Construction, transfer and properties of a novel temperature-sensitive integrable plasmid for genomic analysis of Staphylococcus aureus

Elimination of editing plasmid mediated by theophylline riboswitch in Zymomonas mobilis

Zymomonas mobilis is regarded as a potential chassis for the production of platform chemicals. Genome editing using the CRISPR-Cas system could meet the need for gene modification in metabolic engineering. However, the low curing efficiency of CRISPR editing plasmid is a common bottleneck in Z. mobilis. In this study, we utilized a theophylline-dependent riboswitch to regulate the expression of the replicase gene of the editing plasmid, thereby promoting the elimination of exogeneous plasmid. The riboswitch D (RSD) with rigorous regulatory ability was identified as the optimal candidate by comparing the transformation efficiency of four theophylline riboswitch-based backbone editing plasmids, and the optimal theophylline concentration for inducing RSD was determined to be 2 mM. A highly effective method for eliminating the editing plasmid, cells with RSD-based editing plasmid which were cultured in liquid and solid RM media in alternating passages at 37 °C without shaking, was established by testing the curing efficiency of backbone editing plasmids pMini and pMini-RSD in RM medium with or without theophylline at 30 °C or 37 °C. Finally, the RSD-based editing plasmid was applied to genome editing, resulting in an increase of more than 10% in plasmid elimination efficiency compared to that of pMini-based editing plasmid. KEY POINTS: • An effective strategy for curing CRISPR editing plasmid has been established in Z. mobilis. • Elimination efficiency of the CRISPR editing plasmid was enhanced by 10% to 20% under the regulation of theophylline-dependent riboswitch RSD.

Genetic interruption of target genes for investigation of virulence factors

Recently, more emphasis has been given to understand molecular genetics and the contribution of a gene in the disease process. In fact, increased understanding of bacterial pathogenesis and intracellular communication has revealed many potential strategies for development of novel agents to treat bacterial infection. Therefore, to study the function and the involvement of a particular gene in pathogenesis, the inactivation or interruption is very important. In this section, various methods leading to inactivation of the gene in Staphylococcus aureus will be discussed.

Generalized bacterial genome editing using mobile group II introns and Cre-lox

Efficient bacterial genetic engineering approaches with broad-host applicability are rare. We combine two systems, mobile group II introns ('targetrons') and Cre/lox, which function efficiently in many different organisms, into a versatile platform we call GETR (Genome Editing via Targetrons and Recombinases). The introns deliver lox sites to specific genomic loci, enabling genomic manipulations. Efficiency is enhanced by adding flexibility to the RNA hairpins formed by the lox sites. We use the system for insertions, deletions, inversions, and one-step cut-and-paste operations. We demonstrate insertion of a 12-kb polyketide synthase operon into the lacZ gene of Escherichia coli, multiple simultaneous and sequential deletions of up to 120 kb in E. coli and Staphylococcus aureus, inversions of up to 1.2 Mb in E. coli and Bacillus subtilis, and one-step cut-and-pastes for translocating 120 kb of genomic sequence to a site 1.5 Mb away. We also demonstrate the simultaneous delivery of lox sites into multiple loci in the Shewanella oneidensis genome. No selectable markers need to be placed in the genome, and the efficiency of Cre-mediated manipulations typically approaches 100%.

Targeted gene disruption for the analysis of virulence of Staphylococcus aureus

In recent years, molecular genetic approaches to the study of the disease pathogenesis of Staphylococcus aureus have resulted in many new biological insights. I describe methods used for targeted disruption of staphylococcal genes leading to loss of gene function, important for studies of staphylococcal proteins and their role in virulence.

The hyaluronate lyase of Staphylococcus aureus - a virulence factor?

