C. trachomatis has a unique biphasic life cycle involving both elementary and reticulate bodies. Elementary bodies (EBs) represent a metabolically inactive infectious phenotype capable of attaching to epithelial cells with subsequent internalization resulting in the formation of an inclusion body. Once inside the inclusion, the EB differentiates into a metabolically active reticulate body (RB) that multiplies via binary fission. As the inclusion grows, the RBs reorganize into EBs that are released from the host cell and can infect adjacent cells. These varying bioforms make treatment of chlamydial infections difficult. Furthermore, antibiotic therapies, exposure to IFNγ, or nutrient deprivation can lead to an atypical, persistent, non-cultivable, and morphologically aberrant intracellular state (reviewed in [7]).

Chlamydial infections in the conjunctiva and genitalia can incite an intense inflammatory response that, if chronic, can lead to scarring and fibrosis. Numerous pro-inflammatory cytokines, including TNFα, IL-1α, IL-6 and IL-18 [8,9], as well as a group of chemokines [8,10,11] responsible for the recruitment of leukocytes have been shown to be secreted from C. trachomatis-infected epithelial cells. This arsenal of cytokines and chemokines with incoming leukocytes results in the stimulation of both cellular- and humoral-mediated immune defenses. The type of host inflammatory response that is initiated with the infection determines the outcome of the infection. The current hypothesis is that resolution is mediated primarily by a dominant cell-mediated Th1 response, whereas chronic inflammation with subsequent scarring ensues if either the humoral Th2 response or regulatory T cells predominate (reviewed in [5]).

Development of chronic chlamydial infections is believed to arise as a result of immunopathology. This has been demonstrated by persistent elevation of pro-inflammatory cytokines like IL-6 among infertile women [12] and in tear fluid from post-scarring trachoma populations [13]. One study identified IL-6 secretion via the TLR2 signaling pathway after C. trachomatis infections [14]. This TLR2 pathway has been shown to be associated with fallopian-tube pathology, potentially contributing to the immunopathogenesis associated with C. trachomatis infection [14]. The chemokine monocyte chemoattractant protein-1 (CCL2) has also been identified in chronic chlamydial infections demonstrating elevated levels in post-scarring trachoma populations [13].

Due to the high prevalence of worldwide trachoma, the World Health Organization (WHO) established and supports the use of the SAFE (surgery, antibiotics, facial cleanliness, and environmental improvements) strategy to reduce disease transmission in endemic areas. Mass antibiotic therapy has been a mainstay in this program resulting in diminished prevalence of active chlamydial infections [15-17]. However, heightened recurrence rates of infection 6-24months after termination of antibiotic therapy were evident in multiple studies [18-21]. Additionally, Burnham et al. saw an increase in chlamydia-associated STI Reinfection after a control program with antibiotic treatment was established [22]. The mass administration of antibiotics may lead to the development of antibiotic resistance in chlamydial species as well as other pathogenic bacteria. It is apparent that research into alternative treatments is warranted, and the use of phototherapy may be an attractive option.

Phototherapy utilizing low power lasers or light emitting diodes (LEDs) has been shown to reduce pain and chronic inflammation, and to promote tissue regeneration via a photochemical mechanisms (reviewed in [23]). Additionally, anti-bacterial effects due to the increased production of reactive oxygen species resulting in membrane instability and DNA damage have been evident with phototherapy [23-27]. Its use with several discrete wavelengths exhibits anti-bacterial activity requiring short treatment times without inducing anti-bacterial resistance subsequent to multiple treatment sessions [28].

One potential alternative treatment utilizing 405nm irradiation was evaluated in this study and demonstrated photo inactivation of C. trachomatis during active and persistent states. Small dosages starting at 5J/cm² had a significant growth inhibiting effect, with increasing energy densities positively correlating with growth inhibition. Therapeutic utility and clinical safety have been described using LED phototherapy at 405nm against acne vulgaris [35] and gastric Helicobacter pylori infections, with the latter applied to the gastrointestinal mucosa via a light wand [36]. In vitro anti-bacterial activity of 405nm irradiation has been demonstrated against multiple medically relevant Gram-positive and Gram-negative extracellular pathogens like Staphylococcus aureus (including methicillin-resistant strains, MRSA), Streptococcus pyogenes, Pseudomonas aeruginosa, Clostridium perfringens, Campylobacter jejuni, Salmonella enteritidis and Escherichia coli[24,37]. Overall Gram-negative bacteria appear more resistant to 405nm irradiation than Gram-positive, with the exception of Enterococcus faecalis. The majority of Gram-positive bacteria appeared to require less than 11J/cm² for a log₁₀ reduction in colony forming units, whereas Gram-negative bacteriocidal effects were apparent between 25 and 96J/cm²[24]. The portable LEDs used in this study were battery operated with 88second dosing times, therefore making it difficult to obtain higher energy densities. Comparing the log₁₀ reduction levels of other Gram negative bacteria with C. trachomatis is difficult due to its intracellular nature and considering it may exist as two-uncultivable life cycle forms: RBs and aberrant persistent forms. After irradiation with an energy density of 20J/cm² we demonstrated a nearly 70% reduction in chlamydial growth, reflecting levels similar to other Gram-negative bacteria. To our knowledge, this is the first data demonstrating chlamydial growth inhibition caused by 405nm irradiation.

