In this study, we describe the involvement of both Th17-related and B cell-related immune responses in patients with LNB, i.e., beyond the previously well-described Th1- and Th2-associated immune responses. Our prospective and well-characterized patient cohort with standardized clinical follow-up visits and a second LP provides insights into the kinetics of cytokine and chemokine expression in the CSF and their significance for the disease course.
Half of the patients with LNB had a prolonged recovery period (> 6 months), which was dominated by symptoms such as facial palsy, radiculitis, myalgia and arthralgia, i.e. well-known residual symptoms as presented in the systematic review of Dersch et al [2]. We found, not only the presence of Th17-related cytokines and chemokines in the CSF samples of patients with LNB, in similarity to previous studies [7, 13, 20–23], but also increased baseline levels of IL-17A, CXCL1 and CCL20, as compared with the controls. In contrast to most other cytokines and chemokines that showed decreased levels at the 1-month follow-up, IL-17A was distinguished by sustained high levels in the patients compared with the controls. Moreover, Th17-associated IL-17A and CCL20 were the only cytokines/chemokines that were associated with time of recovery; the levels of IL-17A at the 1-month follow-up were higher in patients with a delayed (> 6 months) recovery and lower levels of the Th17-induced chemokine CCL20 were associated with a short time to recovery (< 1 month). Interestingly, the Th17 type of immunity has been implicated in other neuroinflammatory conditions, such as multiple sclerosis (MS) and its experimental animal model of autoimmune encephalomyelitis (EAE) [24]. In EAE, Th17 cells are important drivers of CNS inflammation through its signature cytokine IL-17A [11]. In addition, the Th17-recruiting chemokine CCL20 is expressed in the choroid plexus and, thus attracts Th17 cells to the CNS by binding its receptor CCR6, which is expressed on Th17 cells [24]. In LNB, increased CSF levels of IL-17A have previously been described [7, 20]. Henningsson et al. [7] found increased CSF levels of IL-17A in half of the investigated patients with confirmed LNB in a retrospective cohort. Furthermore a high percentage of these patients reported fatigue, although no correlations were noted between the baseline level of IL-17A and the duration of symptoms. In line with our findings, Pietikäinen et al. [22] have reported significantly increased levels of CXCL1 and IL-17 in the CSF both before and after treatment in 23 patients with LNB, as compared to non-LNB controls; however, that study did not include information on disease course. In another study [25], factors associated with a subclinical course of Borrelia exposure were investigated in asymptomatic, seropositive individuals compared to symptomatic individuals who had been previously diagnosed with LNB. The main factors linked to a subclinical course included lower levels of secretion of IL-17A and CCL20 by Borrelia-stimulated mononuclear cells. Thus, a propensity for a restricted Th17 response may contribute to a subclinical course after Borrelia exposure, which is in line with our finding that an uncontrolled Th17 response may instead contribute to a delayed disease course in LNB. Based on the aggregated findings from previous studies and our present study, we hypothesize that IL-17A and CCL20 are useful as prognostic markers of disease course in patients with LNB post-treatment. We therefore suggest that a second LP should be considered for patients with residual symptoms, in order to assess ongoing Th17-driven inflammation. Even though our findings need to be confirmed in larger studies, they lend support to the notion that Th17 inflammation contributes to persisting symptoms after treatment. Therefore, new treatment strategies involving Th17 downregulation are of interest. Several drugs that contain IL-17A inhibitors are increasingly used to inhibit Th17-driven inflammation in psoriasis [26], although the CCR6-CCL20 axis is considered to be a pharmaceutical target also in several other inflammatory conditions [27]. Speculatively, Th17 inhibition could be a possible treatment option also for patients with LNB, by improving the convalescence of patients with symptoms that persist after treatment.