The hyaluronate lyase (HL) gene of Staphylococcus aureus 8325-4 (hysA) was inactivated in vitro with the insertion of the erythromycin determinant, ermC, from plasmid pE194. The hysA : : ermC mutation was introduced into S. aureus via a temperature-sensitive shuttle vector, where it underwent homologous recombination with the wild-type (w.t.) allele. The insertion of ermC in the chromosomal hysA locus was confirmed by Southern blot hybridization and the loss of HL activity was demonstrated macroscopically by a plate assay. The importance of HL for pathogenicity was assessed by comparing the virulence of the HL(-) mutant strain to that of the w.t. in an established mouse abscess model of S. aureus infection. A significantly higher cell recovery was obtained from lesions infected with the w.t. strain compared to the lesions infected with the HL(-) strain (P =0.01). Although the lesion areas from both groups were not significantly different (P=0.9) they were of different morphology. A colorimetric assay was used to measure HL activity from culture supernatants of the S. aureus 8325-4 strains w.t., WA250 (agr) and PC1839 (sar) grown in a chemically defined medium. HL activity reached a maximum in the w.t. strain during mid-exponential phase (t=5 h) and while it showed a 16-fold decrease in the agr mutant it increased 35-fold in the sar mutant background. These results strongly suggest that HL is a virulence factor which is important in the early stages of subcutaneous infections.

Description of staphylococcus serine protease (ssp) operon in Staphylococcus aureus and nonpolar inactivation of sspA-encoded serine protease

Signature tagged mutagenesis has recently revealed that the Ssp serine protease (V8 protease) contributes to in vivo growth and survival of Staphylococcus aureus in different infection models, and our previous work indicated that Ssp could play a role in controlling microbial adhesion. In this study, we describe an operon structure within the ssp locus of S. aureus RN6390. The ssp gene encoding V8 protease is designated as sspA, and is followed by sspB, which encodes a 40.6-kDa cysteine protease, and sspC, which encodes a 12.9-kDa protein of unknown function. S. aureus SP6391 is an isogenic derivative of RN6390, in which specific loss of SspA function was achieved through a nonpolar allelic replacement mutation. In addition to losing SspA, the culture supernatant of SP6391 showed a loss of 22- to 23-kDa proteins and the appearance of a 40-kDa protein corresponding to SspB. Although the 40-kDa SspB protein could degrade denatured collagen, our data establish that this is a precursor form which is normally processed by SspA to form a mature cysteine protease. Culture supernatant of SP6391 also showed a new 42-kDa glucosaminidase and enhanced glucosaminidase activity in the 29 to 32 kDa range. Although nonpolar inactivation of sspA exerted a pleiotropic effect, S. aureus SP6391 exhibited enhanced virulence in a tissue abscess infection model relative to RN6390. Therefore, we conclude that SspA is required for maturation of SspB and plays a role in controlling autolytic activity but does not by itself exert a significant contribution to the development of tissue abscess infections.

Cloning of the Staphylococcus aureus ddh gene encoding NAD+-dependent D-lactate dehydrogenase and insertional inactivation in a glycopeptide-resistant isolate

The mechanism of low-level glycopeptide resistance among staphylococci is not known. A cytoplasmic protein, provisionally called Ddh (W. M. Milewski, S. Boyle-Vavra, B. Moreira, C. C. Ebert, and R. S. Daum, Antimicrob. Agents Chemother. 40:166-172, 1996), and the RNA transcript that contains the ddh gene, which encodes Ddh, are present in increased amounts in a vancomycin-resistant isolate, 523k, compared with the susceptible parent isolate, 523. Sequence analysis had previously revealed that Ddh is related to NAD+-dependent D-lactate dehydrogenase (D-nLDH) and VanH. This latter protein is essential for high-level glycopeptide resistance in Enterococcus faecium and Enterococcus faecalis by synthesizing the D-lactate needed for biosynthesis of D-lactate-terminating peptidoglycan precursors with low affinity for vancomycin. We now provide the direct evidence that the ddh gene product is Staphylococcus aureus D-nLDH and hereafter refer to the protein as D-nLDH. However, overproduction of this protein in isolate 523k did not result in production of D-lactate-containing peptidoglycan precursors, and susceptibility testing of ddh mutants of 523k demonstrated that S. aureus D-nLDH is not necessary for glycopeptide resistance in this isolate. We conclude that the mechanism of glycopeptide resistance in this isolate is distinct from that in enterococci.

