The normal microflora of the skin includes staphylococcal species that will induce inflammation when present below the dermis but are tolerated on the epidermal surface without initiating inflammation. Here we reveal a previously unknown mechanism by which a product of staphylococci inhibits skin inflammation. This inhibition is mediated by staphylococcal lipoteichoic acid (LTA) and acts selectively on keratinocytes triggered through Toll-like receptor 3(TLR3). We show that TLR3 activation is required for normal inflammation after injury and that keratinocytes require TLR3 to respond to RNA from damaged cells with the release of inflammatory cytokines. Staphylococcal LTA inhibits both inflammatory cytokine release from keratinocytes and inflammation triggered by injury through a TLR2-dependent mechanism. To our knowledge, these findings show for the first time that the skin epithelium requires TLR3 for normal inflammation after wounding and that the microflora can modulate specific cutaneous inflammatory responses.
All complex metazoans are colonized with a myriad of microbial organisms, a group that has been referred to as the 'microbiome'. On the skin, bacterial colonization is abundant, diverse and constant, but inflammation is undesirable and is an indication of disease. The two principal normal stimuli of inflammation are injury and infection. During infection, the detection of microbes is accomplished in part by TLRs, which are best known as stimuli of inflammation. Although the role of TLRs in response to infection is well defined, the mechanisms involving TLRs that regulate inflammation in the skin injury are poorly understood.
Epithelial surfaces in the gut regulate the magnitude and duration of TLR signaling, thus shaping and maintaining normal mucosal immunity1,2,3 via the induction of proinflammatory and anti-inflammatory cytokine synthesis4,5. Moreover, the commensal bacteria Lactococcus lactis and Bacteroides vulgatus can prime the host to produce interleukin-10 (IL-10), trefoil factors and transforming growth factor-β (TGF-β), which are suggested to modulate inflammation in the intestine6,7,8. However, TLRs that have been generally thought to act as proinflammatory signals in response to microbial products also may recognize self-epitopes that are released from damaged cells or are present at the surface of apoptotic cells in autoimmune diseases9,10. These observations have raised the possibility that TLRs may have a role in initiating inflammation in response to injury11,12.
In skin injury, tissue damage results in necrosis and apoptosis, but it is not known if this event is involved in the initiation of the inflammatory response that is crucial to normal wound repair. In the absence of infection, uncontrolled inflammation during wound repair is undesirable and may cause dysfunction during healing. Uncontrolled inflammation after minor trauma is also well known to exacerbate several human skin diseases, such as psoriasis. Therefore, normal immune defense requires that a balance is maintained to minimize unnecessary inflammation yet rapidly respond to infection and injury. This balance is particularly difficult to maintain at epithelial surfaces that are in contact with the external environment and have frequent trauma and exposure to the products of the microbiome. The innate systems that enable the control of this inflammatory response are generally unknown.
Given the hypothesis that epithelial flora may serve to protect the host from unintended inflammatory diseases and the importance of TLRs in the recognition of microbial products and potential role after tissue damage, we set out to study how these systems may be involved in homeostatic control of skin inflammation. Staphylococcal species are the most frequently cultured normal inhabitants of the healthy human skin13 and have been hypothesized to serve a role in human health14. It has been entirely unknown how these bacteria might affect cutaneous homeostasis. In this study, we describe a mechanism by which a product of staphylococci, LTA, suppresses skin inflammation during wound repair.
Note: Supplementary information is available on the Nature Medicine website.
Staphylococcal products suppress inflammation
Recent observations in several systems have suggested that activation of TLRs on keratinocytes will trigger inappropriate production of proinflammatory cytokines in the epidermis as an element in the pathogenesis of some skin diseases15,16,17. However, despite production of TLR ligands, commensal bacterial species, including Staphylococcus epidermidis, normally reside in contact with keratinocytes in the epidermis and do not initiate inflammation. We therefore hypothesized that S. epidermidis can influence the inflammatory response of keratinocytes through negative regulation of TLR signaling. Primary human keratinocytes treated with a panel of TLR ligands showed that polyriboinosinic polyribocytidylic acid (poly(I:C)), a stimulus for TLR3 (refs. 18,19), was the most potent stimulus for expression of tumor necrosis factor-α (TNF-α) by keratinocytes and that previous exposure to a <10-kDa product of S. epidermidis suppressed poly(I:C)-induced IL-6 and TNF-α expression (Fig. 1a and Supplementary Fig. 1a). This suppression persisted over time and affected both messenger RNA and protein levels of TNF-α (Supplementary Fig. 1b).
