Regulatory impairment in untreated Parkinson’s disease is not restricted to Tregs: other regulatory populations are also involved
Parkinson’s disease (PD) is the second most common neurodegenerative disease in the world. Various studies have suggested that the immune response plays a key role in this pathology. While a predominantly pro-inflammatory peripheral immune response has been reported in treated and untreated PD patients, the study of the role of the regulatory immune response has been restricted to regulatory T cells. Other immune suppressive populations have been described recently, but their role in PD is still unknown. This study was designed to analyze the pro and anti-inflammatory immune response in untreated PD patients, with emphasis on the regulatory response.
Thirty-two PD untreated patients and 20 healthy individuals were included in this study. Peripheral regulatory cells (CD4+Tregs, Bregs, CD8+Tregs, and tolerogenic dendritic cells), pro-inflammatory cells (Th1, Th2, and Th17 cells; active dendritic cells), and classical, intermediate, and non-classical monocytes were characterized by flow cytometry. Plasmatic levels of TNF-α, IFN-γ, IL-6, GM-CSF, IL-12p70, IL-4, IL-13, IL-17α, IL-1β, IL-10, TGF-β, and IL-35 were determined by ELISA.
Decreased levels of suppressor Tregs, active Tregs, Tr1 cells, IL-10-producer CD8regs, and tolerogenic PD-L1+ dendritic cells were observed. With respect to the pro-inflammatory response, a decrease in IL-17-α and an increase in IL-13 levels were observed.
A decrease in the levels of regulatory cell subpopulations in untreated PD patients is reported for the first time in this work. These results suggest that PD patients may exhibit a deficient suppression of the pro-inflammatory response, which could contribute to the pathophysiology of the disease.
KeywordsParkinson’s disease Untreated patients Tregs Bregs CD8regs Peripheral immune response
- APC Cy7
- APC H7
Regulatory B cells
Regulatory CD8 T cells
Clínica de Investigación en Enfermedades Infecciosas
Central nervous system
Enzyme-linked immunosorbent assay
Erythrocyte sedimentation rate
Granulocyte-macrophage colony-stimulating factor
Hoehn and Yahr
Human leukocyte antigen complex
Immunoglobulin-like transcript 3
Instituto Nacional de Neurología y Neurocirugía
Inducible regulatory T cells
Mitogen-activated protein kinase
Nuclear factor-kappa B
Peripheral blood mononuclear cells
Phosphate buffer solution
Programmed death-ligand 1
- PerCP Cy5.5
Peridinin-chlorophyll proteins complex-cyanine 5.5
- PerCP eFluor 710
Peridinin chlorophyll proteins complex-eFluor 710
Signaling lymphocytic activation molecule
Transforming growth factor beta
Tumor necrosis factor alpha
Type-1 regulatory T cells
Regulatory T cells
- UK PDSBB
United Kingdom Parkinson’s Disease Society Brain Bank
Unified Parkinson’s disease rating scale
Parkinson’s disease (PD) is a neurodegenerative disorder characterized by bradykinesia, rigidity, and rest tremor. In the most severe cases, it results in a total inability to move . PD is the second most common neurodegenerative syndrome after Alzheimer’s disease, affecting 1–2% of the population over 60 years old. A recent meta-analysis on 47 global epidemiological studies conducted between 1985 and 2010 showed that the prevalence of PD increases with age, with a rate of 41 per 100,000 inhabitants in the 40–49-year-old group; 107 in the 50–59-year-old group; 173 in the 55–64-year-old group; 428 in the 60–69-year-old group; 425 in the 65–74-year-old group; 1087 in the 70–79-year-old group; and 1903 in subjects older than 80 years .
