In S. enterica serovar Typhimurium, FliG is involved in torque generation, directional rotation of the flagellar filament (8, 19, 20), and flagellar filament structure (8, 11). The role of fliG in T. denticola is unknown. Because the organization and regulation of spirochete motility genes are different from those of enteric bacteria, analysis of T. denticola fliG will enable us to gain a better understanding of the role of this protein in spirochete motility.

Strains and media. T. denticola ATCC 33520 was grown at 36°C in New Oral Spirochete (NOS) broth with 10% rabbit serum or was plated on NOS medium containing 0.5% agarose (9, 18).

Construction and analysis of a fliG deletion mutant. A suicide plasmid, pFEH1, was constructed (Fig. 1A) and was electroporated into T. denticola, using 5 to 10 µg of DNA as previously described (18). Plating was done on NOS-0.5% agarose plates containing 100-µg/ml erythromycin to select for double-crossover recombinants (18). After 1 week of incubation, small dense colonies grew on the surface of NOS-agarose plates. After growth in liquid medium, cells of this fliG deletion mutant, TDWFLIG, showed no movement when observed by dark-field microscopy.

View larger version (29K): [in this window] [in a new window]   FIG. 1. Plasmid constructions. (A) A suicide plasmid vector for generating a fliG deletion in T. denticola by allelic exchange. (B) A new expression plasmid, pBFC, that replicates and confers chloramphenicol resistance in T. denticola. This shuttle vector was used for cloning of T. denticola fliG as indicated for complementation analysis. NS, NsiI; P, PstI; M, MluI; K, KpnI; Sp, SpeI; S, SacI; N, NotI; A, ApaI; E, EcoRI; oriT.d., T. denticola origin of replication.

View this table: [in this window] [in a new window]   TABLE 1. Motility-related characteristics of wild-type T. denticola, TDWFLIG, and TDWFLIG harboring fliG on a newly constructed plasmid

Quantitation of RNA expression in TDWFLIG by RT-PCR.

Primers specific for flgB, flgC, fliH, and fliI (Table 2) were designed with the Primer Express software (Applied Biosystems, Foster City, Calif.). For reverse transcription-PCR (RT-PCR), 90 ng of RNA was used in an RT-PCR according to the manufacturer's instructions (Applied Biosystems). T. denticola 16S rRNA was used as a reference target for quantitation (see Table 2 for primer sequences).

View larger version (15K): [in this window] [in a new window]   FIG. 2. Quantitative RT-PCR analysis of gene expression of wild-type T. denticola and TDWFLIG. The y-axis scale indicates the relative quantity of RNA, as compared to a 16S rRNA standard. The x axis indicates the genes comprising the noncontiguous operons, with the direction of transcription as indicated by the horizontal arrows. Light gray bars are the T. denticola wild type, dark gray bars are TDWFLIG, and the striped bar indicates the expression of fliG from TDWFLIG harboring the plasmid pBFCFliG. The open triangle represents where the erythromycin resistance cassette is inserted in TDWFLIG and indicates that no fliG RNA was detected. The error bars for each gene represent 1 standard deviation derived from at least two independent assays.

View larger version (48K): [in this window] [in a new window]   FIG. 3. Immunoblot with FlaB antiserum. The three FlaB polypeptides migrated as a single band under these gel running conditions. Lanes: 1, T. denticola wild type; 2, TDWFLIG; 3, TDWFLIG containing pBFCFliG. Note that the expression of flagellar filament polypeptides in TDWFLIG was only 17% that of the wild type.

Construction of a newly derived expression plasmid that confers chloramphenicol resistance in T. denticola. The T. denticola replicative shuttle plasmid pKMR4PEMCS (3) was used as the basis for construction of a newly derived selectable plasmid (Fig. 1B). The new plasmid, pBFC, contained the T. denticola fla operon promoter (P_fla), located upstream of FliK/TapI (18), followed by the Staphylococcus aureus chloramphenicol resistance gene. The plasmid was electroporated into wild-type T. denticola and was selected on 10-µg/ml chloramphenicol.