We next examined cutaneous inflammation induced by poly(I:C) in mice to determine the in vivo relevance of the response observed to S. epidermidis. Ears pretreated with the <10-kDa product of S. epidermidis before poly(I:C) showed less inflammation compared to those treated only with poly(I:C) (Fig. 1b,c). The decrease in inflammation corresponded with a decrease in the expression of IL-6 and TNF-α mRNA (Fig. 1d). However, we did not observe the inhibitory effects of S. epidermidis <10-kDa product in whole skin when inflammation was induced by lipopolysaccharide (LPS) (Supplementary Fig. 1c), or phorbol 12-myristate 13-acetate (PMA) (Supplementary Fig. 1d). Thus, these data show that a product of S. epidermidis functions as a selective suppressor of poly(I:C)-mediated inflammation in the skin.
Analysis of similar soluble <10-kDa products of other staphylococcal strains showed that the capacity to inhibit poly(I:C)-induced TNF-α expression was present in multiple staphylococcal strains, except one hospital-isolated strain of Staphylococcus aureus (Supplementary Fig. 2). The <10-kDa product of S. epidermidis also suppressed the expression of IL-8 but was not able to suppress interferon-β (IFN-β) or IL-1β (data not shown). Moreover, the <10-kDa product of S. epidermidis inhibited the capacity of mouse epidermal sheets to express TNF-α and IL-6 in response to poly(I:C) (Supplementary Fig. 3a). However, in contrast to keratinocytes and epidermal sheets, other cell types representative of those present in skin but below the epidermis were not inhibited by the <10-kDa product of S. epidermidis and had increased expression of IL-6 and TNF-α in response to poly(I:C) and S. epidermidis (Supplementary Fig. 3b–d). Taken together, these results show poly(I:C) is a potent stimulus to release proinflammatory cytokines in the skin, but a soluble, low-molecular-weight product from some bacteria will inhibit this response selectively in keratinocytes.
TLR3 mediates a response to injury
To understand the immunological relevance of suppression of TLR3-induced cytokine release by keratinocytes, we next sought to investigate conditions in which TLR3 might be activated in skin. In gastrointestinal epithelium, TLR3 has been implicated as a mechanism for detection of cell death20. Skin injury results in the generation of necrotic and apoptotic cells21,22. Therefore, we examined whether TLR3 activation might be a mechanism for detection of skin injury and initiation of inflammation. To test this hypothesis, we made aseptic, full-thickness incisions on the backs of Tlr3-deficent mice and matched wild-type controls. Tlr3-deficent mice showed significantly less production of IL-6 and TNF-α at the wound edge compared to wild-type controls (Fig. 2a). This correlated with a decrease in inflammation and leukocyte recruitment (Fig. 2b and Supplementary Fig. 4). Furthermore, consistent with the inhibitory effects of S. epidermidis on poly(I:C)-induced skin inflammation, application of the <10-kDa product of S. epidermidis also inhibited wound-induced IL-6, TNF-α and inflammation in wild-type mice but had no marked effect on the injury response in Tlr3−/− mice (Fig. 2a,b and Supplementary Fig. 4). Thus, these findings establish that Tlr3 is required for part of the normal inflammatory response after injury and that S. epidermidis acts on this pathway to decrease the magnitude of inflammation.
Wounding results in the rapid generation of abundant amounts of damaged cells, including necrotic and apoptotic keratinocytes. To test whether a product of damaged keratinocytes can stimulate TLR3-dependent inflammation in adjacent normal cells, we treated cultured human keratinocytes with ultraviolet B (UVB) radiation to induce apoptosis and cell death. We then collected these cells (UVR cells) and added them to separate cultures of normal human keratinocytes. TNF-α release significantly increased when we exposed normal keratinocytes to UVR cells but not when we exposed them to equal amounts of sonicated, nonirradiated cells (Fig. 2c and Supplementary Fig. 5a). This response was dependent on TLR3, as targeted knockdown of TLR3 by siRNA abrogated the response to UVR cells (Fig. 2c and Supplementary Fig. 6). Consistent with the response to poly(I:C) or wounding, the <10-kDa product of S. epidermidis also inhibited TNF-α release induced by UVR cells (Fig. 2d). The product of UVR cells that activated TLR3 in normal keratinocytes was RNA, as RNase abrogated the capacity of UVR cells to stimulate the production of TNF-α, but treatment with DNase did not (Fig. 2e). We also sorted UVR cells into intact, annexin V+ cells that excluded propidium iodide and dead cells whose membrane was permeable after UVB irradiation and thus stained with propidium iodide. Nonirradiated cells (normal cells) disrupted by sonication, or early apoptotic cells that were annexin V–positive but excluded propidium iodide (annexin V–positive, propidium iodide–negative cells), could not induce TNF-α release or TLR3 expression (Supplementary Fig. 5a,b). However, UVR cells staining with propidium iodide (propidium iodide–positive cells) substantially increased TNF-α release and TLR3 expression (Supplementary Fig. 5a,b). Thus, these results show that RNA released from necrotic cells can induce TNF-α and TLR3 expression in keratinocytes.