In addition to IL-17A, we found increased levels of the Th1-associated chemokine CXCL10 in the CSF of patients with LNB at baseline, in accordance with the results reported in other studies for both adults [4, 7, 22, 28, 29] and in children [30, 31], and the levels were significantly reduced at follow-up. However, we did not find any association between CXCL10 and disease course, as has been reported in other studies [7, 29]. Indeed, in our small study, we identified that the two patients who had the highest levels of CXCL10 post-treatment showed a high degree of inflammation, as evidenced by higher CSF cell counts, higher albumin ratio, and increased total IgG index. In addition, one of these patients had a longer period of convalescence (> 12 months). Thus, it is possible that a larger study would link Th1-associated inflammation with disease course, while in the present study with a smaller sample size, Th17-associated inflammation emerged as having the strongest association with the course of LNB.
Regarding the Th2-related chemokine CCL22, higher CSF levels were found in the CSF samples of patients, as compared with the controls, in accordance with previous findings [7, 31]. However, we did not detect any associations between CCL22 and disease course. CCL22 is primarily produced by macrophages that are polarized towards an anti-inflammatory response [9]. CCL22 may have dual roles in LNB; acting as an anti-inflammatory agent that stimulates different mechanisms of healing [32] and as an inflammatory mediator, as seen in EAE [9]. Thus, the relationship between CCL22 and clinical outcome in patients with LNB is still unclear.
Our study confirms previous findings of increased levels of the B cell-associated cytokines APRIL and BAFF in the CSF samples of patients with LNB [13, 14], although we could not relate these cytokine levels to clinical disease course, as shown previously in a retrospective cohort of patients with LNB [13]. It is possible that the association is time-dependent, since our study had no follow-up visits between 1 and 6 months post-treatment. The CSF levels of APRIL were significant higher in the controls than in the patients with LNB, both at baseline and at follow-up. This is somewhat surprising, since the findings contradict the results of the analyses of APRIL levels in our previous study [13], obtained using the same laboratory method. As a consequence, these results are difficult to interpret. The median age of the controls differed significantly between the present study and our previous study, which might explain the discrepant results. Interestingly, we observed significantly higher levels of BAFF in the patients with radiculitis, possibly reflecting a higher B-cell activity associated with this symptom, as has also been shown by Ogrinc et al. [28].
As many previous studies have highlighted before, the chemokine CXCL13 remains a reliable biomarker for differentiating LNB from many other neuroinflammatory conditions [14]. However, we could not relate CXCL13 to disease course, possibly indicating the impacts of other types of immune responses in the later stages of LNB. Senel et al. [33] studied CXCL13 in the CSF samples of patients with LNB both before and after treatment; in line with our findings, the authors could not relate CXCL13 to disease course. In a recent study of 26 patients with bacterial or viral infections of the CNS [34], not including LNB, increased levels of CXCL13 in the CSF samples of patients with a complicated disease course were observed. Although CXCL13 is a well-studied chemokine in the CSF of patients with different neuroinfectious and neuroinflammatory conditions, its potential role as a prognostic marker in patients with LNB needs to be studied further.
A limitation of the present study is the limited number of included patients. Nonetheless, the study is prospective and includes a follow-up LP after 1-month, as well as a standardized protocol for clinical follow-up during 1 year. Since cytokines and chemokines were not analyzed in serum samples, we cannot determine whether the increased levels in the CSF were the result of a systemic inflammation rather than a localized neuroinflammation, especially in the patients with a disrupted blood-brain barrier. However, several studies have clearly demonstrated compartmentalization of the inflammatory response to the CNS in patients with LNB, and almost no systemic inflammation has been observed in these patients [7, 13, 20, 21, 23, 29, 30, 33]. Thus, the recorded inflammation in the CSF is very likely the result of an intrathecal inflammatory process. Additional strengths of this study are; the inclusion of a control group consisting of relatively healthy patients; investigations conducted with several PCR measurements, in order to avoid interference from other tick-borne infections; and the possibility to use the sensitive PEA methodology, which allowed for robust detection of the low-abundance proteins IL-17A and CCL20.
To summarize, in this prospective follow-up study of patients with LNB, we show that slow recovery after antibiotic treatment is associated with higher CSF levels of IL-17A and CCL20. These findings suggest IL-17A and CCL20 as prognostic markers and Th17-related immunity as a potential therapeutic target for patients with LNB, who show delayed post-treatment recovery due to a persisting intrathecal Th17-driven inflammation.