Construction of the temperature-sensitive vectors pLUCH80 and pLUCH88 for delivery of Tn917::NotI/SmaI and use of these vectors to derive a circular map of Listeria monocytogenes Scott A, a serotype 4b isolate

A physical map of Listeria monocytogenes Scott A was generated by the pulsed-field technique of contour-clamped-homogeneous-electric-field (CHEF) electrophoresis. The circular genome of this serotype 4b strain contains 12 AscI fragments (38 to 790 kb), 5 NotI fragments (55 to 1,400 kb), 3 SrfI fragments (110, 1,110, and 2,000 kb), and 2 SfiI fragments (1,320 and 1,920 kb). Summation of individually sized fragments derived by digestion of Scott A genomic DNA with each of these four enzymes provided an average estimated genome length of 3,210 +/- 60 kb. Efforts to assemble the macrorestriction map benefited greatly from the construction and use of pLUCH80 and pLUCH88, temperature-sensitive vectors for delivering transposon Tn917::NotI/SmaI to the chromosome of Scott A. As another component of this study, the positions of four known virulence genes (inlA, mpl, hly, and prf) and three L. monocytogenes-specific sequences (lisM44, lisM51, and lisM52) were localized on the physical map of Scott A by hybridization. Probes prepared from lisM44, lisM51, and the four virulence genes hybridized within a cluster on a 150-kb fragment of the Scott A genome that overlaps part of the NotI-B and AscI-D fragments. The lisM52 probe hybridized with the AscI-F2 (120-kb) fragment of Scott A, which is separated from the NotI-B-AscI-D region by about 300 kb. These results established the first physical and genetic map of a serotype 4b strain of L. monocytogenes and provided further insight on this important food-borne pathogen at the genome level.

Gene replacement in Staphylococcus carnosus and Staphylococcus xylosus

A system for high-efficiency gene replacement in Staphylococcus carnosus and Staphylococcus xylosus has been developed, that is based on temperature-sensitive Escherichia coli-Staphylococcus shuttle vectors for fragment delivery and erythromycin resistance cassettes to facilitate selection of genomic copies of disrupted genes. The approach was tested by constructing a phosphotransferase-deficient mutant of S. carnosus and an S. xylosus mutant strain unable to utilize sucrose. Allelic replacements were observed at rather high frequencies, ranging from approximately 10% for the ptsI gene in S. carnosus up to 50% for the scrB gene in S. xylosus. These differences most likely reflect the length of homology rather than strain-specific variations in recombination efficiencies. Apart from the staphylococcal species tested in this study, the system appears to be applicable in other staphylococci.

Lack of the extracellular 19-kilodalton fibrinogen-binding protein from Staphylococcus aureus decreases virulence in experimental wound infection

A mutant deficient for the 19-kDa extracellular fibrinogen-binding protein (Fib) from Staphylococcus aureus has been constructed. The gene was inactivated by allele replacement. A 2.0-kb fragment from transposon Tn4001 carrying the gene for gentamicin resistance was inserted into the gene encoding Fib (fib). The genotype was verified by PCR analysis, and the loss of Fib was demonstrated by Western blotting (immunoblotting). The mutation has not altered the ability of the strain to bind to fibrinogen or fibronectin compared with that of the isogenic parental strain, FDA486. The mutant, designated K4.3, was compared with strain FDA486 in a wound infection model in rats. Sixty-eight percent of the rats challenged with parental strain FDA486 developed severe clinical signs of wound infection, whereas only 29% of the animals challenged with isogenic mutant K4.3 showed severe symptoms (P < 0.01). The weight loss of animals infected with the wild type was also significantly different from that of animals infected with the mutant strain. The result demonstrates that the extracellular 19-kDa fibrinogen-binding protein from S. aureus contributes to the virulence in wound infection and delays the healing process.

