Enteric glial cells favor accumulation of anti-inflammatory macrophages during the resolution of muscularis inflammation

Time-dependent recruitment of myeloid cells in the inflamed muscularis

Surgery-induced damage to the muscularis leads to a transient impairment of GI motility associated with extensive recruitment of immune cells to the ENS. To characterize the immune cell infiltrate and their respective activation states during muscularis inflammation, droplet-based single cell RNA sequencing (scRNA-seq) was performed on sorted CD45+ immune cells from the muscularis of naïve mice, and during the acute inflammatory (24 h) and the recovery phase of muscularis inflammation (72 h) (10X Genomics Platform; Fig. 1a). Unsupervised clustering of 4102 cells and reference-based cell identification using Immgen (Fig. 1b, c and Supplementary Fig. 1a, b) revealed 12 independent immune cell populations including monocytes (Ccr2, Ly6c2, Chil3), 3 clusters of Mφs (1: Cd63, Cd68, Trem2; 2: Itgam, Arg1, Lyz2; 3: Cx3cr1, Csf1r, Mrc1), dendritic cells (DCs; Itgax, Cd209a, Ccl17), 2 clusters of neutrophils (1: Cxcr2, Mmp9, S100a9; 2:, S100a8, Hcar2, Msrb1), eosinophils (Siglec-f, Cxcr4, Pim1), ILCs (Thy1, Rora, Il7r), T cells (Cd3e, Cd7, Trdc) and 2 clusters of B cells (1: Cd79a, Cd20, CD79b; 2: Eaf2, Mef2b, CD19)20.

Fig. 1: Identification of CD45+ immune cell populations by unsupervised scRNA-seq clustering in the healthy and inflamed muscularis.figure 1

a Experimental pipeline of scRNA-seq experiment. b UMAP of sorted CD45+ immune cells from the healthy muscularis, 24 h and 72 h post-injury from WT mice. Each sample was pooled from 3–4 mice. c Heatmap of the 50 most differentially expressed genes in each cluster. d UMAPs of time-dependent infiltration of immune cells upon muscularis inflammation. Data of Fig. 1b has been split based on different time points. e Cell fraction of each cluster relative to the total number of CD45+ immune cells at different time points after muscularis inflammation.

To examine the role of different immune cell populations, we determined their gene expression signatures at different time points during muscularis inflammation. At homeostasis, the muscularis mainly consisted of a population of Cx3cr1+ Mφs (Mφ_3) together with T cells, B cells and ILCs (Fig. 1d, e). Consistent with previous observations11,21, a shift in the leukocyte populations was observed in the acute phase (24 h) after the induction of muscularis inflammation with a massive infiltration of monocytes in addition to Mφs (Mφ_1 and Mφ_2) and neutrophils (Neu_1 and Neu_2), pointing towards a pro-inflammatory micro-environment (Fig. 1d, e). During the resolution of muscularis inflammation (72 h), the muscularis was mainly populated by Cx3cr1+ Mφs (Mφ_3), DCs and eosinophils, indicating a return to homeostasis. Altogether, these results show that during muscularis inflammation a shift in the immune landscape favors the resolution of inflammation and a rapid return to homeostasis.

Identification of two distinct myeloid subpopulations during the resolution of muscularis inflammation