The progressive degeneration of dopaminergic neurons in PD has been linked to different mechanisms, including α-synuclein aggregation, oxidative stress, mitochondrial and proteasome ubiquitin dysfunction, apoptosis, and neuroinflammation. Recently, a connection between the central nervous system (CNS) and the peripheral immune system has been reported in mice and humans [3, 4]; a lymphatic vessel network in the dura mater collects cerebrospinal fluid (CSF) and interstitial fluid from the subarachnoid space and brain parenchyma. Dural lymphatic vessels transport fluids and cells to deep cervical lymphatic nodes. This connection stresses the need of studying the role of the peripheral immune system in neurological diseases. CNS alterations observed in PD could lead to changes in the periphery. Several studies have reported a decrease in CD3+, CD4+, CD19+, activated T cells (CD4+CD25+), CD4+ T cells, effector cells (CD31+CD4+), regulatory T cells (Tregs) (CD4+CD25hi and CD3+CD4+CD25hiCD127dim), myeloid dendritic cells (DC) (CD11c+human leukocyte antigen complex+ [HLA-DR]), and T helper (Th) cells (Th2 and Th1) in the peripheral blood [5, 6, 7, 8, 9, 10, 11]. Other reports showed an increase in CD4−CD8+ cells, memory cells (CD45RO+CD95+CD4+), natural killers (NKs), monocyte precursor cells, and classical monocytes, as well as in Th1 and Th17 cells [6, 7, 8, 10, 12, 13].
Other studies have reported peripheral alterations in cytokine levels, namely increased levels of the tumor necrosis factor alpha (TNF-α), interleukin- (IL-) 1β, IL-2, and IL-10 [14, 15, 16, 17] and decreased levels of IL-4, IL-6, IL-10, TNF, interferon gamma (IFN-γ), and IL-17α [5, 6, 14]. Conflicting results on the levels of some molecules and immune populations have been reported, possibly due to differences in treatment and in the clinical status of the subjects included [5, 6, 8, 10, 18, 19]. Few studies have described the immune response in untreated patients [18, 20, 21, 22].
Altogether, these findings suggest that the peripheral pro-inflammatory immune response has an important role in the progression of PD. In fact, both the levels of cytokines and of immune cells are related to symptom worsening, as reflected in clinical scales like the Hoehn & Yahr (H&Y) scale and the Unified Parkinson’s Disease Rating Scale (UPDRS) [10, 23]. This persistent inflammation in PD patients may be suppressed by regulatory cell populations. However, there are few studies about the immunomodulatory response in PD patients.
With respect to the suppression of the immune response, only a regulatory response mediated by T-CD4 regulatory cells has been reported in PD. While some reports have described a decline in Tregs populations, other studies reported no changes. Cells with the phenotype CD4+CD25+, CD4+CD25hi, CD4+CD25+FOXP3+, CD4+CD25+CD127−, and CD3+CD4+CD25hiCD127dim have been labeled as Tregs [5, 6, 7, 8, 10]. In addition, experimental data from murine PD models support the role of Tregs in neuroprotection .
Other regulatory populations, like regulatory B cells (Bregs), CD8 regulatory T cells (CD8regs), and plasmatic cells, can also produce IL-10 and have suppressive actions [25, 26, 27]. In addition, tolerogenic DCs induce, convert, or expand Tregs . However, no study has described yet the role of these regulatory populations in PD.
Monocytes can be categorized as classical, intermediate, and non-classical according to their expression of CD14 and CD16, exhibiting pro-inflammatory properties in a higher or lesser degree and even anti-inflammatory traits . No study has analyzed yet the role of these monocyte populations in PD.
Thus, considering the possible relevance of inflammation in the pathogenesis of PD, the anti- and pro-inflammatory immune response in untreated PD patients was analyzed in this work, with emphasis on the regulatory response.
Material and methods
Thirty-two patients with no previous dopaminergic treatment and 22 healthy subjects (controls) were included in this study. All patients attended the Instituto Nacional de Neurología y Neurocirugía (INNN) and agreed to participate in this study by signing an informed consent letter. The protocol was approved by the INNN Ethics Committee (permit No. 95/14) and was conducted in accordance with the Helsinki Declaration. All diagnoses were performed by an expert neurologist at the INNN, following the United Kingdom Parkinson’s Disease Society Brain Bank (UK PDSBB) diagnosis criteria. The UPDRS and H&Y scales, as well as the Schwab & England and Beck depression questionnaires, were applied to comprehensively evaluate the patients’ clinical status and state of mind.