LTA suppresses TLR3 inflammation
TLR-TLR cross-talk can suppress inflammatory responses23,24, and LTA is a known molecular signal for recognition of staphylococci; thus, we sought to determine whether this molecule might be responsible for the observed effects. LTA from S. epidermidis has two forms, cellular and exocellular LTA25. Exocellular LTA can be recovered from liquid growth medium and is the form present in the <10-kDa product of S. epidermidis, whereas commercial LTA is derived from the cell wall and membrane. Commercially available LTA from S. aureus (LTA-SA), but not LPS or flagellin, suppressed the production of TNF-α induced by poly(I:C) (Fig. 3a). LTA directly purified from S. epidermidis (LTA-SE) or commercial LTAs from some other staphylococcal species suppressed poly(I:C)-induced TNF-α, whereas other ligands of TLR2 either synergistically induced TNF-α or failed to suppress TNF-α when combined with poly(I:C) (Fig. 3b). TLR2 ligands tested included PGN-SA (peptidoglycan from Staphylococcus aureus), PGN-EK (peptidoglycan from Escherichia coli K12) and zymosan, as well as ligands that activate heterodimers of TLR2 and TLR1 such as the synthetic triacylated lipoprotein Pam3CSK4, or ligands of heterodimers of TLR2 and TLR6 such as diacylated lipoprotein FSL-1 ((S,R)-(2,3-bispalmitoyloxypropyl)-Cys-Gly-Asp- RPro-Lys-His-Pro-Lys-Ser-Phe) and macrophage-activating lipopeptide (Malp-2). Notably, LTAs from Streptococcus fecalis and Bacillus subtilis (LTA-SF and LTA-BS) were not active (Fig. 3b).
We next confirmed the identity of LTA as the molecule in S. epidermidis responsible for suppression of keratinocyte TNF-α production by use of a specific LTA-neutralizing antibody25 (Fig. 3c). Furthermore, synthetic LTAs containing two or three D-alanines suppressed poly(I:C)-induced TNF-α, whereas synthetic LTAs only containing an anchor or containing two or five N-acetylglucosamine failed to suppress TNF-α (Fig. 3d). We then confirmed the necessity of D-alanine modification by using LTA from a S. aureus dltA mutant that lacks D-alanine modifications26. Preparations from this mutant bacterial culture supernatant (SA dltA) partially lost the capacity to suppress poly(I:C)-induced TNF-α compared to its parental strain (Fig. 3e).
N-TRAF1 mediates LTA inhibition of TLR3
We observed that S. epidermidis blocked nuclear translocation of the p50 subunit of nuclear factor-κB1, but not the translocation of interferon regulatory factor-3, both stimulated by poly(I:C) in keratinocytes (Supplementary Fig. 7a,b). Thus, we next investigated negative regulators involved in TLR-mediated NF-κB signaling, including TNF receptor–associated factor-1 (TRAF1), TNF-α–induced protein-3 (TNFAIP3) and interleukin-1 receptor–associated kinase M (IRAK-M)27. LTA and the <10-kDa product of S. epidermidis significantly induced TRAF1 protein and mRNA in keratinocytes within 1 h and maximally between 6 and 9 h (Fig. 4a and Supplementary Fig. 8a). The expression of other negative regulatory genes such as nucleotide-binding domain (NBD)- and leucine-rich-repeat (LRR)-containing family member X1 (NLRX1), TNFAIP3 or IRAK3 (encoding IRAK-M) involved in both the NF-κB and retinoic acid–inducible gene (RIG)-like helicase pathways, were not induced (Supplementary Fig. 8a). We confirmed the role of TRAF1 as a mediator of the LTA inhibitory effect by experiments in Traf1−/− mice where LTA was unable to suppress the production of IL-6 and TNF-α at wound edge compared to wild-type controls (Fig. 4b).