Monocyte-derived Mφs are essential for the recovery of GI motility during the resolution of muscularis inflammation11,21. However, their heterogeneity and differentiation trajectory towards tissue-protective Mφs have not yet been characterized during muscularis inflammation. To this end, subsets originally identified as monocyte/Mφ subpopulations in our scRNA-seq dataset (Fig. 1) were extracted and re-clustered to better define which types of myeloid cells might aid in the resolution of muscularis inflammation, thereby identifying 7 distinct subsets (Fig. 2a–d and Supplementary Fig. 2a). At homeostasis, the muscularis micro-environment mainly consisted of Cx3cr1+ Mφs with high expression of typical resident Mφ markers such as Cd81, Cd72 and H2-Eb1 (Fig. 2e). During acute muscularis inflammation, the most predominant subpopulation was the cluster of classical Ly6c+ monocytes, which was enriched for the expression of Plac8, Hp and Chil3 (Fig. 2b–e). Additionally, a subpopulation with a gene expression signature suggestive of an intermediate monocyte-to-Mφ differentiation state was observed (Ccr2+ int Mφs), which was underscored by their moderate MhcII expression as compared to Ly6c+ monocytes and homeostatic Cx3cr1+ Mφs (Fig. 2b). Besides Ly6c+ monocytes and Ccr2+ int Mφs, we observed a subcluster of Arg1+ Mo/Mφs with high expression of Ccl9 and Srgn alongside Fabp5+ Mo/Mφs with characteristic expression of Lgals1, Ccl7 and Flt1 (Fig. 2e). Of note, 72 h post-injury, during the resolution of muscularis inflammation, Ly6c+ monocytes and Ccr2+ int Mφs were present at a low percentage but two novel Mφ subclusters were identified: Cd206+ Mφs and Timp2+ Mφs (Fig. 2c, d and Supplementary Fig. 2b). The most abundant subcluster during the resolution of muscularis inflammation, Cd206+ Mφs, displayed high MhcII expression similar to homeostatic Cx3cr1+ Mφs, in addition to high expression of anti-inflammatory genes such as Selenop, Mrc1, Igf1, Trem2 and Stab1 (Fig. 2b and Supplementary Fig. 2b, c). In contrast, Timp2+ Mφs had lower MhcII expression compared to homeostatic Cx3cr1+ Mφs, but similarly expressed high levels of tissue reparative markers such as Ltc4s and Adgre5 (Fig. 2b, e and Supplementary Fig. 2b, c). To further investigate differences in the transcriptional regulation of Cd206+ and Timp2+ Mφs, single-cell regulatory network inference and clustering (SCENIC) was employed to assess specific regulon activities in different myeloid subclusters (Fig. 2f and Supplementary Fig. 2f). Cd206+ Mφs displayed high regulon activity of FosB, Runx1 and Irf8 similar to Cx3cr1+ Mφs, while Timp2+ Mφs had a distinctly altered transcription factor signature with high Cebpb and Gata6 regulon activity.

Fig. 2: Two main anti-inflammatory Mφ subpopulations with a unique transcriptional state are present during the resolution of muscularis inflammation.figure 2

a UMAP of reclustered monocyte/Mφ subpopulations from Fig. 1a from the healthy muscularis, 24 h and 72 h post-injury from WT mice. b Heatmap of typical monocyte and Mφ markers including MHCII genes. c UMAPs of time-dependent infiltration of monocyte and Mφ subsets upon muscularis inflammation. d Cell fraction of each subcluster relative to the total number of monocytes/Mφs at different time points after muscularis inflammation. e Dotplot showing expression of selected differentially expressed genes in each subcluster. f Heatmap of regulon activity per cluster according to SCENIC analysis. g Pseudotime analysis of monocytes/Mφs at different time points after muscularis inflammation. h Heatmap of gene expression showing the top 50 genes of different branches of the pseudotime trajectory tree.

To evaluate whether these subclusters can also be detected by flow cytometry, a comparative study was performed during muscularis inflammation. In the healthy muscularis, only 1 subset of MHCIIhi Mφs was observed similar to homeostatic Cx3cr1+ Mφs (Supplementary Fig. 2d, e). During acute muscularis inflammation, the muscularis micro-environment was mainly dominated by infiltrating Ly6Chi monocytes, which differentiated into Ly6C+ MHCII+ immature Mφs. However, at single cell level, we observed 4 different Mφ subclusters, indicating that Mφ heterogeneity was higher than originally considered. Interestingly, 72 h post-injury, flow cytometric analysis also revealed only two main Mφ subclusters (MHCIIhi and MHCIIlo Mφs), similar to our observations at single cell level (Supplementary Fig. 2d, e).

