Clinically, the integrity of the oral epithelial barrier is of utmost importance as it offers protection to the underlying connective tissue, which is more sensitive to environmental damage and bacterial invasion [2–4, 6]. The loss of integrity of the epithelial cell layer caused by a catabolic inflammatory environment, bacterial proteases, or mechanical damage is associated with inflammatory responses of the underlying connective tissue, which is mainly consisted of gingival fibroblasts but also immune cells, including macrophages [5–7]. However, whether and how the damage of oral epithelial cells signals the demand for a local repair by initiating an inflammatory response of the adjacent connective tissue remains largely unknown. In this study, we report that the lysates obtained upon sonication or freeze/thawing of oral squamous cell carcinoma cells provoked a robust increase in the expression of interleukins IL1, IL6, and IL8 by gingival fibroblasts, which was confirmed by immunoassays of IL6. Conversely, lysates obtained from the gingival fibroblasts failed to increase the expression of interleukins in oral squamous cell carcinoma cells. Additionally, the epithelial cell lysates caused the activation of the NF-kB signalling cascade in gingival fibroblasts as indicated by the nuclear translocation of p65, suggesting inflammation. Finally, we demonstrated that the epithelial cell lysates can adhere to the titanium and particularly to collagen membrane surfaces indicated by the IL8 expression of gingival fibroblasts.
Clinically, dying cells may represent a threat to the body, for instance, in an evolving cancer that may be eliminated by the host immune response [21]. On the other hand, the inflammatory response may counteract certain pathological processes; for example, in an ischemic infarct, where inflammation-induced vasodilatation may help perfuse adjacent ischemic areas [22, 23]. In other forms of injury, increased blood flow and fluid leakage may help dilute and drain away soluble injurious agents or the cellular response may encase offending particulate material, e.g. in a granuloma [22]. Thus, even in these non-bacterial situations, the inflammatory response may still be playing a defensive role and limit further damage to the host [22]. However, the inflammatory response, although beneficial in most cases, may impair the host tissues, especially when chronic. This may happen in cases of continuing mechanical damage to tissues.
The reduced inflammatory response of epithelial cells challenged by gingival fibroblast lysates is evidence of the resistance of epithelial cells against external dangers and further confirmation of their protective function. Similar to our finding, cell-penetrating peptides (CPP) failed to activate NF-κB and no significant increase in the release of the IL6 and IL8 was detected in epithelial cells exposed to these CPP complexes [24]. Nevertheless, Lysate 2 provoked moderate toxicity by reaching about 50% reduced cell viability. This means that the gingival necrotic cells were able to reduce the epithelial cell viability but failed to provoke an inflammatory response. This could be related to the potential of these lysates to affect the epithelial barrier by modifying the expression and integrity of the different cell-cell junctions [6]. To sustain their function, the stratified epithelia of the oral mucosa have to sustain tight cell-cell adhesion in the viable cells that involve intercellular tight and adherent junctions which connect to the actin cytoskeleton [6]. While we focused on the inflammatory response, further studies could then report on the expression of these adhesion molecules under the challenge of necrotic cell lysates.
Primary inflammatory stimuli, including microbial products and cytokines such as IL1β, IL6, and TNFα, mediate inflammation through interaction with receptors, e.g. the TLRs and IL1 receptor (IL1R) [25, 26]. Receptor activation triggers important intracellular signalling pathways, including the nuclear factor kappa-B (NF-κB) signalling [25]. NF-kB controls the expression of the molecules needed for acute inflammation, especially the pro-inflammatory cytokines tested herein, i.e., IL1, IL6, and IL8 [22]. However, blocking of interleukin-1 receptor-associated-kinase-1/4 inhibitor and the TLR4 inhibitor TAK-242 could not reduce the inflammatory activity of the HSC2 cell lysates. Together with our observations that HGF and HSC2 lysates failed to cause inflammation in RAW 264.7 macrophages (data not shown), these data suggest that pathways of inflammation are not causes by HSC2-derived IL1 or any LPS-related contamination of the lysates. Nevertheless, future studies could consider other TLRs, such as TLR2 or TLR9, that can activate NF-kB signalling [22]. The use of TLR2 or TLR9 antagonists such as MMG-11 [27] and inhibitory oligonucleotides (ODN) [28], respectively, could prove this potential involvement. Thus, we could not explain what pro-inflammatory molecules the epithelial cells release and what receptor-mediated signalling pathway fibroblasts use to drive the inflammatory response.