Twenty milliliters of peripheral blood were collected from each patient and control subject in tubes containing acid-citrate-dextrose (ACD) (Vacutainer ACD, BD Franklin Lakes, NJ, USA). Blood samples were centrifuged to separate the plasma, and the cells were resuspended in sterile phosphate buffer solution (PBS) 1×. The samples were diluted 1:1 with sterile PBS 1×. Peripheral blood mononuclear cells (PBMCs) were separated by density gradient using Ficoll-Hypaque (Sigma Aldrich, Little Chalfont, UK). The samples were centrifuged for 30 min at 1800 rpm, without brake. Subsequently, the PBMCs were separated and washed with PBS 1× twice, centrifuging for 10 min at 1600 rpm. Finally, the cells were resuspended in 1 mL of 1× PBS and counted in a Neubauer chamber using Trypan Blue stain. Only samples with at least 95% of cellular viability were used to characterize cellular phenotypes by flow cytometry.
Cell population labeling for flow cytometry analysis
For each phenotype and isotype, 106 PBMCs in a total volume of 50 μL were stained and analyzed. For intracellular labeling, PBMCs were incubated with brefeldin (10 μg/mL) for 4 h at 37 °C and 5% CO2 before labeling. Cytokine production was assayed in unstimulated PBMCs, since it has been reported that cytokine induction heavily depends on the stimulus used ; additionally, the analysis of unstimulated PBMCs has been reported previously [31, 32, 33]. Thus, only spontaneous cytokine production was considered in this study. Thereafter, antibodies for extracellular labeling were added and incubated for 30 min at 4 °C. PBMCs were washed with PBS supplemented with bovine serum albumin 5% and fetal bovine serum 1%. Then, PBMCs were permeabilized by adding 300 μL of fixation and permeabilization buffers (eBioscience, Waltham, MA, USA). PBMCs were then incubated at 4 °C for 2 h, washed with permeabilization buffer (eBioscience), blocked with 20 μL of 10% rat serum solution, and incubated again for 1 h at 4 °C. Intracellular antibodies were added with no previous wash, and PBMCs were incubated for 30 min at 4 °C. Finally, PBMCs were washed with permeabilization buffer and fixed with 200 μL of 2% paraformaldehyde.
Cell phenotype antibodies. CD4 regulatory T cells: CD127 fluorescein isothiocyanate (FITC)a (isotype mouse IgG1k FITC), FOXP3 phycoerythrin (PE)a* (isotype rat IgG2ak PE), IL-10 PEa* (isotype rat IgG2ak PE), CD45RO Peridinin-chlorophyll protein complex-cyanine 5.5 (PerCP Cy5.5)c (isotype mouse IgG2ak PerCP Cy5.5), TGF-β PerCP Cy5.5d* (isotype mouse IgG1k PerCP Cy5.5), CD25 allophycocyanin (APC)b (isotype mouse IgG1k APC), and CD4 allophycocyanin-cyanine 7 (APC Cy7)b (isotype mouse IgG1k APC Cy7). The markers analyzed for each Tregs phenotype are shown in Additional file 1: Table S1. As shown, different Tregs cell phenotypes already described in the literature were analyzed, because different subsets of Tregs have been reported to suppress the immune response through different mechanisms [34, 35, 36, 37]. CD8 regulatory T cells: CD56 FITCa (isotype mouse IgG1k FITC), CCR7 FITCa (isotype rat IgG2ak FITC), FOXP3 PEa* (isotype rat IgG2ak PE), IL-10 PEa* (isotype rat IgG2ak PE), CD161 PerCPa (isotype mouse IgG1 PerCP Cy5.5), CD45RO PerCPc (isotype mouse IgG2ak PerCP), CD8 APCa (isotype mouse IgG1k APC), and CD28 allophycocyanin-Hilite®7 (APC H7)b (isotype mouse IgG1k APC H7). With respect to CD8regs, different phenotypes were analyzed as well [25, 26, 27] Additional file 1: Table S1. B regulatory and plasma cells: CD138 FITCa (isotype mouse IgG1k FITC), CD5 FITCa (isotype mouse IgG2ak FITC), FOXP3 PEa* (isotype rat IgG2ak PE), IL-10 PEa* (isotype rat IgG2ak PE), CD24 PerCPb (isotype mouse IgG2ak PerCP