Identifying relevant gene expression changes in myeloid subclusters during muscularis inflammation could shed light on the molecular mechanisms regulating Mφ differentiation. In order to define these possible temporal transcriptional alterations leading to differentiation into Cd206+ and Timp2+ Mφs, Monocle-2 was used to superimpose subclusters on a trajectory placing Ly6c+ monocytes at the beginning of the pseudotime (Fig. 2g, h)22. Using this approach, we identified a major trajectory bifurcation leading to a branch of cells with high expression of genes found in homeostatic Mφs such as Cd74, Tmem176a/b, complement genes (C1qa, C1qb, C1qc) and MhcII genes (H2-Eb1, H2-Ab1, H2-Aa; Branch 1), while the cells in the second branch expressed less complement and MhcII genes but had increased expression of Fn1, Ltc4s and Saa3 (Branch 2) (Fig. 2h and Supplementary Fig. 2g, h). Interestingly, the Cd206+ and Timp2+ Mφ subsets were at two opposite ends of the trajectory suggesting different differentiation paths during the resolution of muscularis inflammation (Fig. 2g). Of note, homeostatic Cx3cr1+ Mφs were located in close proximity to Cd206+ Mφs in the pseudotime, underscoring the similarity between both Mφ subsets. Arg1+ and Fabp5+ Mo/Mφs were mainly present in Branch 2, while Ccr2+ int Mφs were exclusively present in Branch 1, indicating that these subpopulations might act as intermediates before attaining their terminal differentiation state. These findings support the hypothesis that there are two major monocyte-to-Mφ differentiation trajectories in the inflamed muscularis giving rise to Cd206+ and Timp2+ Mφs during the resolution of inflammation.

Pro-resolving Mφs originate from CCR2± monocytes during muscularis inflammation

In a previous study, we have shown that the influx of CCR2+ monocytes is essential for resolution of muscularis inflammation, as blocking monocyte infiltration resulted in a delayed recovery of GI motility and damage to the ENS11. Thus, to investigate whether CCR2+ monocytes are the source of pro-resolving Mφs during muscularis inflammation, scRNA-seq was performed on sorted CD45+ immune cells from the muscularis of WT and CCR2−/− mice 24 h and 72 h post-injury (Fig. 3a–c and Supplementary Fig. 3a–d). After extraction and re-clustering of the monocyte and Mφ subsets (2,406 cells), the gene expression signatures from the myeloid subsets in Fig. 2 were crossmatched by singleR with this novel dataset to specifically annotate the subpopulations (Supplementary Fig. 3c), yielding only one additional cluster, i.e., Fn1+ Mo/Mφs. In CCR2−/− mice, there was a large alteration in the myeloid compartment after muscularis inflammation. As expected upon acute muscularis inflammation in CCR2−/− mice, there was an almost complete loss of Ly6c+ monocytes, and Arg1+ and Fabp5+ Mo/Mφs. In addition, we could only detect a small subpopulation of Cx3cr1+ Mφs representing the long-lived resident Mφs. During the resolution of muscularis inflammation, the Cd206+ and Timp2+ Mφ subsets were also completely absent in CCR2−/− mice, confirming that these subpopulations are derived from CCR2+ monocytes and that they possibly represent the pro-resolving Mφs essential for recovery of GI motility after tissue damage.

Fig. 3: Two distinct Mφ subpopulations during the resolution of muscularis inflammation are derived from CCR2+ monocytes.figure 3

a UMAP of monocyte and Mφ subclusters from the muscularis of WT and CCR2−/− mice at 24 h and 72 h after induction of muscularis inflammation. Each sample was pooled from 3–4 mice. b UMAPs of myeloid cells at different time points post-injury. c Cell fraction of each subcluster relative to the total number of myeloid cells at different time points after muscularis inflammation. d GO analysis of monocytes versus Cd206+ Mφs (left) or Timp2+ Mφs (right) showing negative Log10(p-value). e Immunofluorescent images of muscularis whole-mount preparations 3 days after the induction of muscularis inflammation stained for GFAP (purple), TIMP2 (yellow) and CD206 (light blue). Scale bar 15 µm. f Experimental outline of in vitro EGC proliferation by stimulation with supernatant of monocytes or Mφs from different time points post-injury. g Fold induction of EGCs stimulated with the supernatant of LY6Chi monocytes from 24 h post-injury or MHCIIhi Mφs from 72 h post-injury relative to control medium. Every data point is an independent sorting and culture experiment One-way ANOVA; test *p < 0.05; **p < 0.01; ns not significant.

