Development of novel plasmid vectors and a promoter trap system in Francisella tularensis compatible with the pFLN10 based plasmids

Francisella tularensis is a category A bioterror pathogen which in some cases can cause a severe and fatal human infection. Very few virulence factors are known in this species due to the difficulty in working with it as well as the lack of tools for genetic manipulation. This work describes the construction of a shuttle vector that can replicate in Escherichia coli and F. tularensis as well as two distinct promoter trap constructs based on the shuttle vector backbone. Replication in F. tularensis is based on the promiscuous origin of replication from the Staphylococcus aureus plasmid pC194. We demonstrate the novel plasmids can coexist with established F. tularensis vectors based on the pFNL10 plasmid, the current workhorse of F. tularensis genetics. Our promoter trap can identify promoters that are activated during intracellular growth and survival. These new vectors provide additional tools for the genetic manipulation of F. tularensis.     

Cryptic plasmid pFNL10 from Francisella novicida-like F6168: The base of plasmid vectors for Francisella tularensis

Abstract The plasmid pFNL100 was created by ligation of Escherichia coli plasmid pBR328 and plasmid pFNL10 from Francisella novicida -like strain F6168. This plasmid was able to replicate and to express the genes for chloramphenicol and tetracycline resistance in both E. coli and F. tularensis . The origin of replication of pFNL10, needed for the replication of pFNL100 in F. tularensis , was mapped. A Sau 3A-deletion derivative of pFNL100, designated pFNL200, was constructed. This plasmid could replicate only in F. tularensis and was found to be stably inherited during cultivation both on solid medium and in liquid cultures.     

Construction of a shuttle vector for use in Francisella tularensis

Abstract The characterisation of virulence factors of Francisella tularensis has been hampered by the lack of genetic system for the bacterium. In this study, a shuttle vector was constructed that can replicate autonomously in F. tularensis and Escherichia coli . To obtain this vector, the p15A replication origin of E. coli plasmid pACYC184 was introduced into a plasmid derivative of plasmid pFNL200, a plasmid which only can replicate in F. tularensis . The resulting shuttle vector, designated pKK202, harboured resistance genes for chloramphenicol and tetracycline. This vector might be used as a basis for the studies of virulence factors of F. tularensis .     

Construction and characterization of a highly efficient Francisella shuttle plasmid

Francisella tularensis is a facultative intracellular pathogen that infects a wide variety of mammals and causes tularemia in humans. It is recognized as a potential agent of bioterrorism due to its low infectious dose and multiple routes of transmission. To date, genetic manipulation in Francisella spp. has been limited due to the inefficiency of DNA transformation, the relative lack of useful selective markers, and the lack of stably replicating plasmids. Therefore, the goal of this study was to develop an enhanced shuttle plasmid that could be utilized for a variety of genetic procedures in both Francisella and Escherichia coli. A hybrid plasmid, pFNLTP1, was isolated that was transformed by electroporation at frequencies of >1 x 10(7) CFU mug of DNA(-1) in F. tularensis LVS, Francisella novicida U112, and E. coli DH5alpha. Furthermore, this plasmid was stably maintained in F. tularensis LVS after passage in the absence of antibiotic selection in vitro and after 3 days of growth in J774A.1 macrophages. Importantly, F. tularensis LVS derivatives carrying pFNLTP1 were unaltered in their growth characteristics in laboratory medium and macrophages compared to wild-type LVS. We also constructed derivatives of pFNLTP1 containing expanded multiple cloning sites or temperature-sensitive mutations that failed to allow plasmid replication in F. tularensis LVS at the nonpermissive temperature. In addition, the utility of pFNLTP1 as a vehicle for gene expression, as well as complementation, was demonstrated. In summary, we describe construction of a Francisella shuttle plasmid that is transformed at high efficiency, is stably maintained, and does not alter the growth of Francisella in macrophages. This new tool should significantly enhance genetic manipulation and characterization of F. tularensis and other Francisella biotypes.     

Nucleotide sequence, structural organization, and functional characterization of the small recombinant plasmid pOM1 that is specific for Francisella tularensis

pOM1 is a recombinant 4442-bp plasmid that includes the replicon of the Francisella novicida-like strain F6168 cryptic plasmid pFNL10 and the tetracycline resistance gene (tetC) of plasmid pBR328. pOM1 can stably replicate and is maintained in Francisella tularensis biovars tularensis, palaearctica, and palaearctica var. japonica. The replicon of pOM1 includes the ori region and the repA gene. The ori region, located upstream of the repA gene includes two sets of 31- and 13-bp direct repeats (DR), with AT-rich regions preceding each of the DRs. Two putative promoters of the repA gene were found connected with the DR regions. A 40-kDa protein was encoded by the repA gene and found essential for replication. Expression of the tetC gene is regulated by an Escherichia coli sigma(70)-like promoter and is dependent on the F. tularensis strain and its environment.     