It has been hypothesized that TRAF1 is processed by caspase-8 to an active N-terminal fragment (N-TRAF1) followed by binding to TRIF to serve as a negative regulator of TLR3. We observed the cleavage of TRAF1 to N-TRAF1 in the presence of the <10-kDa product of S. epidermidis and poly(I:C) (Fig. 4c), and it occurred in a caspase-8–dependent manner, as treatment with a caspase-8 inhibitor blocked the generation of N-TRAF1 (Fig. 4d). We found that TRAF1 associated with TRIF by immunoprecipitation of S. epidermidis–treated keratinocytes with TRAF1-specific antibody and detection with antibody to TRIF (Supplementary Fig. 8b). Furthermore, addition of a caspase-8 inhibitor increased TNF-α production and completely abrogated the inhibitory effects of S. epidermidis and LTA (Supplementary Fig. 8c,d).
TLR2 inhibits TLR3
Having established the involvement of TRAF1 in the suppression of keratinocyte cytokine release, and the role of the TLR2 ligand LTA in initiating this effect, we next sought to further confirm the mechanism and physiological relevance of these observations in vivo. Analysis of the skin from germ-free wild-type mice that were never exposed to bacterial products showed that the expression of Traf1 in their skin was markedly decreased compared to skin of normal mice housed in pathogen-free but nonsterile conditions (Fig. 4e). In addition to that in skin, the expression of Traf1 in small intestine and lung, but not in heart, of germ-free wild-type mice was decreased compared to those tissues from conventional wild-type mice (Supplementary Fig. 8e). Furthermore, because recognition of LTA requires TLR2 and the downstream adapter protein myeloid differentiation factor-88 (MYD88), we also observed diminished expression of Traf1 in Tlr2−/− or Myd88−/− mice exposed to LTA (Fig. 4f). Therefore, Tlr2−/− mice might be used as another model to test the effect of diminished Traf1 on suppression of Tlr3-dependent skin inflammation after injury. As expected, LTA failed to suppress inflammation and the production of IL-6 and TNF-α at wound edge in Tlr2−/− mice (Fig. 5a,b), and we observed a similar loss of responsiveness to LTA in Tlr2−/− mice treated with poly(I:C) (Fig. 5c).
Commensal microorganisms have been proposed to influence host immune responses and host-pathogen interactions in the gut28. Here we hypothesized that specific elements of the resident microbiota of normal human skin can modulate cutaneous immune responses triggered by TLR ligands. Our results confirmed this hypothesis while also revealing that TLR3 is a key element in the induction of inflammation after skin injury. Inhibition of this inflammatory event is accomplished by specific staphylococcal LTAs and is mediated by TLR2 on keratinocytes. The mechanism for LTA-TLR– mediated suppression of TLR3 signaling is by induction of the negative regulatory factor TRAF1, an event we show has a major role in limiting the extent of cutaneous inflammation. Thus, we show that a sensitive balance exists between stimulating and inhibitory mediators during wound healing and that epithelial cells uniquely detect these signals to achieve tissue homeostasis after injury.
It was previously unclear why keratinocytes are highly sensitive to TLR3 ligands, as the classical ligand for TLR3, viral double-stranded RNA, is not a frequent initiator of major inflammatory responses in the skin. The epidermis can be exposed to double-stranded RNA from viral infections, but such infections are relatively uncommon compared to infections by other skin pathogens. We show here that the high sensitivity to TLR3 ligands is probably because the epidermis uses TLR3 for recognition of injury to self. Our data show that RNA from necrotic cells triggers TLR3 on undamaged keratinocytes, leading to a local release of proinflammatory cytokines. This is probably a frequent mechanism for detection of injury and maintenance of homeostasis, as necrotic cells are abundant at the wound edge. Therefore, it is reasonable to speculate that TLR3 in the normal epidermis is an important sensor of injury and that systems must exist to modulate this response to prevent excessive or unwanted inflammation. Furthermore, given that S. epidermidis or LTA not only inhibited proinflammatory cytokine production by isolated keratinocytes in culture but also inhibited inflammation in vivo, the production of proinflammatory cytokines by keratinocytes is probably a major contributor to some forms of skin inflammation.
