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BRIEF DEFINITIVE REPORT |
CORRESPONDENCE Victor Nizet: vnizet{at}ucsd.edu
 Top Abstract RESULTS AND DISCUSSIONMATERIALS AND METHODSReferences |
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RESULTS AND DISCUSSION |
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TopAbstractRESULTS AND DISCUSSIONMATERIALS AND METHODSReferences |
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CrtM mutant was nonpigmented and lacked the characteristic triple-peak spectral profile of WT carotenoid at 440-, 462-, and 491-nM wavelengths (Fig. 1 B). No differences in growth rate, stationary phase density, surface charge, buoyancy, or hydrophobicity were observed between WT and CrtM S. aureus (Fig. S1, A–D, available at http://www.jem.org/cgi/content/full/jem.20050846/DC1). S. aureus crtM and crtN together are sufficient for production of 4,4'-diaponeurosporene (3). To facilitate gain of function analyses, we expressed both genes in the nonpigmented Streptococcus pyogenes, a human pathogen associated with a disease spectrum similar to that of S. aureus. When transformed with the pCrtMN plasmid, S. pyogenes gained yellow pigmentation (Fig. 1 B) with the spectral characteristics of a carotenoid (not depicted). Complementation of the S. aureus CrtM mutant with pCrtMN vector also fully restored pigmentation (Fig. 1 B).
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CrtM S. aureus to oxidants in vitro. As shown in Fig. 1, C and D, the CrtM mutant was killed more efficiently by hydrogen peroxide and singlet oxygen compared with the WT S. aureus strain. Complementation with pCrtMN restored the ability of the CrtM mutant to resist singlet oxygen killing (Fig. 1 D). Similarly, heterologous expression of staphylococcal pigment in S. pyogenes led to a significant decrease in susceptibility to singlet oxygen (Fig. 1 E).
S. aureus pigment confers resistance to neutrophil and whole-blood killing
We next sought to determine whether the observed antioxidant activity of the S. aureus carotenoid translated to increased bacterial resistance to innate immune clearance using two ex vivo assay systems: human or mouse whole-blood survival and coculture with purified human neutrophils. WT S. aureus survived significantly better than the nonpigmented CrtM intracellularly within human neutrophils (Fig. 2 A and Fig. S2 F, available at http://www.jem.org/cgi/content/full/jem.20050846/DC1) and in whole blood of normal mice or human donors (Fig. 2, B and E). The former effect was not explained by differences in the rate of phagocytosis, because uptake of the WT S. aureus and CrtM mutant was comparable (Fig. S2 A). Nor were differences attributable to changes in the magnitude of neutrophil oxidative burst, because uptake of WT and mutant strains produced similar results in a nitroblue tetrazolium reduction assay (Fig. S2 B). Complementation of the S. aureus CrtM mutant with pCrtMN restored resistance to killing by mouse whole blood (Fig. 2 B). Likewise, the pigmented S. pyogenes expressing staphylococcal carotenoid showed enhanced survival in human neutrophils versus the parent strain (Fig. 2 C).
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CrtM S. aureus survived equally well in human neutrophils (Fig. 2 D) and mouse blood (Fig. S2 C) when oxidative burst was inhibited by DPI. Gp47Phox–/– is an inherited defect in phagocyte oxidative burst function commonly found in patients who have chronic granulomatous disease (CGD), and the gp91Phox–/– mouse represents a model of human X-linked CGD (11). The survival advantage of WT over nonpigmented CrtM S. aureus was evident only in the blood of normal humans and mice (CD1 or C57Bl/6), and not in the blood of a human gp47phox–/– patient or gp91Phox–/– mice lacking NADPH oxidase activity (Fig. 2, E and F).
It was recently reported that the apparent neutrophil killing of pathogens by reactive oxygen species could largely reflect the activation of granule proteases mediated through changes in potassium flux (12). We found no difference in the susceptibility of WT and CrtM S. aureus to the antimicrobial action of cathepsin G, and both strains were resistant to human neutrophil elastase as previously observed for S. aureus (13) (Fig. S2 D). Other effector molecules of mammalian neutrophils critical to innate immune defense are the cathelicidin family of antimicrobial peptides (14). The carotenoid-deficient S. aureus mutant was equally susceptible to killing by the murine cathelicidin mCRAMP when compared with the WT strain (Fig. S2 E). These results support a primary role for the free-radical scavenging antioxidant properties of the S. aureus carotenoid in resistance to neutrophil-mediated killing.