Description of two new plasmids isolated from Francisella philomiragia strains and construction of shuttle vectors for the study of Francisella tularensis

Francisella tularensis is the causative agent of tularemia, a zoonotic disease often transmitted to humans by infected animals. The lack of useful specific genetic tools has long hampered the study of F. tularensis subspecies. We identified and characterized two new plasmids, pF242 and pF243, isolated from Francisella philomiragia strains ATCC 25016 and ATCC 25017, respectively. Sequence analysis revealed that pF242 and pF243 are closely related to pC194 and pFNL10 plasmids, respectively. Two generations of pF242- and pF243-based shuttle vectors, harboring several antibiotic resistance markers, were developed. We used the first generation to compare transformation efficiencies in two virulent F. tularensis subspecies. We found that electroporation was more efficient than cryotransformation: almost all vectors tested were successfully introduced by electroporation into Francisella strains with a high level of efficiency. The second generation of shuttle vectors, containing a multiple cloning site and/or gfp gene downstream of Francisella groES promotor, was used for GFP production in F. tularensis. The development of new shuttle vectors offers new perspectives in the genetic manipulation of F. tularensis, helping to elucidate the mechanisms underlying its virulence.     

Genetic elements for selection, deletion mutagenesis and complementation in Francisella spp

Francisella novicida is a gram-negative pathogen that can induce disease in mice that mimics human tularemia, and is nearly identical to Francisella tularensis at the genomic level. In this work a number of antibiotic marker cassettes that incorporate a strong F. novicida promoter is constructed, which greatly enhances selection in F. novicida and F. tularensis. Two low-copy plasmid vectors based on a broad-host-range plasmid, and an integrating vector have also been made, and these can be used for genetic complementation. Two general approaches to deletion mutagenesis in F. novicida is also described.     

Transformation and allelic replacement in Francisella spp.

We describe methods for transposon mutagenesis and allelic replacement in the facultative intracellular pathogen Francisella. Recombinant clones were constructed by insertion of partially cut F. tularensis or F. novicida DNA into pUC19 and then mutagenized with a mini-Tn10-Km transposon. F. novicida could be transformed with these plasmids either by a chemical transformation method or by electroporation, whereas F. tularensis could be transformed only by electroporation. Transformation of F. tularensis by electroporation was enhanced in the absence of the capsule. Southern blot analysis showed that the KmR marker was rescued either by integration of the plasmid into the Francisella chromosome or by allelic replacement. Allelic replacement was found to be the mechanism underlying a site-specific mutation affecting FopA, an outer-membrane protein of Francisella. F. novicida could also be transformed with chromosomal DNA carrying the KmR marker and the transformation frequency obtained using chromosomal DNA was generally greater than that obtained using plasmid DNA. F. novicida was also transformed by an IncQ plasmid containing an F. novicida DNA insert, which replicated autonomously in this host.     

Construction of a reporter plasmid for screening in vivo promoter activity in Francisella tularensis

Francisella tularensis is a facultative intracellular bacterium that survives and multiplies inside macrophages. Here we constructed a new promoter probe plasmid denoted pKK214 by introduction of a promoter-less chloramphenicol acetyltransferase (cat) gene into the shuttle vector pKK202. A promoter library was created in F. tularensis strain LVS by cloning random chromosomal DNA fragments into pKK214. Approximately 15% of the recombinant bacteria showed chloramphenicol resistance in vitro. The promoter library was also used to infect macrophages in the presence of chloramphenicol and after two cycles of infection the library contained essentially only chloramphenicol resistance clones which shows that pKK214 can be used to monitor F. tularensis genes that are expressed during infection.     

Cloning and expression of protective antigens of <Emphasis Type="Italic">Mycobacterium tuberculosis</Emphasis> Ag85B and ESAT-6 in <Emphasis Type="Italic">Francisella tularensis</Emphasis> 15/10

The possibility of expression of genes encoding mycobacterial antigens in Francisella tularensis 15/10 vaccine strain cells has been shown for the first time. To obtain stable and effective expression of mycobacterial antigens in the F. tularensis cells, the plasmid vector pPMC1 and hybrid genes consisting of the leader part FL of the F. tularensis membrane protein FopA and structural moieties of the mature protein Ag85B or the fused protein Ag85B-ESAT-6 were constructed. Recombinant strains F. tularensis RVp17 and RVp18 expressing protective mycobacterial antigens in the fused proteins FL-Ag85B and FL-Ag85B-ESAT-6, respectively, were obtained. Expression of the protective mycobacterial antigens in F. tularensis was analyzed using specific antisera to the recombinant proteins Ag85-(His)6 and ESAT-6-(His)6 isolated from Escherichia coli producer strains created on the basis of the pET23b(+) and pET24b(+) vectors. The expression of heterologous protective antigens in F. tularensis 15/10 is promising for creation of live recombinant anti-tuberculosis vaccines on the basis of the tularemia vaccine strain.     

