MCP1-CCR2 and neuroinflammation in the ALS motor cortex with TDP-43 pathology

Postmortem human tissue was collected according to protocols approved by Northwestern University’s Institutional Review Board. Clinical records were available for every patient. Neuropathologists with expertise in neurodegenerative disorders examined all samples. Brains were fixed as reported [14]. Areas of the primary motor cortex (Brodmann area 4) were retrieved and processed as reported [14]. This study includes motor cortex isolated from normal control cases with no neurologic disease (n = 3), ALS patients with cortex involvement and TDP-43 pathology (n = 9), and ALS-FTLD patients with TDP-43 pathology (n = 3; Table 1). Presence of TDP-43 pathology was confirmed by pS409/410–2 (1:5000 dilution; AEC chromogen, Cosmo-Bio USA, Carlsbad, CA, USA) [15].

All animal experiments followed the standards set by National Institutes of Health and were performed in accordance to animal protocols approved by the Northwestern University Animal Care and Use committee. Mice were on a C57/BL6 background. WT, prpTDP-43^A315T (Jackson Laboratory, stock#. 010700), UCHL1-eGFP (generated by the Ozdinler Lab and made available at Jackson Laboratory, stock#. 022476) [16], and prpTDP-43^A315T-UeGFP mice (generated by the Ozdinler Lab) are used [14].

Mice were deeply anesthetized and perfused as previously described [11]. The brain was dissected, post-fixed in 4% PFA overnight, stored in PBS with 0.01% sodium azide, and sectioned at 50 μm using Leica vibratome (Leica VT1000S, Leica Inc., Nussloch, Germany). Floating sections were processed for immunocytochemistry [10]. All antibodies were obtained from Abcam (Cambridge, MA, USA) unless otherwise stated. In this study, chicken anti-GFP (1:500), rat anti-GFAP (1:1000; Invitrogen), rabbit anti-Iba1 (1:500; Wako), TMEM 119 (1:500), mouse anti-CCR2 (1:500), and rabbit anti-CD31 (1:500) were used.

For postmortem human samples, slides were baked for 60 min at 60 °C, deparaffinized with xylene for 5 min, and rehydrated in ethanol (100, 95, 70, and 50%). Antigen retrieval was performed as previously reported [17]. In this study, chicken anti-Map 2 (1:200, Abcam, Cambridge, MA, USA), rat anti-GFAP (1:1000; Invitrogen, Thermo Fisher Scientific, Rockford, IL, USA), rabbit anti-Iba1 (1:500; Wako), TMEM 119 (1:1000), mouse anti-CCR2 (1:500), and rabbit anti-CD31 (1:500) were used.

Nikon Eclipse TE2000-E (Nikon Inc., Melville, NY, USA), Leica TCS SP5 confocal microscope (Leica Inc., Bensheim, Germany), and Zeiss 880 confocal microscope (Carl Zeiss microscopy, Jena, Germany) were used to acquire low- and high-magnification images, respectively. EM grids were examined on FEI Tecnai Spirit G2 TEM (FEI company, Hillsboro, OR, USA), and digital images were captured on a FEI Eagle camera. Electron microscopy imaging was performed at the Center for Advanced Microscopy/Nikon Imaging Center (CAM), at the Northwestern University Feinberg School of Medicine, Chicago.

Investigators collecting the data and performing the quantifications were blind to the genotype and pathology. After all data were collected, investigators were unblinded and statistical analyses were performed using the Prism software (GraphPad Software Inc., La Jolla, CA, USA). D’Agostino and Pearson normality tests were performed on all data sets. Either Student’s t test or ANOVA with post hoc Tukey’s multiple comparison test was used to determine statistical differences between the experimental groups depending on the genotype, experimental conditions, and the disease group. Data are shown as mean ± SEM of at least three replicates and are representative of three independent experiments unless otherwise stated and statistically significant differences were taken at p < 0.05, and p values or adjusted p values are reported in the text.