The MIC of chloramphenicol for wild-type T. denticola is <1.0 µg/ml. T. denticola cells harboring pBFC grew well in 1.0 µg of chloramphenicol per ml, although they could grow in higher concentrations of this drug (up to 10 µg/ml). However, the growth rate slowed, and viability was reduced at the higher concentrations of chloramphenicol. For selection of transformants, 10 µg/ml was used in plated media to suppress background growth. The pBFC expression plasmid could be transformed and maintained in Escherichia coli, using kanamycin as a selectable marker, but it did not confer chloramphenicol resistance in E. coli.

The expression plasmid pBFC provides an important new tool for analysis of gene expression in T. denticola mutants. Use of chloramphenicol with this newly derived plasmid provides a method by which to obtain successfully transformed T. denticola cells with minimal or no background growth. It is likely, although not yet demonstrated, that this cat cassette will also be useful for generating chromosome-based gene interruptions.

Complementation analysis using fliG from T. denticola and T. pallidum. T. denticola fliG was cloned into pBFC to form pBFCFliG (Fig. 1B). Quantitative RT-PCR demonstrated that the amount of fliG RNA expressed from this plasmid was greater than the amount of wild-type fliG RNA expressed from the chromosomal location (Fig. 2). The higher expression levels of fliG RNA are likely the result of the plasmid-borne location of the promoter (L. Slivienski-Gebhardt and R. Limberger, unpublished observations), but they do not adversely affect cell growth or morphology.

Flagellated cells of TDWFLIG harboring the plasmid pBFCFliG regained the ability to gyrate their cell ends in broth cultures, and the mean flagellar filament lengths were restored to the wild-type level. Cells also regained the ability to form spreading colonies on agarose plates, although colony diameters were less than wild type. The number of flagellar filament structures and the amount of FlaB polypeptides were slightly increased, although not to wild-type levels (Fig. 3 and Table 1). Conceivably, the synthesis and assembly of flagellar structures require expression of fliG at the lower wild-type levels, so as to ensure proper molecular stoichiometry. In B. burgdorferi, complementation of an flaB null mutant was achieved only after integration of flaB into the chromosome (28). Unfortunately, it is not yet technically feasible to insert fliG back into the T. denticola chromosome in order to attempt complementation from a chromosomal location.

T. pallidum fliG, cloned and expressed in pBFC, was also able to restore gyration of the cell ends of TDWFLIG, as well as colony spreading in agarose. This is the first report of a successful complementation of a T. denticola mutant by using a T. pallidum gene. T. pallidum FliG shows an 84% amino acid sequence identity with T. denticola and a 90% similarity. These experiments demonstrate the potential utility of T. denticola as a surrogate system in which to analyze the function of T. pallidum polypeptides.

Future development and application of additional genetic tools will be critical in resolving the mechanisms involved in the expression, regulation, and function of spirochete motility genes.

Nucleotide sequence accession number. The entire sequence of fliG and partial sequences of fliF and fliH from T. denticola 33520 have been deposited in GenBank under accession no. AF343975.

	ACKNOWLEDGMENTS

 
We acknowledge Mary Beth Kinoshita, Dustin Vale-Cruz, and the Wadsworth Center Molecular Genetics and Electron Microscopy Core Facilities and Photography and Illustrations Unit for technical assistance. T. pallidum cells were kindly provided by K. Wicher (Wadsworth Center), and the FlaB antiserum was kindly provided by Nyles Charon, West Virginia University, Morgantown. Preliminary sequence data for T. denticola 35405 were obtained from The Institute for Genomic Research website (http://www.tigr.org) and the Baylor College of Medicine Human Genome Sequencing Center T. denticola sequencing project website (http://hgsc.bcm.tmc.edu/microbial/Tdenticola/), with support from NIH-NIDCR, and the Treponema Molecular Genetics website (http://dpalm.med.uth.tmc.edu/treponema/tpall.html).

This work was supported by Public Health Research Service grant AI34354 from the National Institutes of Health.

	FOOTNOTES

 
* Corresponding author. Mailing address: David Axelrod Institute for Public Health, Wadsworth Center, New York State, Department of Health, P.O. Box 22002, Albany, NY 12201-2002. Phone: (518) 474-4177. Fax: (518) 486-7971. E-mail: Ron.Limberger{at}wadsworth.org.