Our findings show that LTA produced by staphylococcal species have a unique anti-inflammatory action on keratinocytes. In contrast, LTA initiates the opposite response when exposed to other immune cells. It is logical that LTA would have distinct effects on cytokine release depending on the cell type exposed. LTA acts as a proinflammatory factor for cells that normally exist in a sterile environment, such as macrophages (Supplementary Fig. 3b), monocytes and mast cells29,30. These cells are not normally exposed to the surface microbiome and appropriately recognize LTA as foreign. However, keratinocytes are unique in that they are frequently exposed to LTA. Furthermore, the structure of LTA seems to determine the nature of the keratinocyte response. Addition of D-alanine to the LTA core seemed to be a key factor in dictating activity, but further analysis is necessary to understand these LTA structure-function relationships. Moreover, other TLR2 ligands that depend on formation of a heterodimer with TLR1 or TLR6 do not inhibit TLR3 in keratinocytes but rather have a proinflammatory effect. Thus, the specificity of the response is dictated by cell type and the specific structure of the TLR2 ligand produced by the microbe. In particular, S. epidermidis, a normal inhabitant of the skin, may have a uniquely structured TLR2 ligand that maximizes anti-inflammatory action yet minimizes the capacity to initiate inflammation.
To limit TLR-induced inflammation, several negative regulatory systems exist, including sequestration of signaling molecules, blockade of their recruitment, degradation of target proteins and inhibition of transcription27,31. These negative regulators can be part of microbial virulence. Examples of TLR inhibition by microbes include decoy receptors in some bacterial infections that prevent a direct interaction between TLRs and their microbial ligands, and vaccinia virus production of several proteins that interfere with viral recognition through both TLR3 and helicases32,33,34. Therefore, there is potential for pathogenic staphylococci such as S. aureus to exploit suppression of keratinocyte activation as a mechanism of virulence, whereas S. epidermidis may benefit the host by dampening unwanted inflammation. This hypothesis requires further testing but is supported by the data we obtained from germ-free mice that shows such mice lack normal expression of Traf1 in the skin. These observations support additional findings that the ability of TLR2 to recognize commensal bacteria is not irrelevant under normal conditions. Rather, activation of TLR2 in keratinocytes has its own beneficial effect in maintaining homeostasis.
Taken together, these findings are best appreciated when one recognizes that inflammation is an undesirable condition on skin but is fundamentally a necessary protective response after injury. Prolonged and dysregulated production of inflammatory cytokines leads to excessive neutrophil influx, resulting in sustained inflammatory responses and poor healing, subsequently causing extensive tissue damage35,36. In contrast, without an appropriate inflammatory response, wound healing is also delayed, and the host is more susceptible to microbial invasion. Local modulation of the inflammatory response by products of bacterial commensals at the site of such an injury might be a beneficial therapeutic strategy for management of wound healing complicated by excessive inflammation or control of other inflammatory skin disorders. The trick will be to evoke a reduction in the detrimental aspects of inflammation without increasing the risk of wound infection. Our findings emphasize the potential benefit of the resident bacteria on skin and the potential negative consequences of complete depletion of microflora from skin by indiscriminate use of topical and systemic antibiotics.
Mice. We housed C57BL/6 wild-type, Tlr3-deficient, Myd88-deficient and Tlr2-deficient mice and BABL/c wild-type mice in the VA San Diego Healthcare System Veterinary Medical Unit, and we purchased Traf1-dificient mice from the Jackson Laboratory. We purchased Swiss-Webster conventional and germ-free mice from Taconic. All animal experiments were approved by the VA San Diego Healthcare System Institutional Animal Care and Use Committee.
Bacterial extracts preparation and lipoteichoic acid purification. We grew bacteria in tryptic soy broth at 37 °C for 15–16 h. For scale-up preparation, we diluted overnight cultures 1 in 100 into tryptic soy broth and grew them for another 15–16 h. We then collected bacterial cultures and filtered them by 0.22 μM Stericup (Millipore). We used the MacroSep 10K OMEGA column (VWR) to collect the <10-kDa fractions from bacterial supernatants and determined concentrations of bacterial extracts by BCA Protein Assay Kit (Pierce). We purified LTA from S. epidermidis conditioned culture medium by using a previously described protocol37.