To investigate the role of neuroinflammation with respect to ALS with TDP-43 pathology, we first investigated the presence of microgliosis and astrogliosis in the primary motor cortex Brodmann area 4 of normal controls, ALS cases, and ALS-FTLD cases with TDP-43 pathology (Fig. 1A’, A”; Table 1). Microglia and astrocyte morphology which allows for the differentiation of “quiescent/normal” microglia has a small cell body and ramified thin processes, and “activated” microglia have enlarged cell body and thick and short processes as previously defined by us and others [10, 18]. GFAP signal was low in the normal control brain (Fig. 1B), and the total number of astrocytes were comparable between normal controls (46 ± 1, n = 3) and ALS cases (47 ± 2, n = 9; p = 0.7571). However, the percentage of activated astrocytes increased about 34% in ALS patients with TDP-43 pathology (normal controls: 24 ± 5%, n = 3; ALS with TDP-43 pathology: 58 ± 3, n = 9, p < 0.0001), in contrast to percentage of quiescent astrocytes in patients (normal controls: 76 ± 5%, n = 3; ALS with TDP-43 pathology: 41 ± 2, n = 9, p < 0.0001; Fig. 1E, G). Similar observations were made with microglia. The total number of microglia were comparable between normal controls (36 ± 1, n = 3) and ALS cases (36 ± 2, n = 9; p = 0.786); there was a significant decrease of quiescent microglia in ALS patients with TDP-43 pathology (normal controls: 72 ± 1%, n = 3; ALS with TDP-43 pathology: 51 ± 2, n = 9, p < 0.0001; Fig. 1C) and about 21% increase of activated microglia in ALS patients with TDP-43 pathology (normal controls: 28± 1%, n = 3; ALS with TDP-43 pathology: 49 ± 2, n = 9, p < 0.0001; Fig. 1D). Betz cells with small soma and vacuolated apical dendrite, consistent with characteristics of degenerating Betz cells [17] (arrow), were surrounded by activated microglia (arrowhead). In contrast, “quiescent” microglia (asterisk) were in close proximity to healthy Betz cells in normal controls (Fig. 1B). Interestingly, the presence of unique rod-like microglia characterized by elongated nuclei was observed exclusively in ALS patients (Fig. 1F, H, number sign), and they were found mostly aligned with degenerating apical dendrites.

We previously generated and characterized prpTDP-43^A315T-UeGFP mice, a novel TDP-43 mouse model with genetically-labeled eGFP+ CSMN, by crossing the well-characterized prpTDP-43^A315T mice with UCHL1-eGFP (Fig. 2a). CSMN of these mice faithfully recapitulate the cellular defects observed in Betz cells of ALS patients with TDP-43 pathology [14]. We investigate the involvement of neuroinflammation in layer 2/3 of the motor cortex, where CSMN receives most of its modulatory inputs, and layer 5 [20], where CSMN soma is located.