The Staphylococcus aureus collagen adhesin is a virulence determinant in experimental septic arthritis

The importance of a collagen-binding adhesin in the pathogenesis of septic arthritis has been examined by comparing the virulence of two sets of Staphylococcus aureus mutants in an animal model. Collagen adhesin-negative mutant PH100 was constructed by replacing the chromosomal collagen adhesin gene (cna) in a clinical strain, Phillips, with an inactivated copy of the gene. Collagen adhesin-positive mutant S. aureus CYL574 was generated by introducing the cna gene into CYL316, a strain that normally lacks the cna gene. Biochemical, immunological, and functional analyses of the generated mutants and their respective parent strains showed that binding of 125I-labeled collagen, expression of an immunoreactive collagen adhesin, and bacterial adherence to cartilage were directly correlated with the presence of a functional cna gene. Greater than 70% of the mice injected with the Cna+ strains developed clinical signs of arthritis, whereas less than 27% of the animals injected with Cna- strains showed symptoms of disease. Furthermore, mice injected with the Cna+ strain Phillips had remarkably elevated levels of immunoglobulin G1 and interleukin-6 compared with mice injected with the Cna- mutant PH100. Taken together, these results demonstrate that collagen adhesin plays an important role in the pathogenesis of septic arthritis induced by S. aureus.

Genomic analysis of Pediococcus starter cultures used to control Listeria monocytogenes in turkey summer sausage

The pulsed-field technique of clamped homogeneous electric field electrophoresis was employed to characterize and size genomic DNA of three pediocin-producing (Ped+) and two non-pediocin-producing (Ped-) strains of Pediococcus acidilactici. Comparison of genomic fingerprints obtained by digestion with the low-frequency-cleavage endonuclease AscI revealed identical restriction profiles for four of the five strains analyzed. Summation of results for 10 individually sized AscI fragments estimated the genome length to be 1,861 kb for the four strains (H, PAC1.0, PO2, and JBL1350) with identical fingerprints. Genomic analysis of the pediocin-sensitive, plasmid-free strain P. acidilactici LB42 with the unique fingerprint revealed nine AscI fragments and a genome length of about 2,133 kb. Ped- (JBL1350) and Ped+ (JBL1095) starter cultures (one each) were used to separately prepare turkey summer sausage coinoculated with a four-strain Listeria monocytogenes mixture (ca. 10(5) CFU/g). The starter cultures produced equivalent amounts of acid during fermentation, but counts of L. monocytogenes were reduced to a greater extent in the presence of the Ped+ starter culture (3.4 log10 unit decrease) than in the presence of the Ped- starter culture (0.9 log10 unit decrease). Although no listeriae were recovered from sausages following the cook/shower, appreciable pediocin activity was recovered from sausages prepared with the Ped+ strain for at least 60 days during storage at 4 degrees C. The results of this study revealed genomic similarities among pediococcal starter cultures and established that pediocins produced during fermentation provide an additional measure of safety against listerial proliferation in turkey summer sausage.

Construction of an IS946-based composite transposon in Lactococcus lactis subsp. lactis

An artificial composite transposon was constructed based on the lactococcal insertion sequence IS946. A 3.0-kb element composed of the pC194 cat gene (Cmr) flanked by inversely repeated copies of IS946 was assembled on pBluescript KS+. When subcloned into the shuttle vector pSA3 (Emr), two putative transposons were created on the recombinant plasmid pTRK128: the 3.0-kb Cmr element (Tn-CmA) and an inverse 11.5-kb Emr element (Tn-EmA). pTRK128 was electroporated into the recombination-deficient strain Lactococcus lactis MMS362, which contains the self-transmissible plasmid pRS01. An MMS362 Cmr Emr transformant was used to assay for transposition events via conjugal mobilization of pTRK128-encoded Cmr or Emr to L. lactis LM2345. Transfer of either marker alone occurred at frequencies of ca. 2 x 10(-4) per input donor. Approximately 19% of the Emr transconjugants were Cms, indicating loss of the cat gene marker. No Cmr Ems transconjugants were recovered (n = 550). Plasmid analysis showed that the Cms Emr isolates contained a single large plasmid that was determined to be a cointegrate between pRS01 and the Tn-EmA element. A 32P-labeled pSA3 probe hybridized specifically to pTRK128 sequences and revealed different junction fragments within each of the cointegrate plasmids. DNA sequence analysis of the Tn-EmA::pRS01 junctions from a representative cointegrate verified transposition by Tn-EmA. This represents the first example of a functional composite transposon in the genus Lactococcus and serves as an experimental tool and model for the genetic analyses of transposons in these organisms.