Ultraviolet B–induced apoptosis and necrosis. We irradiated cultured human keratinocytes by UVB at 15 mJ cm−2 for 1 min. After 24 h, we collected the UVB-irradiated cells and sorted them into annexin V–positive, propidium iodide–negative cells and propidium iodide–positive cells. To stimulate TNF-α, we added these sorted UVR cells to untreated normal human keratinocytes in culture. We used sonicated nonirradiated cells (normal cells) as controls. We measured TNF-α in culture medium 24 h after treatment with these cells.
Lipoteichoic acid neutralization. We used 300 μg ml−1 of S. epidermidis LTA monoclonal antibody (Abcam) or monoclonal mouse IgG1 isotype control (clone PPV-06) (EXBIO, 11-457-C100) to incubate with 30 μg of the <10-kDa product of S. epidermidis for 20 h at 4 °C before we added the <10-kDa product of S. epidermidis to stimulate cells. After 24 h stimulation, we collected cell supernatants for TNF-α ELISA assay.
RNA interference. We seeded neonatal human epidermal keratinocytes at first or second passage in 24-well plates and transfected cells with 10 nM of four pairs of siRNA oligonucleotides targeted to TLR3 (Dharmacon; SMART Pool) and nontargeted control siRNA (Dharmacon) by using silentFect (BioRad), as we have described previously38. We tested the efficiency of TLR3 siRNA blockage by western blotting. After 24 h transfection, we added UVR cells to stimulate cells for 24 h. We evaluated the production of TNF-α by ELISA.
Caspase-8 inactivation. We applied 100 nM caspase-8 inhibitor (Z-IETD; R&D) 10 min before we added 10 μg ml−1 of poly(I:C) with or without 36 μg ml−1 of the <10-kDa product of S. epidermidis or 10 μg ml−1 of LTA in cultured human keratinocytes and waited for 6 h or 48 h. We analyzed the inhibition of TRAF1 processing by western blotting, and we measured the production of TNF-α by ELISA.
Immunoprecipitation and immunoblotting. We stimulated cultured human keratinocytes at the time points indicated in Figure 4a,c and Supplementary Figure 8b. We lysed cells by using RIPA buffer (50 mM Tris-HCl pH 7.4, 150 mM NaCl, 2 mM EDTA, 1% NP-40 and 0.1% SDS) containing protease inhibitor cocktail (Roche) and then sonicated them on ice-cold water. We measured protein concentrations of the extracts by BCA Protein Assay Kit (Pierce) and used 15 μg of total protein for immunoprecipitation and 3 μg of total protein for western blotting. We used SDS-PAGE to separate bands, and detected TRAF1 by immunoblotting with the antibody to TRAF1 (Santa Cruz, sc-983) or the association of TRAF1 and TRIF by immunoblotting with TRIF-specific antibody (Cell Signaling, 4596).
Cutaneous inflammation in vivo. We shaved the backs of age-matched adult littermates and removed hair by chemical depilation (Nair; Church & Dwight), as previously described39. We intradermally injected 100 μl of PBS or 100 μl of the <10-kDa product of S. epidermidis (24 μg) or 100 μl of LTA-SA (50 μg) 24 h and 2 h before wounding back skin of wild-type or Tlr3-deficient mice or Traf1-deficient mice by biopsy punches. Three days later, we collected 2 mm of skin around wound edges either for ELISA assay or stored it in formalin (Protocol) for H&E staining.
For cutaneous inflammation in ears, we injected 12 μg of the <10-kDa product of S. epidermidis or 10 μg of LTA-SA into the ear lobes of C57BL/6 wild-type (or BABL/c wild-type mice) and Tlr2-deficient mice 2 h before we injected 50 μg of poly(I:C) or 20 μg of LPS. After 24 h, we cut mouse ears to either store them in formalin for H&E staining or homogenize them for RNA isolation. We analyzed the expression of cytokines by real-time RT-PCR.
For PMA-induced skin inflammation, we injected 12 μg of the <10-kDa product of S. epidermidis into BALB/c wild-type mouse ear lobes 2 h before we topically treated mouse ears with 20 μl of 1mg ml−1 PMA (Sigma). After 6 h, we took ears for cytokines analysis.
Statistical analysis. All data are presented as means ± s.e.m. We used two-tailed t tests to determine significances between two groups. We did analyses of multiple groups by one-way or two-way ANOVA with Bonferroni's post test of GraphPad Prism Version 4. For all statistical tests, we considered P values <0.05 to be statistically significant.