Astrocyte numbers were higher in the motor cortex of prpTDP-43^A315T-UeGFP mice with prominent astrogliosis, especially in the layer 5 (Fig. 2b–g), but numbers were comparable in layer 2/3 at P30 (WT-UeGFP: 23 ± 1 astrocytes; prpTDP-43^A315T-UeGFP: 27 ± 3 astrocytes, n = 3 mice; adjusted p = 0.994). However, the presence of astrocytes increased at P60 (WT-UeGFP: 43 ± 5 astrocytes; prpTDP-43^A315T-UeGFP: 63 ± 5 astrocytes, n = 3 mice, adjusted p = 0.014), P90 (WT-UeGFP: 35 ± 2 astrocytes; prpTDP-43^A315T-UeGFP: 59 ± 4 astrocytes, n = 3 mice, adjusted p = 0.014), P120 (WT-UeGFP: 30 ± 1 astrocytes; prpTDP-43^A315T-UeGFP: 48 ± 2 astrocytes, n = 3 mice, adjusted p = 0.004), and P150 (WT-UeGFP: 34 ± 5 astrocytes; prpTDP-43^A315T-UeGFP: 62 ± 4 astrocytes, n = 3 mice, adjusted p = 0.014) (Fig. 2h). Initially, there was no difference in the numbers of astrocytes in layer 5 of the motor cortex at P30 (WT-UeGFP: 30 ± 2 astrocytes; prpTDP-43^A315T-UeGFP: 34 ± 1 astrocytes, n = 3 mice). However, the number of astrocytes in layer 5 increased at P60 (WT-UeGFP: 50 ± 1 astrocytes; prpTDP-43^A315T-UeGFP: 84 ± 6 astrocytes, n = 3 mice, adjusted p = 0.031), P90 (WT-UeGFP: 31 ± 2 astrocytes; prpTDP-43^A315T-UeGFP: 72 ± 7 astrocytes, n = 3 mice, adjusted p = 0.027), P120 (WT-UeGFP: 31 ± 3 astrocytes; prpTDP-43^A315T-UeGFP: 81 ± 11 astrocytes, n = 3 mice, adjusted p = 0.032), and P150 (WT-UeGFP: 45 ± 7 astrocytes; prpTDP-43^A315T-UeGFP: 107 ± 14 astrocytes, n = 3 mice, adjusted p = 0.033) (Fig. 2i).

We next investigated whether there is microgliosis in layer 2/3 and layer 5 in the motor cortex with respect to disease initiation and/or progression (Fig. 3). The total numbers of microglia did not change over time in layer 2/3 at P30 (WT-UeGFP: 160 ± 23 microglia; prpTDP-43^A315T-UeGFP: 110 ± 3 microglia, n = 3 mice), P60 (WT-UeGFP: 151 ± 32 microglia; prpTDP-43^A315T-UeGFP: 135 ± 30 microglia, n = 3 mice), P90 (WT-UeGFP: 146 ± 11 microglia; prpTDP-43^A315T-UeGFP: 175 ± 18 microglia, n = 3 mice), P120 (WT-UeGFP: 124 ± 11 microglia; prpTDP-43^A315T-UeGFP: 150 ± 20 microglia, n = 3 mice), and P150 (WT-UeGFP: 133 ± 7 microglia; prpTDP-43^A315T-UeGFP: 138 ± 9 microglia, n = 3 mice; Fig. 3g), and in layer 5 at P30 (WT-UeGFP: 148 ± 9 microglia; prpTDP-43^A315T-UeGFP: 151 ± 10 microglia, n = 3 mice), P60 (WT-UeGFP: 178 ± 33 microglia; prpTDP-43^A315T-UeGFP: 171 ± 29 microglia, n = 3 mice), P90 (WT-UeGFP: 202 ± 11 microglia; prpTDP-43^A315T-UeGFP: 224 ± 35 microglia, n = 3 mice), P120 (WT-UeGFP: 165 ± 14 microglia; prpTDP-43^A315T-UeGFP: 211 ± 32 microglia, n = 3 mice), and P150 (WT-UeGFP: 182 ± 8 microglia; prpTDP-43^A315T-UeGFP: 214 ± 24 microglia, n = 3 mice; Fig. 3h). However, activated microglia became prominent with disease progression. In layer 2/3, the levels were comparable at P30 (WT-UeGFP: 3 microglia; prpTDP-43^A315T-UeGFP: 4 microglia, n = 3 mice), but increased at P60 (WT-UeGFP: 3 microglia; prpTDP-43^A315T-UeGFP: 11 ± 2 microglia, n = 3 mice, adjusted p = 0.046), P90 (WT-UeGFP: 5 ± 1 microglia; prpTDP-43^A315T-UeGFP: 21 ± 2 microglia, n = 3 mice, adjusted p = 0.013), P120 (WT-UeGFP: 7 microglia; prpTDP-43^A315T-UeGFP: 22 ± 2 microglia, n = 3 mice, adjusted p = 0.016), and P150 (WT-UeGFP: 6 microglia; prpTDP-43 ^A315T-UeGFP: 23 ± 3 microglia, n = 3 mice, adjusted p = 0.042). The presence of activated microglia was more evident in layer 5 and became significant with disease progression. Even though the levels were comparable at P30 (WT-UeGFP: 3 microglia; prpTDP-43^A315T-UeGFP: 4 microglia, n = 3 mice), the extent of microgliosis was increased at P60 (WT-UeGFP: 5 microglia; prpTDP-43^A315T-UeGFP: 17 ± 2 microglia, n = 3 mice, adjusted p = 0.034), P90 (WT-UeGFP: 5 ± 1 microglia; prpTDP-43^A315T-UeGFP: 26 ± 2 microglia, n = 3 mice, adjusted p = 0.010), P120 (WT-UeGFP: 9 microglia; prpTDP-43^A315T-UeGFP: 34 ± 3 microglia, n = 3 mice, adjusted p = 0.012), and P150 (WT-UeGFP: 7 ± 1 microglia; prpTDP-43^A315T-UeGFP: 33 ± 4 microglia, n = 3 mice, p = 0.012; Fig. 3j).