S. aureus pigment contributes to virulence in a subcutaneous abscess model
Our in vitro and ex vivo results demonstrate that S. aureus carotenoid is both necessary and sufficient to promote oxidant resistance and phagocyte survival. To assess the significance of these observations to disease pathogenesis, we used a murine subcutaneous challenge model. In these studies, individual animals were injected simultaneously in one flank with the WT S. aureus strain and in the opposite flank with the CrtM mutant. At the site of WT injection (106 CFU), mice developed sizeable abscess lesions reaching a cumulative size of 80 mm2 by d 4; injection of an equivalent inoculum of the carotenoid-deficient mutant on the contralateral flank failed to produce visible lesions (Fig. 3 A). Quantitative culture from skin lesions at two different challenge doses (106 CFU to 107 CFU) consistently demonstrated significantly higher numbers of surviving WT S. aureus compared with the CrtM mutant in the individual mice (Fig. 3 A). To corroborate that an antioxidant effect is key to the mechanism of protection afforded by the S. aureus carotenoid in vivo, the subcutaneous infection experiment was repeated in gp91Phox–/– mice. In the absence of host NADPH oxidase function, WT and CrtM mutant S. aureus produced lesions of similar cumulative size, and no survival advantage was detected on quantitative abscess culture (Fig. 3 B). Finally, we asked whether S. aureus carotenoid was sufficient to enhance bacterial virulence by comparing the course of infection produced by S. pyogenes expressing CrtMN with that in controls transformed with vector alone. As shown in Fig. 3 C, lesions generated by the carotenoid-expressing strain were significantly larger and contained greater numbers of surviving bacteria than those produced by the WT strain. Raw data from the in vivo experiments are provided in Table S1 (available at http://www.jem.org/cgi/content/full/jem.20050846/DC1).
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carotenoid intermediate was noted in those experiments. As shown in Fig. 4 A, we found a dose-dependent decrease in pigment production in our WT strain of S. aureus grown in the presence of this agent. Blocking S. aureus pigment formation led to a dose-dependent increase in the susceptibility of the organism to singlet oxygen killing (Fig. 4 B) and a decrease in the ability of WT S. aureus to survive in murine whole blood (Fig. 4 C). As a control, the CrtM mutant was exposed to SKF 525-A in parallel experiments with no significant effects on oxidant susceptibility or blood survival (Fig. 4, B and C).
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MATERIALS AND METHODS |
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TopAbstractRESULTS AND DISCUSSIONMATERIALS AND METHODSReferences |
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Human CGD patient
The human CGD patient was an 18-yr-old female with a gp47phox deficiency (homozygous GT deletion in exon 2). At the time of study, she was in good health, and her only medication was IFN
(50 µg/m2) administered three times per wk by subcutaneous injection.
Generation of the carotenoid-deficient S. aureus mutant, CrtM
Precise, in-frame allelic replacement of the S. aureus crtM gene with a chloramphenicol acetyltransferase (cat) cassette was performed using PCR-based methods as described for S. pyogenes (19) or Streptococcus agalactiae (20), with minor modifications. Primers were designed based on the published S. aureus crtMN sequence (6) cross-referenced to genome S. aureus strain N315 (21). PCR was used to amplify 
500 bp upstream of crtM with primers crtMupF 5'-TTAGGAAGTGCATATACTTCAC-3' and crtMstartR 5'-GGTGGTATATCCAGTGATTTTTTTCTCCATACTAGTCCTCCTATATTGAAATG-3', along with 500 bp of sequence immediately downstream of crtM with primers crtMendF 5'-TACTGCGATGAGTGGCAGGGCGGGGCGTAACAAAGTATTTAGTATTGAAGC-3' and crtMdownR 5'-GGCACCGTTATACGATCATCGT-3'. The crtMstartR and crtMendF primers were constructed with 25-bp 5' extensions corresponding to the 5' and 3' ends of the cat gene, respectively. The upstream and downstream PCR products were then combined with a 650-bp amplicon of the complete cat gene (from pACYC184) as templates in a second round of PCR using primers crtMupF and crtMdownR. The resultant PCR amplicon, containing an in-frame substitution of crtM with cat, was subcloned into temperature-sensitive vector pHY304 to create the knockout plasmid. This vector was transformed initially into permissive S. aureus strain RN4220 (provided by P. Sullam (Veteran's Affairs Medical Center, San Francisco, CA) and then into S. aureus strain Pig1 by electroporation. Transformants were grown at 30°C, shifted to the nonpermissive temperature for plasmid replication (40°C), and differential antibiotic selection and pigment phenotype were used to identify candidate mutants. Allelic replacement of the crtM allele was confirmed unambiguously by PCR reactions documenting targeted insertion of cat and absence of crtM in chromosomal DNA isolated from the final mutant CrtM.
Complementation and heterologous expression studies.
Primers CrtF 5'-CAGTCTAGAAATGGCATTTCAATATAGGAG-3' and CrtR 5'-ATCGAGATCTCTCACATCTTTCTCTTAGAC-3' were used to amplify the contiguous CrtM and CrtN genes from the chromosome of WT S. aureus strain Pig1. The fragment was directionally cloned into the shuttle expression vector pDCerm (19) and the recombinant plasmid (pCrtMN) used to transform by electroporation the S. aureus CrtM mutant and S. pyogenes strain 5448. All stocks of pCrtMN-transformed S. pyogenes were destroyed by autoclaving at the conclusion of the project.