Editor: J. T. Barbieri

Present address: The Forsyth Institute, Boston, MA 02115.

	REFERENCES

Top Abstract Text References

 

1.	Charon, N. W., and S. F. Goldstein. 2002. Genetics of motility and chemotaxis of a fascinating group of bacteria: the spirochetes. Annu. Rev. Genet. 36:47-73.[CrossRef][Medline]
2.	Charon, N. W., S. F. Goldstein, S. M. Block, K. Curci, J. D. Ruby, J. A. Kreiling, and R. J. Limberger. 1992. Morphology and dynamics of protruding spirochete periplasmic flagella. J. Bacteriol. 174:832-840.[Abstract/Free Full Text]
3.	Chi, B., S. Chauhan, and H. Kuramitsu. 1999. Development of a system for expressing heterologous genes in the oral spirochete Treponema denticola and its use in expression of the Treponema pallidum flaA gene. Infect. Immun. 67:3653-3656.[Abstract/Free Full Text]
4.	Chi, B., R. J. Limberger, and H. K. Kuramitsu. 2002. Complementation of a Treponema denticola flgE mutant with a novel coumermycin A1-resistant T. denticola shuttle vector system. Infect. Immun. 70:2233-2237.[Abstract/Free Full Text]
5.	Heinzerling, H. F., M. Olivares, and R. A. Burne. 1997. Genetic and transcriptional analysis of flgB flagellar operon constituents in the oral spirochete Treponema denticola and their heterologous expression in enteric bacteria. Infect. Immun. 65:2041-2051.[Abstract]
6.	Heinzerling, H. F., J. E. Penders, and R. A. Burne. 1995. Identification of a fliG homologue in Treponema denticola. Gene 161:69-73.[CrossRef][Medline]
7.	Holt, S. C. 1978. Anatomy and chemistry of spirochetes. Microbiol. Rev. 42:114-160.[Free Full Text]
8.	Irikura, V. M., M. Kihara, S. Yamaguchi, H. Sockett, and R. M. Macnab. 1993. Salmonella typhimurium fliG and fliN mutations causing defects in assembly, rotation, and switching of the flagellar motor. J. Bacteriol. 175:802-810.[Abstract/Free Full Text]
9.	Izard, J., W. A. Samsonoff, M. B. Kinoshita, and R. J. Limberger. 1999. Genetic and structural analyses of the cytoplasmic filaments of wild-type Treponema phagedenis and a flagellar filament-deficient mutant. J. Bacteriol. 181:6739-6746.[Abstract/Free Full Text]
10.	Kihara, M., M. Homma, K. Kutsukake, and R. M. Macnab. 1989. Flagellar switch of Salmonella typhimurium: gene sequences and deduced protein sequences. J. Bacteriol. 171:3247-3257.[Abstract/Free Full Text]
11.	Kihara, M., G. U. Miller, and R. M. Macnab. 2000. Deletion analysis of the flagellar switch protein FliG of Salmonella. J. Bacteriol. 182:3022-3028.[Abstract/Free Full Text]
12.	Kimsey, R. B., and A. Spielman. 1990. Motility of Lyme disease spirochetes in fluids as viscous as the extracellular matrix. J. Infect. Dis. 162:1205-1208.[Medline]
13.	Klitorinos, A., P. Noble, R. Siboo, and E. C. Chan. 1993. Viscosity-dependent locomotion of oral spirochetes. Oral Microbiol. Immunol. 8:242-244.[Medline]
14.	Li, C., A. Motaleb, M. Sal, S. F. Goldstein, and N. W. Charon. 2000. Spirochete periplasmic flagella and motility. J. Mol. Microbiol. Biotechnol. 2:345-354.[Medline]
15.	Li, H., J. Ruby, N. Charon, and H. Kuramitsu. 1996. Gene inactivation in the oral spirochete Treponema denticola: construction of an flgE mutant. J. Bacteriol. 178:3664-3667.[Abstract/Free Full Text]
16.	Limberger, R. J. 2004. The periplasmic flagellum of spirochetes. J. Mol. Microbiol. Biotechnol. 7:30-40.[CrossRef][Medline]