Antioxidant defence systems, including antioxidant enzymes, influence the oxidative stress [25]. Elevated oxidative stress can produce reactive oxygen species (ROS) [25]. Herein, we checked the ROS release for the gingival fibroblasts stimulated with the HSC2 lysates; however, the stimulation did not lead to ROS release (data not shown). Likewise, we hypothesised if the HSC2 cell lysates could activate the NLRP3 inflammasome, which is related to a potent inflammatory response due to the maturation and release of IL1β and IL18 [16, 20, 29]. The NLRP3 activation is closely related to the activation of Caspases, especially Caspases-1 and − 11, which in turn will cleave the membrane pore-forming molecule known as Gasdermin D, in a cascade process called pyroptosis [29, 30]. It is the Gasdermin D that produces pores into the cell membrane that will allow the release of the IL1β and IL18 that were maturated due to the action of the above-mentioned caspases [29, 30]. Nonetheless, the HSC2 lysates failed to increase the expression of NLRP3 and the related genes, namely Caspase-1, Caspase-11, Gasdermin D, and IL18 in gingival fibroblasts (data not shown). Therefore, the hypothesis for pyroptosis signalling involvement can be rebutted.
The use of titanium and collagen membranes was proposed to add to the clinical relevance of this in vitro study since these materials are used in implant dentistry surgical procedures, when cells are largely damaged. We showed that necrotic epithelial cell lysates produced by sonication could attach to the surfaces and provoke the release of IL8 by gingival fibroblasts. This can be extended to dental surfaces, where we know that virulence factors can adhere to and provoke inflammation [31]. Therefore, the overall recommendation is to avoid as much as possible the injuries of the oral epithelium as cell fragments can adhere to surfaces and cause an inflammatory reaction. Minimal invasive approaches such as flapless surgeries and guided surgeries help to reduce tissue damage and prevent further inflammatory triggering.
This study has all the limitations of an in vitro study. The main restraint is the translation of the outcomes to the clinical relevance. Nevertheless, our hypothesis that injured epithelial cells or fragments impairs gingival fibroblasts seems to be tangible considering the continuously mechanical challenges affecting the oral mucosa. Impressively, as far as we know, no one tested this setting before, which opens a path for further in vivo research. However, the better establishment of the in vitro outcomes should be consolidated before moving to translational research. In this sense, as previously mentioned, future in vitro studies could thus consider other TLR antagonists to confirm the likelihood of the NF-kB signalling involvement of the present model. Additionally, MAPK and JAK-STAT pathways for inflammation could be also assessed. Moreover, in-depth analyses to verify what are the active contents released by the disrupted necrotic cells would give insights into the downstream inflammatory response generated by challenging healthy cells with necrotic cells. In addition, how the lysates attach to surfaces should be addressed in further research. Furthermore, the application of other cell lines, in particular inflammatory cell lineages such as macrophages and monocytes, must be considered. Although this study has limitations, the suggestions for future studies are exciting as the results may lead to contributions to the knowledge of the pathobiology of the mechanical damage, i.e. aseptic inflammation, caused by mastication or iatrogenic damage.
In summary, at sites of tissue injury, damaged epithelial cells release factors that trigger the inflammatory cascade, along with chemokines and growth factors, which attract neutrophils and monocytes [25]. The release of interleukins and chemokines by gingival fibroblasts is evidence that they become inflammatory cells in response to external dangers, in the present case, in response to epithelial necrotic cells. Therefore, the overall main conclusion we may draw from this in vitro research is that injured oral epithelial cells can release factors that incite gingival fibroblasts to become pro-inflammatory cells.