Cy5.5), CD1d, Peridinin chlorophyll proteins complex-eFluor 710 (PerCP eFluor 710)b (isotype mouse PerCP eFluor 710), CD38 APCa (isotype mouse IgG1k APC), IL-10 APCb* (isotype rat IgG2a APC), and CD19 APC Cy7b (isotype mouse IgG1k APC Cy7). Different phenotypes were analyzed for Bregs and plasmatic cells [38, 39] (Additional file 1: Table S1). Monocytes (classical, non-classical, and intermediate): CD16 FITCa (isotype mouse IgG1k FITC), IL-12 PEb* (isotype mouse IgG1 PE), IL-10 PEa* (isotype rat IgG2ak PE), CD14 PerCPa (isotype mouse IgG1k PerCP Cy5.5), CD163 APCa (isotype mouse IgG1k APC), and HLA-DR APC Cy7b (isotype mouse IgG2ak APC Cy7). With respect to monocytes, the phenotypes proposed by Ziegler-Heitbrock and Wong [29, 40, 41] were analyzed (Additional file 1: Table S1). Dendritic cells: programmed death-ligand 1 (PD-L1) FITCb (isotype mouse IgG1k FITC), CD205 FITCa (isotype mouse IgG2bk FITC), signaling lymphocytic activation molecule (SLAM) PEa (isotype mouse IgG1k PE), CD40 PEb (isotype mouse IgG1k PE), CD11c PerCP eFluor 710a (isotype mouse IgG1k PerCP eFluor 710), immunoglobulin-like transcript 3 (ILT3) APCa (isotype mouse IgG1 APC), CD86 APCb (isotype mouse IgG1 APC), HLA-DR APC Cy7b (isotype mouse IgG2ak APC Cy7), and CD80 APC H7b (isotype mouse IgG1k APC H7). For DCs, different phenotypes reported in the literature were analyzed  (Additional file 1: Table S1). Th1 cells: IFN-γ FITCa* (isotype mouse IgG1k FITC), Tbet PEa* (isotype mouse IgG1k PE), TNF-α PerCP Cy5.5a* (isotype mouse IgG1k PerCP Cy5.5), and CD4 APC Cy7b (isotype mouse IgG1k APC Cy7). Th1 phenotypes are described in Additional file 1: Table S1, [42, 43, 44]. Th2 cells: IL-13 FITCa* (isotype mouse IgG1k FITC), IL-4 PEa* (isotype mouse IgG1k PE), GATA-3 PerCPa* (isotype rat IgG2bk PerCP eFluor 710), and CD4 APC Cy7b (isotype mouse IgG1k APC Cy7). Th2 phenotypes are shown in Additional file 1: Table S1 [42, 43, 44]. Th17 cells: IL-17α FITCa* (isotype mouse IgG1k FITC), ROR-γ (t isoform) PEa* (isotype rat IgG2a PE), and CD4 APC Cy7b (isotype mouse IgG1k APC Cy7). The Th17 phenotype is shown in Additional file 1: Table S1 [42, 43, 45, 46]. Isotype controls were used to discriminate positive from negative cells. Finally, the antibody labeling and the respective isotype controls for all antibodies used in this work are shown in Additional file 2: Figure S1. The antibodies used in this study were purchased from eBioscience (Waltham, MA, USA) (a), BD (Franklin Lakes, NJ, USA) (b), Invitrogen (Waltham, MA, USA) (c), and Biolegend (San Diego, CA, USA) (d); *intracellular antibodies. Labeled cells were read in an Attune Acoustic Focusing Cytometer (Applied Biosystems, Waltham, MA, USA) and analyzed with the Attune Cytometric Software v.1.2.5. The strategy used in the flow cytometry analysis is shown in Additional file 3: Figure S2.
Cytokine levels were determined by enzyme-linked immunosorbent assay (ELISA) in plasma samples from patients and controls. An Elabscience kit (Wuhan, China) was used for IL-35 determination, following the manufacturer’s instructions. Invitrogen kits were used to determine the levels of the granulocyte-macrophage colony-stimulating factor (GM-CSF), IFN-γ, IL-1b, IL-4, IL-6, IL-10, IL-12p70, IL-13, IL-17α, the transforming growth factor beta (TGF-β), and TNF-α, following the manufacturer’s protocols. TGF-β was measured using the TGF-β1 ELISA Ready-Set-Go, which includes an acid treatment to detect both the mature cytokine and the TGF-β1 latency-associated peptide (LAP). The detection limits were 2 pg/mL for IL-1β, IL-4, IL-6, and IL-10; 4 pg/mL for IL-13, IFN-γ, TNF-α, IL-12p70, and IL-17α; 6 pg/mL for GM-CSF; 8 pg/mL for TGF-β; and 9.38 pg/mL for IL-35.