Transfer of bacteriophage PRD1 genes into modified plasmid Sa of Escherichia coli and Francisella tularensis cells]

The donor specific bacteriophage PRDI has been shown to mediate the genes transfer into Escherichia coli and Francisella tularensis cell under certain conditions. It is necessary for the process that the recipient cells inherit the plasmids determining absorbtion of bacteriophages on the cellular surface while the transferred genes are able to be expressed. The frequencies of the tet-gene transfer from the plasmid pSKFT5 into Escherichia coli and Francisella tularensis 15 cells inheriting the plasmid Sa are, correspondingly, 10(-6) and 10(-7) clones per bacteriophage plaque.     

Deletion of IglH in virulent Francisella tularensis subsp. holarctica FSC200 strain results in attenuation and provides protection against the challenge with the parental strain

Francisella tularensis, the causative agent of tularemia, is a highly infectious intracellular pathogen with no licensed vaccine available today. The recent search for genome sequences involved in F. tularensis virulence mechanisms led to the identification of the 30-kb region defined as a Francisella pathogenicity island (FPI). In our previous iTRAQ study we described the concerted upregulation of some FPI proteins in different F. tularensis strains cultivated under stress conditions. Among them we identified the IglH protein whose role in Francisella virulence has not been characterized yet. In this work we deleted the iglH gene in a European clinical isolate of F. tularensis subsp. holarctica FSC200. We showed that the iglH gene is necessary for intracellular growth and escape of F. tularensis from phagosomes. We also showed that the iglH mutant is avirulent in a mouse model of infection and persists in the organs for about three weeks after infection. Importantly, mice vaccinated by infection with the iglH mutant were protected against subcutaneous challenge with the fully virulent parental FSC200 strain. This is the first report of a defined subsp. holarctica FPI deletion strain that provides protective immunity against subsequent subcutaneous challenge with a virulent isolate of F. tularensis subsp. holarctica.     

PCR和Southern Blot检测土拉弗氏菌气溶胶

为提高检测土拉弗氏菌的特异性和敏感性,建立了土拉菌ＰＣＲ及核酸杂交检测方法。运用平板计数、多聚酶链反应对土拉菌气溶胶稳定性进行了比较,结果表明ＰＣＲ具有较高灵敏度,并且在采样后３小时ＰＣＲ就可以得出定性结果,而平板计数则需要３～７天。采用ＰＣＲ法合成了土拉菌３７６－ｂｐ探针,分别对细菌菌液、５６８－ｂｐＰＣＲ产物和气溶胶样品进行杂交,结果表明菌悬液直接杂交可检出１０５ＣＦＵ左右的细菌,检测ＰＣＲ产物可达４０ｐｇ。ＰＣＲ和Ｓｏｕｔｈｅｒｎ印迹相结合有利于细菌的分离鉴定     

Genome characterisation of the genus Francisella reveals insight into similar evolutionary paths in pathogens of mammals and fish

ABSTRACT: BACKGROUND: Prior to this study, relatively few strains of Francisella had been genome-sequenced. Previously published Francisella genome sequences were largely restricted to the zoonotic agent F. tularensis. Only limited data were available for other members of the Francisella genus, including F. philomiragia, an opportunistic pathogen of humans, F. noatunensis, a serious pathogen of farmed fish, and other less well described endosymbiotic species. RESULTS: We determined the phylogenetic relationships of all known Francisella species, including some for which the phylogenetic positions were previously uncertain. The genus Francisella could be divided into two main genetic clades: one included F. tularensis, F. novicida, F. hispaniensis and Wolbachia persica, and another included F. philomiragia and F. noatunensis. Some Francisella species were found to have significant recombination frequencies. However, the fish pathogen F. noatunensis subsp. noatunensis was an exception due to it exhibiting a highly clonal population structure similar to the human pathogen F. tularensis. CONCLUSIONS: The genus Francisella can be divided into two main genetic clades occupying both terrestrial and marine habitats. However, our analyses suggest that the ancestral Francisella species originated in a marine habitat. The observed genome to genome variation in gene content and IS elements of different species supports the view that similar evolutionary paths of host adaptation developed independently in F. tularensis (infecting mammals) and F. noatunensis subsp. noatunensis (infecting fish).     