Molecular cloning and deoxyribonucleic acid polymorphisms in Lactobacillus acidophilus and Lactobacillus gasseri

Lactobacillus strain ADH is a bile-resistant, bacteriocin-producing human isolate that was phenotypically classified within the Lactobacillus acidophilus group. Total DNA and phage DNA extracted from strain ADH were separately digested with BclI and ligated with BclI-digested pGK12. Following electroporation of these ligation mixtures directly into strain ADH, electrotransformants were recovered at frequencies of 1.5 x 10(3) and 2.0 x 10(4)/micrograms of pGK12 for preparations of pGK12::phage DNA and pGK12::total DNA, respectively. Among the electrotransformants screened, 6 and 22% contained passenger DNA of either phage DNA or chromosomal origin, respectively, as determined by restriction-enzyme analyses and hybridization assays. Derivatives of pGK12 containing passenger DNA of chromosomal (pTRK120) or phage (pTRK121) origin and pTRK15 (native cryptic plasmid) were evaluated for use as species-specific probes. The strain ADH-derived probes hybridized primarily to members of the B-1 and B-2 lactobacilli homology groups and demonstrated strain-specific polymorphisms within these groups. Identical hybridization patterns were established for strain ADH and Lactobacillus gasseri VPI 6033 (ATCC 19992). Identification of DNA probes and establishment of a host-vector cloning system have facilitated our efforts to characterize the Lactobacillus chromosome and to distinguish between closely related species thought to be important inhabitants of the gastrointestinal tract.

Gene disruption by plasmid integration in Listeria monocytogenes: insertional inactivation of the listeriolysin determinant lisA

A plasmid integration technique was developed for insertional inactivation of chromosomal Listeria monocytogenes genes. A Listeria-Escherichia coli shuttle vector (pLSV1) was constructed which carried the temperature-sensitive gram-positive replication origin from plasmid pTV32(Ts). An internal fragment of the listeriolysin gene (lisA) was cloned into pLSV1 to create pLSV2. In L. monocytogenes pLSV2 transformants, plasmid pLSV2 integrated into the L. monocytogenes chromosome at a frequency of 2 x 10(-3) via lisA homology and these cells could be selected at 42 degrees C using a plasmid-encoded erythromycin resistance. Plasmid integration resulted in disruption of the lisA gene, production of a truncated, immunologically cross-reactive listeriolysin protein and loss of the hemolytic phenotype. An improved Listeria protoplast transformation method is also described which facilitates genetic manipulation of Listeria species.

Construction of single-copy integration vectors for Staphylococcus aureus

Single-copy integration vectors suitable for cloning in Staphylococcus aureus have been constructed. Their construction was based on the site-specific recombination system of staphylococcal phage, L54a. The vectors are capable of autonomous replication in Escherichia coli, but they are not endowed with a replication function in S. aureus. As a consequence, establishment of these vectors in S. aureus can only be achieved by the integration system of the phage. Once integrated into the chromosome, the vectors, or their derivatives, were stably inherited even without selective pressure. Because such a vector exists in an integrated form in S. aureus, the gene dosage of the DNA cloned in the vector matches that of the chromosome.