Spectral profile of the S. aureus carotenoid
Stationary phase (48-h) cultures of WT S. aureus Pig1 and its isogenic CrtM mutant were subjected to methanol extraction. The absorbance profile of the extracts was measured with a MBA 2000 spectrophotometer (PerkinElmer).
Oxidant susceptibility assays
Tests for susceptibility to oxidants were performed either in PBS (S. aureus) or THB (S. pyogenes). Hydrogen peroxide (H2O2) was added to 1.5% final concentration, 2 x 09 bacteria were incubated at 37°C for 1 h, and then 1,000 U/ml of catalase (Sigma-Aldrich) was added to quench residual H2O2. Dilutions were plated on Todd-Hewitt agar (THA) for enumeration of surviving CFU. For the singlet oxygen assay, 108 S. aureus or 4 x 108 S. pyogenes were incubated at 37°C in individual wells of a 24-well culture plate in the presence or absence of 1–6 µg/ml methylene blue and situated exactly 10 cm from a 100-W light source. Bacterial viability was assessed after 1–3 h by plating dilutions on THA. Control plates handled identically but wrapped in foil or exposed to light in the absence of methylene blue did not show evidence of bacterial killing.
Whole-blood killing assays
Bacteria were washed twice in PBS, diluted to an inoculum of 104 CFU in 25 µl PBS, and mixed with 75 µl of freshly drawn human or mouse blood in heparinized tubes. The tubes were incubated at 37°C for 4 h with agitation, at which time dilutions were plated on THA for enumeration of surviving CFU.
Neutrophil intracellular survival assays
Neutrophils were purified from healthy human volunteers using a Histopaque gradient (Sigma-Aldrich) per manufacturer's directions. Intracellular survival assays were performed as follows. Bacterial cultures were washed twice in PBS, diluted to a concentration of 4.5 x 106 CFU in 100 µl RPMI 1640 + 10% FCS and mixed with 3 x 105 neutrophils in the same media (multiplicity of infection = 15:1), centrifuged at 700 g for 5 min, then incubated at 37°C in a 5% CO2 incubator. Gentamicin (final concentration 400 µg/ml for S. aureus and 100 µg/ml for S. pyogenes; GIBCO BFL) was added after 10 min to kill extracellular bacteria. At specified time points, the contents of sample wells were withdrawn, centrifuged to pellet the neutrophils, and washed to remove the antibiotic medium. Neutrophils were then lysed in 0.02% Triton X, and CFU were calculated by plating on THA. Several assays were repeated with the addition of a step involving preincubation of the bacterial inoculum with 10% autologous human serum for 15 min on ice.
Murine model of subcutaneous infection
10–16-wk-old CD-1 or gp91Phox–/– mice were injected subcutaneously in one flank (chosen randomly) with the bacterial test strain and simultaneously in the opposite flank with a different strain for direct comparison. Bacterial cultures were washed, diluted, and resuspended in PBS mixed 1:1 with sterile Cytodex beads (GE Healthcare) at the specified inoculum, following an established protocol for generating localized S. aureus and S. pyogenes subcutaneous infection (14, 22). Lesion size, as assessed by the maximal length x width of the developing ulcers, was recorded daily. Cumulative lesion size represents the total sum of lesion sizes from all animals in each treatment group on a given day. At day 8 (S. aureus) or day 5 (S. pyogenes), animals were killed, and skin lesions were excised, homogenized in PBS, and plated on THA for quantitative culture.
Statistics
The significance of experimental differences in oxidant sensitivity, blood killing, and neutrophil survival were evaluated by unpaired Student's t test. Results of the mouse in vivo challenge studies were evaluated by paired Student's t test.
Assurances
All animal experiments were approved by the University of California, San Diego (UCSD) Committee on the Use and Care of Animals and performed using accepted veterinary standards. Experimentations using human blood were approved by the Dual Tracked UCSD Human Research Protection Program/CHSD IRB. Prior informed consents were obtained from the human subjects. Experimental protocols were approved by the UCSD Biosafety Committee.
Online supplemental material
Fig. S1 provides basic characterization of the WT and CrtM mutant S. aureus isolates in terms of growth rate, buoyancy, hydrophobicity, and surface charge. Fig. S2 contains data comparing WT and DCrtM mutant S. aureus with respect to rate of phagocytic uptake in neutrophils, induction of neutrophil oxidative burst, mouse whole-blood survival with and without NADPH oxidase inhibition, sensitivity to granule proteases and cationic antimicrobial peptides, and survival in human neutrophils after preopsonization. Table S1 contains detailed data on lesion size and bacterial counts from the in vivo mouse challenge experiments shown in Fig. 3. A brief supplemental Materials and methods section is provided for those experiments appearing only in the supplemental figures. Online supplemental material is available at http://www.jem.org/cgi/content/full/jem.20050846/DC1.
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Acknowledgments |
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The authors have no competing financial interests.
Submitted: 28 April 2005
Accepted: 1 June 2005
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References |
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TopAbstractRESULTS AND DISCUSSIONMATERIALS AND METHODSReferences |
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