The similarities between findings in the motor cortex of the prpTDP-43^A315T-UeGFP mice and the motor cortex of ALS patients with TDP-43 pathology were remarkable (Fig. 4). The diseased upper motor neurons are near astrocytes and microglia both in mice (Fig. 4B, C) and in patients (Fig. 4E, F). Activated microglia with enlarged cell bodies and thick processes wrapped the degenerating CSMN apical dendrites (Fig. 4B’) and apical dendrites of Betz cells (Fig. 4E, F). Additionally, dysmorphic microglia with characteristics of rod-like microglia were observed both next to the degenerating CSMN (Fig. 4C) and Betz cell apical dendrites (Fig. 4E, F). In contrast, healthy Betz cells were devoid of activated microglia and astrogliosis in their proximity (Fig. 4D). Interestingly, numerous rod-like microglia were noted along the degenerating apical dendrites, further suggesting their potential involvement in UMN degeneration in both species.

Upon visualization of microgliosis and astrogliosis surrounding Betz cells and CSMN in the motor cortex, we next asked if peripheral immune cells contribute to UMN degeneration. We previously detected infiltrating monocytes expressing CCR2 in the motor cortex of hSOD1^G93A mice, one of the best-characterized mouse models of ALS [10]. Therefore, we investigated whether CCR2+ infiltrating monocytes were also present in the brain parenchyma and whether they enter from the bloodstream. In the WT-UeGFP motor cortex, very few CCR2+ infiltrating monocytes were observed (Fig. 5A, B). In striking contrast, numerous CCR2+ infiltrating monocytes were detected within and around the blood vessels in the motor cortex of prpTDP-43^A315T-UeGFP mice (Fig. 5C, D and insets E, F). TMEM119 expression profile further demonstrated that CCR2+ cells were indeed infiltrating monocytes and not of microglia origin (Fig. 5G, H). They were in close proximity to CSMN both at the soma and apical dendrite levels. Interestingly, apical dendrites displayed signs of degeneration with vacuolation and disintegration.

We next focused our attention to the brain parenchyma and the blood vessels, taking advantage of high-resolution EM. In the WT motor cortex, the blood vessels were lined with a thin layer of epithelial cells, and no infiltrating cells from the blood vessel were observed (Fig. 6a–c). In contrast, numerous non-neuronal cells were infiltrating from the blood vessels of prpTDP-43^A315T mice (Fig. 6d–f) even at P60 (WT: 1 ± 1 cell, n = 5 blood vessels, n = 3 mice; prpTDP-43^A315T: 4 ± 1 cell, n = 6 blood vessels, n = 3 mice, p = 0.02; Fig. 6n). The blood vessels were enlarged, and the epithelial lining harbored many infiltrating monocytes that moved towards the brain parenchyma. These were cells of phagocytic origin. Their lumen was white, including large lysosomes, and their nucleus revealed their cellular identity to be a monocyte and macrophage lineage [19]. Interestingly, these infiltrating cells were mostly present in close proximity to large CSMN in the motor cortex, and some of them were found not only having contact but intruding into the CSMN soma, pushing the cytoplasm and even the nucleus. Some even broke the cell membrane and were engulfing parts of the CSMN cytoplasm as early as P60.