The Mann-Whitney U test was used to compare the results in patients and controls. All correlations were analyzed with the Spearman test. A multiple test correction following the Holman-Bonferroni method was performed for all populations. Corrected values are reported only when significance was lost.
Clinical characteristics of patients and controls
Clinical features of patients and controls
Socio-demographic and clinical characteristics
Age at inclusion¢
55.59 ± 10.22
60.81 ± 10.23
Body mass index (BMI)¢
26.85 ± 3.89
27.52 ± 4.54
Symptom duration (years)¢
2.90 ± 3.14
Hoehn & Yahr
2.17 ± 0.88
0.72 ± 0.98
2.50 ± 1.60
0.32 ± 0.89
13.28 ± 6.56
1.72 ± 3.71
35.68 ± 18.29
0 ± 0
0 ± 0
2.77 ± 4.05
51.59 ± 25.13
99.54 ± 2.13
76.59 ± 22.55
Beck’s depression test
5.54 ± 6.24
11.50 ± 8.00
Diabetes mellitus type 2
The levels of regulatory cells are decreased in untreated PD patients
Levels of human CD8regs and Bregs in PD patients and healthy controls
16.69 ± 8.60
14.55 ± 8.05
3.84 ± 2.47
2.47 ± 1.91
13.21 ± 5.13
14.41 ± 5.41
12.70 ± 7.03
13.08 ± 9.23
0.38 ± 0.31
0.23 ± 0.17
17.34 ± 6.65
17.35 ± 6.61
3.22 ± 1.58
3.173 ± 1.76
Plasmatic cells IL-10+
32.83 ± 14.04
26.13 ± 18.99
3.82 ± 2.16
2.64 ± 1.88
1.49 ± 1.13
1.29 ± 0.91
The analysis of regulatory B cell subpopulations showed that the levels of functional Bregs were significantly lower in patients than in controls (Table 2).
The multiple test correction showed that P < 0.02 is considered as significant for differences in this population, so this result should also be taken with caution.
Levels of human dendritic cells in PD patients and healthy controls
54.58 ± 17.08
52.27 ± 18.22
12.63 ± 6.74
10.57 ± 9.49
9.84 ± 6.24
9.65 ± 4.73
37.92 ± 18.03
41.01 ± 18.46
29.22 ± 15.27
30.64 ± 14.61
45.58 ± 19.33
45.48 ± 19.24
9.11 ± 9.59
10.45 ± 12.51
53.11 ± 17.15
52.44 ± 22.76
18.75 ± 11.17
22.86 ± 10.87
Pro-inflammatory cell levels in PD patients
Levels of human CD4 T helper cells in PD patients and healthy controls
CD4 cell subset
17.27 ± 7.96
13.76 ± 7.05
1.98 ± 2.32
1.63 ± 1.30
3.27 ± 2.94
1.83 ± 1.62
3.49 ± 5.32
4.94 ± 7 .21
2.43 ± 3.71
2.45 ± 2.93
1.47 ± 2.16
0.98 ± 0.78
No differences were found in the markers for active DCs between patients and controls (Table 3). However, HLA-DR was found to positively correlate with CD40 and CD80 in patients (r = 0.514, P = 0.004; r = 0.406, P = 0.029, respectively); CD86 positively correlated with CD40 (r = 0.432, P = 0.019). Finally, a positive correlation was observed between CD40 and CD80 (r = 0.647, P = 0.0001).
Monocyte levels in PD patients
No differences in the percentage of total CD14+ cells were found between controls and patients (8.97 ± 3.55 and 9.81 ± 4.92, respectively). Monocytes were characterized by the expression of CD14 and CD16 and then subclassified into non-classical, intermediate, and classical monocytes. As shown in Additional file 7: Table S5, no differences were found between patients and controls. Additionally, no differences were observed in the percentage of M1-like cells (0.02 ± 0.03 and 0.03 ± 0.04, respectively) nor M2-like cells (0.09 ± 0.11 and 0.07 ± 0.09, respectively) between controls and patients.