17.	Limberger, R. J., and N. W. Charon. 1986. Antiserum to the 33,000-dalton periplasmic-flagellum protein of "Treponema phagedenis" reacts with other treponemes and Spirochaeta aurantia. J. Bacteriol. 168:1030-1032.[Abstract/Free Full Text]
18.	Limberger, R. J., L. L. Slivienski, J. Izard, and W. A. Samsonoff. 1999. Insertional inactivation of Treponema denticola tap1 results in a nonmotile mutant with elongated flagellar hooks. J. Bacteriol. 181:3743-3750.[Abstract/Free Full Text]
19.	Lloyd, S. A., H. Tang, X. Wang, S. Billings, and D. F. Blair. 1996. Torque generation in the flagellar motor of Escherichia coli: evidence of a direct role for FliG but not for FliM or FliN. J. Bacteriol. 178:223-231.[Abstract/Free Full Text]
20.	Lloyd, S. A., F. G. Whitby, D. F. Blair, and C. P. Hill. 1999. Structure of the C-terminal domain of FliG, a component of the rotor in the bacterial flagellar motor. Nature 400:472-475.[CrossRef][Medline]
21.	Loesche, W. J. 1988. The role of spirochetes in periodontal disease. Adv. Dent. Res. 2:275-283.[Abstract]
22.	Macnab, R. M. 1992. Genetics and biogenesis of bacterial flagella. Annu. Rev. Genet. 26:131-158.[CrossRef][Medline]
23.	Macnab, R. M. 2003. How bacteria assemble flagella. Annu. Rev. Microbiol. 57:77-100.[CrossRef][Medline]
24.	Minamino, T., R. Chu, S. Yamaguchi, and R. M. Macnab. 2000. Role of FliJ in flagellar protein export in Salmonella. J. Bacteriol. 182:4207-4215.[Abstract/Free Full Text]
25.	Motaleb, M. A., M. Sal, and N. Charon. 2004. The decrease in FlaA observed in a flaB mutant of Borrelia burgdorferi occurs posttranscriptionally. J. Bacteriol. 186:3703-3711.[Abstract/Free Full Text]
26.	Ruby, J. D., H. Li, H. Kuramitsu, S. J. Norris, S. F. Goldstein, K. F. Buttle, and N. W. Charon. 1997. Relationship of Treponema denticola periplasmic flagella to irregular cell morphology. J. Bacteriol. 179:1628-1635.[Abstract/Free Full Text]
27.	Sadziene, A., D. D. Thomas, V. G. Bundoc, S. C. Holt, and A. G. Barbour. 1991. A flagella-less mutant of Borrelia burgdorferi: structural, molecular and in vitro functional characterization. J. Clin. Investig. 88:82-92.
28.	Sartakova, M. L., E. Y. Dobrikova, M. A. Motaleb, H. P. Godfrey, N. W. Charon, and F. C. Cabello. 2001. Complementation of a nonmotile flaB mutant of Borrelia burgdorferi by chromosomal integration of a plasmid containing a wild-type flaB allele. J. Bacteriol. 183:6558-6564.[Abstract/Free Full Text]
29.	Simonson, L. G., C. H. Goodman, J. J. Bial, and H. E. Morton. 1988. Quantitative relationship of Treponema denticola to severity of periodontal disease. Infect. Immun. 56:726-728.[Abstract/Free Full Text]
30.	Thomas, D. D., M. Navab, D. A. Haake, A. M. Fogelman, J. N. Miller, and M. A. Lovett. 1988. Treponema pallidum invades intracellular junctions of endothelial cell monolayers. Proc. Natl. Acad. Sci. USA 8:3608-3612.
31.	Wang, G., C. Barton, and F. G. Rodgers. 2002. Bacterial DNA decontamination for reverse transcription polymerase chain reaction (RT-PCR). J. Microbiol. Methods 51:119-121.[CrossRef][Medline]
32.	Yamaguchi, S., S.-I. Aizawa, M. Kihara, M. Isomura, C. J. Jones, and R. M. Macnab. 1986. Genetic evidence for a switching and energy-transducing complex in the flagellar motor of Salmonella typhimurium. J. Bacteriol. 168:1172-1179.[Abstract/Free Full Text]

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