In vivo Himar1-based transposon mutagenesis of Francisella tularensis

Francisella tularensis is the intracellular pathogen that causes human tularemia. It is recognized as a potential agent of bioterrorism due to its low infectious dose and multiple routes of entry. We report the development of a Himar1-based random mutagenesis system for F. tularensis (HimarFT). In vivo mutagenesis of F. tularensis live vaccine strain (LVS) with HimarFT occurs at high efficiency. Approximately 12 to 15% of cells transformed with the delivery plasmid result in transposon insertion into the genome. Results from Southern blot analysis of 33 random isolates suggest that single insertions occurred, accompanied by the loss of the plasmid vehicle in most cases. Nucleotide sequence analysis of rescued genomic DNA with HimarFT indicates that the orientation of integration was unbiased and that insertions occurred in open reading frames and intergenic and repetitive regions of the chromosome. To determine the utility of the system, transposon mutagenesis was performed, followed by a screen for growth on Chamberlain's chemically defined medium (CDM) to isolate auxotrophic mutants. Several mutants were isolated that grew on complex but not on the CDM. We genetically complemented two of the mutants for growth on CDM with a newly constructed plasmid containing a nourseothricin resistance marker. In addition, uracil or aromatic amino acid supplementation of CDM supported growth of isolates with insertions in pyrD, carA, or aroE1 supporting the functional assignment of genes within each biosynthetic pathway. A mutant containing an insertion in aroE1 demonstrated delayed replication in macrophages and was restored to the parental growth phenotype when provided with the appropriate plasmid in trans. Our results suggest that a comprehensive library of mutants can be generated in F. tularensis LVS, providing an additional genetic tool to identify virulence determinants required for survival within the host.     

O-linked glycosylation of the PilA pilin protein of Francisella tularensis: identification of the endogenous protein-targeting oligosaccharyltransferase and characterization of the native oligosaccharide

Findings from a number of studies suggest that the PilA pilin proteins may play an important role in the pathogenesis of disease caused by species within the genus Francisella. As such, a thorough understanding of PilA structure and chemistry is warranted. Here, we definitively identified the PglA protein-targeting oligosaccharyltransferase by virtue of its necessity for PilA glycosylation in Francisella tularensis and its sufficiency for PilA glycosylation in Escherichia coli. In addition, we used mass spectrometry to examine PilA affinity purified from Francisella tularensis subsp. tularensis and F. tularensis subsp. holarctica and demonstrated that the protein undergoes multisite, O-linked glycosylation with a pentasaccharide of the structure HexNac-Hex-Hex-HexNac-HexNac. Further analyses revealed microheterogeneity related to forms of the pentasaccharide carrying unusual moieties linked to the distal sugar via a phosphate bridge. Type A and type B strains of Francisella subspecies thus express an O-linked protein glycosylation system utilizing core biosynthetic and assembly pathways conserved in other members of the proteobacteria. As PglA appears to be highly conserved in Francisella species, O-linked protein glycosylation may be a feature common to members of this genus.     

Genetic dissection of the Francisella novicida restriction barrier

Francisella tularensis is the causative agent of tularemia and is a category A select agent. Francisella novicida, considered by some to be one of four subspecies of F. tularensis, is used as a model in pathogenesis studies because it causes a disease similar to tularemia in rodents but is not harmful to humans. F. novicida exhibits a strong restriction barrier which reduces the transformation frequency of foreign DNA up to 10(6)-fold. To identify the genetic basis of this barrier, we carried out a mutational analysis of restriction genes identified in the F. novicida genome. Strains carrying combinations of insertion mutations in eight candidate loci were created and assayed for reduced restriction of unmodified plasmid DNA introduced by transformation. Restriction was reduced by mutations in four genes, corresponding to two type I, one type II, and one type III restriction system. Restriction was almost fully eliminated in a strain in which all four genes were inactive. The strongest contributor to the restriction barrier, the type II gene, encodes an enzyme which specifically cleaves Dam-methylated DNA. Genome comparisons show that most restriction genes in the F. tularensis subspecies are pseudogenes, explaining the unusually strong restriction barrier in F. novicida and suggesting that restriction was lost during evolution of the human pathogenic subspecies. As part of this study, procedures were developed to introduce unmodified plasmid DNA into F. novicida efficiently, to generate defined multiple mutants, and to produce chromosomal deletions of multiple adjacent genes.