Additional methods. Detailed methodology is described in the Supplementary Methods.
Rakoff-Nahoum, S., Paglino, J., Eslami-Varzaneh, F., Edberg, S. & Medzhitov, R. Recognition of commensal microflora by Toll-like receptors is required for intestinal homeostasis. Cell 118, 229–241 (2004).
Xu, J. et al. A genomic view of the human-Bacteroides thetaiotaomicron symbiosis. Science 299, 2074–2076 (2003).
Rakoff-Nahoum, S., Hao, L. & Medzhitov, R. Role of Toll-like receptors in spontaneous commensal-dependent colitis. Immunity 25, 319–329 (2006).
Netea, M.G., Van der Meer, J.W. & Kullberg, B.J. Toll-like receptors as an escape mechanism from the host defense. Trends Microbiol. 12, 484–488 (2004).
Kelly, D., Conway, S. & Aminov, R. Commensal gut bacteria: mechanisms of immune modulation. Trends Immunol. 26, 326–333 (2005).
Steidler, L. et al. Treatment of murine colitis by Lactococcus lactis secreting interleukin-10. Science 289, 1352–1355 (2000).
Vandenbroucke, K. et al. Active delivery of trefoil factors by genetically modified Lactococcus lactis prevents and heals acute colitis in mice. Gastroenterology 127, 502–513 (2004).
Haller, D. et al. Transforming growth factor-β1 inhibits nonpathogenic Gram negative bacteria–induced NF-κB recruitment to the interleukin-6 gene promoter in intestinal epithelial cells through modulation of histone acetylation. J. Biol. Chem. 278, 23851–23860 (2003).
Marshak-Rothstein, A. & Rifkin, I.R. Immunologically active autoantigens: the role of Toll-like receptors in the development of chronic inflammatory disease. Annu. Rev. Immunol. 25, 419–441 (2007).
Leadbetter, E.A. et al. Chromatin-IgG complexes activate B cells by dual engagement of IgM and Toll-like receptors. Nature 416, 603–607 (2002).
Matzinger, P. Tolerance, danger and the extended family. Annu. Rev. Immunol. 12, 991–1045 (1994).
Marshak-Rothstein, A. Toll-like receptors in systemic autoimmune disease. Nat. Rev. Immunol. 6, 823–835 (2006).
Ziebuhr, W. et al. Nosocomial infections by Staphylococcus epidermidis: how a commensal bacterium turns into a pathogen. Int. J. Antimicrob. Agents 28 Suppl 1, S14–S20 (2006).
Bibel, D.J. et al. Competitive adherence as a mechanism of bacterial interference. Can. J. Microbiol. 29, 700–703 (1983).
Lebre, M.C. et al. Human keratinocytes express functional Toll-like receptor 3, 4, 5, and 9. J. Invest. Dermatol. 127, 331–341 (2007).
Pivarcsi, A. et al. Expression and function of Toll-like receptors 2 and 4 in human keratinocytes. Int. Immunol. 15, 721–730 (2003).
Baker, B.S., Ovigne, J.M., Powles, A.V., Corcoran, S. & Fry, L. Normal keratinocytes express Toll-like receptors (TLRs) 1, 2 and 5: modulation of TLR expression in chronic plaque psoriasis. Br. J. Dermatol. 148, 670–679 (2003).
Alexopoulou, L., Holt, A.C., Medzhitov, R. & Flavell, R.A. Recognition of double-stranded RNA and activation of NF-κB by Toll-like receptor 3. Nature 413, 732–738 (2001).
Fujimoto, C., Nakagawa, Y., Ohara, K. & Takahashi, H. Polyriboinosinic polyribocytidylic acid [poly(I:C)]/TLR3 signaling allows class I processing of exogenous protein and induction of HIV-specific CD8+ cytotoxic T lymphocytes. Int. Immunol. 16, 55–63 (2004).
Cavassani, K.A. et al. TLR3 is an endogenous sensor of tissue necrosis during acute inflammatory events. J. Exp. Med. 205, 2609–2621 (2008).
Brown, D.L., Kao, W.W. & Greenhalgh, D.G. Apoptosis down-regulates inflammation under the advancing epithelial wound edge: delayed patterns in diabetes and improvement with topical growth factors. Surgery 121, 372–380 (1997).