Photo inactivation by 405nm irradiation is believed to be caused by excitation of androgenic porphyrins, resulting in oxygen free radical production and subsequent bacterial membrane disruption [38]. Endogenously produced porphyrins, like coproporphyrin, uroporphyrins, and protoporphyrin IX, have been shown to be produced by both Gram positive and negative bacteria [25,39] though, to our knowledge, porphyrin production by C. trachomatis has not yet been demonstrated. Considering the intracellular nature of C. trachomatis, a second photo inactivation mechanism might be associated with altered expression of eukaryotic proteins in response to 405nm irradiation. Boncompain et al. demonstrated a transient upregulation of reactive oxygen species within C. trachomatis-infected HeLa cells for approximately six hours after infection, with subsequent basal levels ensuing nine hours post-infection. The regulation of reactive oxygen species appears to be mediated by C. trachomatis sequestration of the NADPH oxidase subunit, Rac1, to the inclusion membrane [40]. Considering the significant growth inhibition effect when 405nm was applied promptly two hours post-infection rather than 24h, the irradiation might have altered chlamydial protein expression thus influencing its ability to sequester host Rac1, thereby increasing reactive oxygen species within the epithelial cells. An alteration in protein expression may have also delayed the formation and secretion of bacterial type III effector proteins, such as CPAF, that have previously been shown to be involved in binding and degrading eukaryotic proteins like cytokeratin 8, adhesion protein nectin-1, host transcription factor RFX5, and multiple host pro-apoptotic BH3 proteins [41-44]. Alternatively, the lack of 405nm photo inactivation effect on chlamydial growth at 24h post-infection might be due to the exponentially higher bacterial burdens within the inclusion body 24h post-infection relative to two hours post-infection, potentially causing the differences after treatment to be less pronounced. It is also possible that multiple mechanisms co-exist and provide a cumulative anti-proliferative effect on C. trachomatis, though further studies are warranted.

The immunopathologic sequelae from conjunctival and genital chlamydial infections are likely mediated through the secretion of a group of pro-inflammatory cytokines. In trachoma, we demonstrated elevated levels of IL-6 during both acute and chronic grades of infection, with detectable chlamydial cases exhibiting more pronounced concentrations [13]. The role of IL-6 in immunopathologenesis was also evident in women with ectopic pregnancies [45] and positively correlated with antibody titers against Chlamydophila pneumoniae amongst atherosclerotic patients [46]. In an attempt to mimic chronic chlamydial infections, Macaca nemestrina fallopian tubes received repeated C. trachomatis infections, which resulted in fibrosis and elevated IL-6, IL-10, IL-2, and IFNγ levels [47]. In TLR2 -/- KO mice infected with mouse pneumonitis (MoPn), decreased fibrosis and inflammation with in oviducts and mesosalpinx correlated with abated IL-6 concentrations [14]. To determine the immunologic correlation of persistence in vitro with clinical presentation, we quantified IL-6 in penicillin-induced C. trachomatis persistent infections in HeLa cells. We demonstrated similar increases in IL-6 production in persistent infections compared to active infections in vitro. A previous study looked at persistent infections with C. pneumoniae in the presence of iron-depletion, IFNγ and penicillin, and demonstrated slightly diminished production of IL-6 after 24h and 48h [48]. However, multiple experimental differences between these studies, including the use of different chlamydial species, might provide an explanation for the differences in results. For example, Peters et al. added penicillin 30min after infection, followed by daily media change. This is in contrast to our study which added penicillin 24h post-infection without a daily media change. Wang et al. provided more molecular details of this persistent state, demonstrating attenuated production of secreted chlamydial proteins from ampicillin-induced persistence of C. trachomatis infected HeLa cells [49], suggesting that secreted type III effector proteins like CPAF [42], Tarp [50], CT311 [51], and CT795 [52] may be involved in regulating IL-6 levels. We are unaware of any other studies that examine inflammatory differences associated with penicillin-induced persistence. The elevation of IL-6 after penicillin-induced persistence supports the importance of this model in elucidating other inflammatory mediators that may be associated with chronic infections in vivo. Further research on molecular characterizations and their immunostimulatory properties is needed to understand this in vitro antibiotic-induced persistent model.

Considering the immunopathologic response to chronic chlamydial infections, we were interested in determining the role of 405nm irradiation on cytokines previously associated with immunopathogenesis. In our study, irradiation with 405nm had a dose-dependent effect on IL-6 production with 20J/cm² causing a 64% reduction. However, this effect was most likely associated with a decreased bacterial burden since previous studies demonstrated elevated IL-6 from UV-A (340-450nm) exposed fibroblasts [53,54] and minimal effects of UV-A (1J/cm²) treated keratinocytes on IL-6 production [55]. Interestingly, attenuation of IL-6 after 405nm treatment was only evident if 405nm irradiation was applied promptly after infection; the effect was lost if applied 24h post-infection. We believe that at this later time point, multiple chlamydial proteins were already secreted by type III secretory pathways into the host cytoplasm and interacted with pattern recognition receptors (PRRs) resulting in IL-6 production.