Cytokine levels in PD patients
Pro-inflammatory cytokines were classified according to the T helper phenotype that they are capable to polarize, or to the cytokine produced by each cell type. Thus, no significative differences were found between patients and controls for the Th1 phenotype (TNF-α and IFN-γ). For the Th2 phenotype (IL-4 and IL-13), IL-13 levels were higher in patients than in controls (P = 0.001). For Th17 (IL-17α), the levels of IL-17α were lower in patients than in controls (P = 0.014). Interestingly, the plasmatic levels of IL-17 positively correlated with the H&Y, UPDRS III, and UPDRS-total scores (r = 0.4090, P = 0.0247; r = 0.4162, P = 0.0222; and r = 0.3945, P = 0.0310, respectively).
The levels of IL-1β, IL-12p70, IL-6, and GM-CSF were not significantly different between patients and controls (Fig. 2).
In this study, the immunological features related to the pro- and anti-inflammatory responses were studied in peripheral blood samples from a cohort of Parkinson’s disease patients naïve to dopaminergic treatment. All enrolled patients exhibited normal laboratory test results (hemogram, blood chemistry, and hormonal profile, as shown in Additional file 4: Table S2, Additional file 5: Table S3 and Additional file 6: Table S4. No significant differences were observed in unspecific inflammatory markers (CRP and ESR) between patients and controls. These markers are acute-phase proteins produced by the liver before pro-inflammatory cytokines like TNF-α, IL-6, and IL-1β are secreted; thus, inflammation in PD patients can be considered as a chronic process.
The main alteration in the immune profile of PD patients was the composition of the population of regulatory cells. Interestingly, lower levels of suppressive Tregs (CD4+CD25hiFOXP3+CD127−), active Tregs (CD4+CD45RO+FOXP3hi), and Tr1 cells (CD4+CD25hiIL-10+) were found in patients with respect to controls. Our finding of decreased levels of suppressive Tregs is in agreement with the work by Saunders (2012), although only treated patients were enrolled in that study . Therefore, the reduced levels of suppressive Tregs seem to be associated with the pathogeny of PD. With respect to active Tregs and Tr1 cells, this work is (to the best of our knowledge) the first study to report decreased levels of these cells in PD patients. A decrease in Tregs levels could have an important role in the progression of PD. The absence of Tregs has been linked to rapid cognitive deterioration, as well as to a rapid disease progression in murine models of neurodegenerative disorders like Alzheimer’s disease and amyotrophic lateral sclerosis [47, 48, 49]. These findings emphasize the relevance of decreased Tregs levels in the pathology of PD, since it is possible that Tregs are unable to control the pro-inflammatory response that is associated with a progression of the disease .
On the other hand, suppressor Tregs and active Tregs act by inhibiting the proliferation of effector CD4+ cells [50, 51, 52], while Tr1 cells are characterized by producing IL-10, an anti-inflammatory cytokine that suppresses several pro-inflammatory pathways involving transcription factors like the nuclear factor-kappa B (NF-κB) and those involving the mitogen-activated protein kinase (MAPK).
With respect to CD8regs lymphocytes, a decrease in the levels of IL-10-producing CD8 cells and a tendency to decrease in functional CD8regs (CD8+CD45RO+CCR7+IL-10+) was observed in PD patients. Both cell lines are mainly responsible for regulating the inflammatory response by secreting IL-10. Interestingly, the levels of IL-10-producing CD8 cells have been reported as significantly reduced in the exacerbation phase of multiple sclerosis but increased during remission, suggesting a favorable effect on patient recovery [53, 54, 55]. Thus, the role of these cells in PD progression should be further studied.
A tendency to decrease in the levels of functional Bregs (CD19+CD38hiCD24hiIL-10+) was found in PD patients. Bregs cells have been involved in the recovery of experimental autoimmune encephalomyelitis and in the induction and maintenance of Tregs . Thus, the tendency to decrease in Breg levels suggests an impairment in the immunoregulatory response in PD patients. Another possible explanation for this fact is their involvement in the suppression of antibody-producing B cells, since antibodies are critically involved in PD, and a failure in their suppression could contribute to pathogeny .