To further investigate the phenotype of Cd206+ and Timp2+ Mφs during muscularis inflammation, gene ontology (GO) analysis was performed and revealed that both Mφ subsets seemed pro-resolving in nature (Fig. 3d). For instance, Timp2+ Mφs were implicated in pathways associated with tissue repair and regulation of the inflammatory response, such as angiogenesis, response to wounding, blood vessel development, icosanoid biosynthetic processes, and phagocytosis-engulfment. Conversely, Cd206+ Mφs were enriched for pathways associated with antigen processing and presentation via MHC class II, negative regulation of oligodendrocyte and glial cell apoptotic processes and positive regulation of gliogenesis. In contrast, monocytes were clearly enriched for pro-inflammatory pathways, such as type I interferon signaling and positive regulation of immune system processes. Interestingly, CD206+ Mφs were located in close proximity or even surrounded the ENS and outnumbered TIMP2+ Mφs, which were located further away from the ENS (Fig. 3e). To confirm that these Cd206+ MhcIIhi Mφs have a neuroprotective effect on the ENS, we nassessed their contribution to EGC proliferation in vitro (Fig. 3f). While Ly6c+ monocytes isolated 24 h post-injury did not alter the proliferation of EGCs, MHCIIhi Mφs from 72 h post-injury significantly induced EGC proliferation, underscoring their role in supporting EGC function (Fig. 3g). These results establish that CCR2+ monocytes differentiate into two distinct Mφ subpopulations with pro-resolving and/or neurotrophic functions.

CX3CR1GFP-based mapping matches unique Mφ subsets observed in scRNA-seq during muscularis inflammation

To further define the phenotype of the Mφ subpopulations identified using scRNA-seq at the protein level, we induced muscularis inflammation in CX3CR1gfp/+ mice (Fig. 4a, b). Upon muscularis inflammation, the percentage of homeostatic CX3CR1hi Mφs was drastically reduced with a concomitant increase of CX3CR1lo MHCIIhi and CX3CR1lo MHCIIlo Mφs. As CCR2 and CD206 have been described as essential markers for recruited and anti-inflammatory Mφs respectively, their protein levels were determined in these CX3CR1hi/lo Mφ subpopulations (Fig. 4c–h and Supplementary Fig. 4a, b). In line with previous findings, CX3CR1hi MHCIIhi Mφs were mainly CD206+ and CCR2− at homeostasis (Fig. 4c–e). However, this subpopulation was gradually replaced by a combination of CX3CR1lo MHCIIlo and CX3CR1lo MHCIIhi Mφs, resembling Timp2+ and Cd206+ Mφs from our scRNA-seq dataset, respectively (Fig. 4c–h). Interestingly, CD206+ CX3CR1lo MHCIIhi Mφs 10-fold outnumbered CX3CR1lo MHCIIlo Mφs, further underscoring the importance of these anti-inflammatory CD206+ MHCIIhi Mφs (Supplementary Fig. 4a, b). Overall, our data validated at protein level the presence of two distinct Mφ subpopulations during the resolution of muscularis inflammation which are derived from CCR2+ monocytes and are anti-inflammatory in nature.

Fig. 4: Flow cytometry validates unique Mφ subpopulations during muscularis inflammation.figure 4

a–h from naïve CX3CR1GFP/+ mice, 24 h and 72 h after muscularis inflammation. a Contour plots representing CX3CR1 expression in Ly6C− MHCIIhi Mφs (left). Percentages and absolute numbers of CX3CR1hi and CX3CR1lo cells from Ly6C− MHCIIhi Mφs are shown as mean ± SEM (right). b Contour plots representing CX3CR1 expression in Ly6C− MHCIIlo Mφs (left). Percentages and absolute numbers of CX3CR1hi and CX3CR1lo cells from Ly6C− MHCIIlo Mφs are shown as mean ± SEM (right). ch CD206 and CCR2 expression in Ly6C− MHCIIhi and MHCIIlo Mφs. Contour plots representing CD206 or CCR2 expression in Ly6C− MHCIIhi (c) and Ly6C− MHCIIlo Mφs (f). Percentages of CD206+ CX3CR1hi, CD206− CX3CR1hi and CD206+ CX3CR1lo cells in the LY6C− MHCIIhi Mφs (d) and MHCIIlo Mφs (g). Percentages of CCR2+ CX3CR1hi, CCR2− CX3CR1hi and CCR2+ CX3CR1lo cells in the LY6C− MHCIIhi Mφs (e) and MHCIIlo Mφs (h). One-way ANOVA; test *p < 0.05; **p < 0.01; ns not significant.