Kono, H. & Rock, K.L. How dying cells alert the immune system to danger. Nat. Rev. Immunol. 8, 279–289 (2008).
Vanhoutte, F. et al. Toll-like receptor (TLR)2 and TLR3 synergy and cross-inhibition in murine myeloid dendritic cells. Immunol. Lett. 116, 86–94 (2008).
Ghosh, T.K. et al. TLR-TLR cross talk in human PBMC resulting in synergistic and antagonistic regulation of type-1 and 2 interferons, IL-12 and TNF-α. Int. Immunopharmacol. 7, 1111–1121 (2007).
Lambert, P.A., Worthington, T., Tebbs, S.E. & Elliott, T.S. Lipid S, a novel Staphylococcus epidermidis exocellular antigen with potential for the serodiagnosis of infections. FEMS Immunol. Med. Microbiol. 29, 195–202 (2000).
Weidenmaier, C. et al. Role of teichoic acids in Staphylococcus aureus nasal colonization, a major risk factor in nosocomial infections. Nat. Med. 10, 243–245 (2004).
Kawai, T. & Akira, S. TLR signaling. Semin. Immunol. 19, 24–32 (2007).
Hooper, L.V. Do symbiotic bacteria subvert host immunity? Nat. Rev. Microbiol. 7, 367–374 (2009).
Timmerman, C.P. et al. Induction of release of tumor necrosis factor from human monocytes by staphylococci and staphylococcal peptidoglycans. Infect. Immun. 61, 4167–4172 (1993).
Yoshioka, M. et al. Lipoteichoic acid downregulates FcεRI expression on human mast cells through Toll-like receptor 2. J. Allergy Clin. Immunol. 120, 452–461 (2007).
Han, J. & Ulevitch, R.J. Limiting inflammatory responses during activation of innate immunity. Nat. Immunol. 6, 1198–1205 (2005).
Stack, J. et al. Vaccinia virus protein A46R targets multiple Toll-like-interleukin-1 receptor adaptors and contributes to virulence. J. Exp. Med. 201, 1007–1018 (2005).
Harte, M.T. et al. The poxvirus protein A52R targets Toll-like receptor signaling complexes to suppress host defense. J. Exp. Med. 197, 343–351 (2003).
Thompson, A.J. & Locarnini, S.A. Toll-like receptors, RIG-I–like RNA helicases and the antiviral innate immune response. Immunol. Cell Biol. 85, 435–445 (2007).
Szpaderska, A.M. & DiPietro, L.A. Inflammation in surgical wound healing: friend or foe? Surgery 137, 571–573 (2005).
Wetzler, C., Kampfer, H., Stallmeyer, B., Pfeilschifter, J. & Frank, S. Large and sustained induction of chemokines during impaired wound healing in the genetically diabetic mouse: prolonged persistence of neutrophils and macrophages during the late phase of repair. J. Invest. Dermatol. 115, 245–253 (2000).
Gründling, A. & Schneewind, O. Synthesis of glycerol phosphate lipoteichoic acid in Staphylococcus aureus. Proc. Natl. Acad. Sci. USA 104, 8478–8483 (2007).
Schauber, J. et al. Histone acetylation in keratinocytes enables control of the expression of cathelicidin and CD14 by 1,25-dihydroxyvitamin D3 . J. Invest. Dermatol. 128, 816–824 (2007).
Nizet, V. et al. Innate antimicrobial peptide protects the skin from invasive bacterial infection. Nature 414, 454–457 (2001).
We thank A. Peschel for advice regarding blocking LTA activity by the antibody; E. Raz from the University of California–San Diego for providing a C57BL/6 Tlr3-deficient mouse breeding pair; V. Nizet and E. Tistiskov for helpful discussion; G. Cheng, B. Beutler, R. Modlin and E. Raz for critical reading and helpful advice; and D. Bird for histological sections. This work was supported by US National Institutes of Health grants R56AI083358, R01AR052728 and R01 AI052453 and a US Veterans Administration Merit Award to R.L.G. and US National Institutes of Health grants DC00129 and DC006279 to A.F.R.
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Lai, Y., Di Nardo, A., Nakatsuji, T. et al. Commensal bacteria regulate Toll-like receptor 3–dependent inflammation after skin injury. Nat Med 15, 1377–1382 (2009). https://doi.org/10.1038/nm.2062
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