With respect to tolerogenic DCs, a decrease in the expression of PD-L1 was observed in PD patients. This fact is remarkable, since PD-L1 is known to play an important role in the development and maintenance of Tregs and inducible Tregs (iTregs) [58, 59]. Thus, the lower expression of PD-L1 in PD patients could be related to the decreased Tregs levels found in our patients.
Altogether, the regulatory immune response in treatment naïve PD patients is characterized by decreased levels of active Tregs, suppressive Tregs, Tr1 cells, functional CD8regs, CD8 IL-10+, functional Bregs, and tolerogenic PD-L1+ DCs, which could be failing to control the pro-inflammatory response.
With regard to the pro-inflammatory response, we found decreased plasmatic levels of IL-17A and increased levels of IL-13 in patients with respect to controls. This could be associated with the type of immune response observed in patients (towards a Th2 phenotype instead of a Th17); however, this fact is not supported by any other experimental result.
Pairwise positive correlations were found between the levels of DCs and several immunomodulatory molecules (PD-L1, ILT3, and CD205); similar positive correlations were observed between DCs and molecules that activate the immune response (CD80, CD86, and CD40). This suggests that both activating and tolerogenic cell phenotypes are participating in the immune response of the patients, although no clear predominance of any specific phenotype was observed.
Considering that PD has been associated with chronic inflammatory processes, the alterations found in this work, mainly related to a deficient anti-inflammatory response, suggest that an imbalance between regulation and inflammation could be underlying the pathogeny of PD, at least in part. Indeed, the levels of several Tregs subpopulations were lower in patients than in controls, but at the same time, these Tregs showed positive correlations with other Tregs subpopulations, suggesting the existence of a feedback among various cell populations. Positive correlations of suppressive and non-Tregs and with classical Tregs could be associated to a transition of non-Tregs towards a functional Tregs phenotype to offset their lower levels, as it has been reported before . The levels of IL-10-producer (Tr1) cells are lower in PD patients, as well as the levels of IL-10-producer CD8 cells. Although these findings suggest that IL-10 may not be involved in the immunosuppression observed in PD patients, further studies are required to confirm its role.
A comparative analysis between sexes, which would allow us to compare sex-related differences in the immune response, was not performed in this work. Sex has been suggested as a possible risk factor in PD, since a male/female ratio of about 2:1 has been reported in PD patients . Some studies have shown that the clinical presentation of PD is slightly different in women, with a higher frequency of dyskinesia and depression. In addition, women generally are diagnosed with PD at an older age than men, possibly due to a decrease in estrogen production . The lack of a comparative analysis of the immune response between sexes is a limitation of our work. Further studies on a larger cohort of male and female PD patients should be conducted to elucidate these differences.
A decrease in the levels of CD4+ Tregs subpopulations, of functional Bregs, of IL-10-producing CD8+ lymphocytes, of functional CD8regs, and of tolerogenic PD-L1+ DCs in untreated PD patients is reported in this work, for the first time. The decreased levels of various phenotypes of regulatory cells suggest a deficiency in the regulatory immune response in untreated PD patients. These findings could contribute to deepen our understanding of the pathophysiology of the disease.
The authors thank Carlos Castellanos Barba for his technical assistance in flow cytometry and Marisela Hernández for her technical assistance. Juan Francisco Rodríguez copy-edited the English version of this paper. DDÁ-L and AA-S thank the Programa de Maestría y Posgrado en Ciencias Médicas, Odontológicas y de la Salud, Universidad Nacional Autónoma de México. LA-P thanks CONACYT SALUD [grant No. 2015-1-261455].
AA-S and LA-P contributed to the study conception and design. DDÁ-L, AA-S, ES, MCB, UR-O, and LA-P organized the project. DDÁ-L, AA-S, JL-H, ES, EM-M, VV-A, CP-C, and RE-C executed the experimental development of the project. DDÁ-L, AA-S, and LA-P designed the statistical analysis, and DDÁ-L executed the analysis. DDÁ-L, AA-S, and LA-P wrote the first draft of the manuscript, and GF and ES reviewed and criticized it. All authors read and approved the final manuscript.
This work was supported by the CONACYT SALUD [2015-1-261455].
Ethics approval and consent to participate
The protocol for this study was approved by the INNN Ethics Committee (permit No. 95/14) and was conducted in accordance with the Helsinki Declaration.
Consent for publication
The authors declare that they have no competing interests.
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