We next investigated whether Betz cells of patients with TDP43 pathology were subject to infiltration of the peripheral immune cells. In the motor cortex of normal controls, blood vessels were not enlarged, and they lacked infiltrating cells (Fig. 6g–i). Interestingly, similar to CSMN of prpTDP-43^A315T, Betz cells of patients were also surrounded by neuroimmune cells (Fig. 6g–m, o), and blood vessels of patients with TDP-43 pathology were enlarged and many neuroimmune cells with large soma and nucleus were breaking off from the epithelial lining to enter the brain parenchyma, moving towards the diseased Betz cells (Fig. 6j). A diseased Betz cell was associated with at least one cell that is filled with lysosomes, and at times more than one neuroimmune cell was attached to a single Betz cell (patients with TDP-43 pathology: 4 ± 1 cell, n = 23 blood vessels, n = 4 subjects, p < 0.0001; Fig. 6l, m, o). However, Betz cells of control cases were not associated with neuroimmune cells (normal control: 1 ± 1 cell, n = 15 blood vessels, n = 3 subject) (Fig. 6o). The human post-mortem samples represent the end-stage of the disease when infiltrating monocytes and neuroimmune cells are most apparent. However, it is important to note that as observed in Figs. 5 and 6a–e, by P60, there are already infiltrating immune cells moving towards the diseased CSMN and are engaging in cell-cell contact with them, suggesting that the “call” has been made early during disease progression.

CCR2 expression profile helped reveal the identity of infiltrating cells in the motor cortex of ALS patients to be an infiltrating monocyte. CCR2+ infiltrating monocytes were not detected in normal controls (Fig. 7A, B), but there was a dramatic increase in the levels of CCR2+ infiltrating monocytes in the primary motor cortex of ALS with TDP-43 pathology. In these cases, CCR2+ infiltrating monocytes were detected inside blood vessels and in their vicinity, indicating possible recent transvasation (Fig. 7C, D, arrowheads). CCR2+ infiltrating monocytes were mainly found in areas where degenerating apical dendrites of Betz cells were present in the brain parenchyma (Fig. 7E, F). Similar to the results obtained in the mouse motor cortex, lack of TMEM119 expression further revealed that CCR2+ cells were infiltrating monocytes and not of microglia origin in the motor cortex of human patients (Fig. 7G, H).

The presence of CCR2+ infiltrating monocytes in the motor cortex of ALS cases with TDP-43 pathology prompted us to investigate whether Betz cells express the chemokine MCP1 [10, 21]. Betz cells with healthy apical dendrites have either no or very low levels of MCP1 throughout the primary motor cortex in normal controls (5 ± 4%, n = 43 cells, n = 3 normal controls; Fig. 8a, b). In contrast, MCP1 expression was dramatically increased in both ALS cases with TDP-43 pathology (93 ± 7%, n = 72 cells, n = 4 patients, p < 0.0002; Fig. 8c, d) and ALS-FTLD cases with TDP-43 pathology (77 ± 4%, n = 44 cells, n = 3 patients, p < 0.002; Fig. 8e, f). Activated microglia also expressed high levels of MCP1, as we have previously shown in ALS pathology (arrowheads) [10]. These activated microglia surrounded degenerating Betz cells expressing high levels of MCP1 (asterisks). Interestingly, some large Betz cells currently with no sign of prominent degradation also displayed high levels of MCP1 (Fig. 8e, f), suggesting that increased MCP1 expression occurred prior to cellular engagement with CCR2+ cells, neuronal degradation, and clearance in the motor cortex of patients with TDP-43 pathology.