Generation of deletions in pTV1tsfollowing transformation of Staphylococcus aureas protoplasts

Plasmid pTV1ts was introduced into Staphylococcus aureus by transformation of protoplasts at frequencies ranging from 6.6 x 10(1) to 2.8 x 10(5) per micrograms of DNA when selection was made for resistance to chloramphenicol and erythromycin, respectively. Phenotypic analysis of regenerated transformants demonstrated three distinct classes. Analysis of the plasmid profiles of several isolates revealed that two classes harboured deleted pTV1ts derivatives.

Characterization of insertion sequence IS946, an Iso-ISS1 element, isolated from the conjugative lactococcal plasmid pTR2030

The self-transmissible plasmid pTR2030 mobilized nonconjugative heterologous cloning vectors pGK12 (Cmr Emr) and pSA3 (Emr) at frequencies of 10(-5) to 10(-6) per input donor. Transconjugants harbored a 51- or 58-kilobase (kb) plasmid not found in the parental strains that cotransferred at high frequency with Cmr Emr and pTR2030-encoded phage resistance (Hsp+) in second-round matings (10(-1) per input donor). Restriction endonuclease mapping and DNA-DNA hybridization identified the 51- to 58-kb plasmids as pTR2030::vector cointegrates. Examination of four cointegrates indicated that pGK12 and pSA3 had inserted within two locations on pTR2030. Resolution of the cointegrates generated vector derivatives containing a 0.8-kb insert of pTR2030 DNA. Restriction analyses of several resolution plasmids indicated that the 0.8-kb element had inserted into various positions within pGK12 and pSA3 and in certain cases had inactivated the Cmr or Emr marker of pGK12. A conjugative mobilization assay demonstrated that the 0.8-kb element, designated IS946, mediated transpositional recombination. Nucleotide sequence determination identified IS946 as an 808-base-pair (bp) insertion sequence sharing ca. 96% homology with lactococcal insertion sequence ISS1. IS946 differed by 27 and 31 bp from ISS1S and ISS1T, respectively, and in 2 of 226 amino acids in the deduced sequence of the putative transposase. IS946 has perfect 18-bp terminal inverted repeats, identical to ISS1, and similarly generated 8-bp direct repeats of the target site upon insertion.

Characterization of the temperate bacteriophage phi adh and plasmid transduction in Lactobacillus acidophilus ADH

Lactobacillus acidophilus ADH is lysogenic and harbors an inducible prophage, phi adh. Bacteriophage were detected in cell lysates induced by treatment with mitomycin C or UV light. Electron microscopy of lysates revealed phage particles with a hexagonal head (62 nm) and a long, noncontractile, flexible tail (398 nm) ending in at last five short fibers. Phage phi adh was classified within Bradley's B1 phage group and the Siphoviridae family. The phi adh genome is a linear double-stranded DNA molecule of 41.7 kilobase pairs with cohesive ends: a physical map of the phi adh genome was constructed. A prophage-cured derivative of strain ADH, designated NCK102, was isolated from cells that survived UV exposure. NCK102 did not exhibit mitomycin C-induced lysis, but broth cultures lysed upon addition of phage. Phage phi adh produced clear plaques on NCK102 in media containing 10 mM CaCl2 at pH values between 5.2 and 5.5. A relysogenized derivative (NCK103) of NCK102 was isolated that exhibited mitomycin C-induced lysis and superinfection immunity to phage phi adh. Hybridization experiments showed that the phi adh genome was present in the ADH and NCK103 chromosomes, but absent in NCK102. These results demonstrated classic lytic and lysogenic cycles of replication for the temperate phage phi adh induced from L. acidophilus ADH. Phage phi adh also mediates transduction of plasmid DNA. Transductants of strain ADH containing pC194, pGK12, pGB354, and pVA797 were detected at frequencies in the range of 3.6 x 10(-8) to 8.3 x 10(-10) per PFU. Rearrangements or deletions were not detected in these plasmids as a consequence of transduction. This is the first description of plasmid transduction in the genus Lactobacillus.