In line with our scRNA-seq datasets, we observed a drastic reduction in the percentage of homeostatic CX3CR1hi Mφs upon the induction of muscularis inflammation (Fig. 2c, d). To determine whether these CX3CR1hi Mφs are replaced by incoming monocyte-derived Mφs, CX3CR1+ resident Mφs were mapped by using a tamoxifen-inducible CX3CR1CreERT2 strain backcrossed with Rosa26-LSL-YFP mice. By comparing circulating unlabeled blood monocytes with resident YFP+ Mφs, we could show that resident Mφs did not diminish in number during muscularis inflammation as quantified by immunofluorescence and flow cytometry (Supplementary Fig. 4c–f). Taken together, these results indicate that CX3CR1hi Mφs were present alongside CX3CR1lo mature Mφs during muscularis inflammation.

Damage-activated EGCs initiate the recruitment and differentiation of monocytes upon muscularis inflammation

Monocytes originate from progenitors in the bone marrow and rely on local chemokine production such as MCP-1/CCL2 for their recruitment at the site of inflammation23. Considering the extensive interaction between CCR2+ monocytes and the ENS in the inflamed muscularis6,11, we examined the production of the major chemoattractant Ccl2 in the muscularis during the early stage of surgery-induced inflammation. Analysis of isolated enteric ganglia 1.5 h post-injury showed an increased gene expression of Ccl2 and Csf1 (Fig. 5a). Moreover, immunofluorescent images showed that CCL2 was specifically produced by GFAP+ EGCs (Fig. 5b), leading us to conclude that during the early stages of muscularis inflammation, EGCs likely initiate the recruitment of monocytes via CCL2 to stimulate tissue repair.

Fig. 5: EGCs produce factors essential for the recruitment and differentiation of monocytes during inflammation.figure 5

a Relative mRNA levels for Ccl2 and Csf1 normalized to the housekeeping gene rpl32 from ganglia isolated from the muscularis of the small intestine from naïve wild-type mice and 1.5 h, 3 h and 24 h after muscularis inflammation. One-way ANOVA; test *p < 0.05; **p < 0.01; ns not significant. b Immunofluorescent images of muscularis whole-mount preparations at homeostasis and 1.5 h after the induction of muscularis inflammation stained for GFAP (green), HuC/D (gray) and CCL2 (purple). Scale bar (25x) 25 µm, (63x) 15 µm. c Experimental overview of experiments in PLP-CreERT2 Rpl22HA mice. d Heatmap of HA-enriched differentially expressed genes between immunoprecipitated samples from naïve PLP-CreERT2 Rpl22HA mice and 3 h after intestinal manipulation. e Selected significant GO terms enriched (GSEA) in PLP1+ EGCs 3 h post-injury compared to naive PLP1+ EGCs. f Heat map of ligand-target pairs showing regulatory potential scores between top positively correlated prioritized ligands and their target genes among the differentially expressed genes between Ly6c+ monocytes and Ccr2+ int Mφs. g Circos plot showing top NicheNet ligand-receptor pairs between EGCs and Ly6c+ monocytes corresponding to the prioritized ligands in Fig. 5f. h Schematic overview of interactions between EGCs and infiltrating Ly6c+ monocytes.

To further explore the role of EGCs during the early phase of muscularis inflammation, PLPCreERT2 Rpl22HA mice were used, which allow immunoprecipitation (IP) of ribosome‐bound mRNAs from PLP1+ EGCs to study the transcriptome of EGCs at homeostasis and during early inflammation (3 h post-injury) (Fig. 5c and Supplementary Fig. 5a, b)24,25,26. Unlike pro-inflammatory reactive astrocytes during brain injury27, EGCs were activated early after muscularis inflammation and produced increased amounts of factors that are able to promote the differentiation of anti-inflammatory Mφs, such as Lif, Serpine-1, Gdf15, Gdnf, Cxcl10 and Csf1 (Fig. 5d and Supplementary Fig. 5c). To explore which pathways are activated in EGCs, gene set enrichment analysis was performed. Positive normalized enrichment scores were identified for response to ROS and cytokines including IL-1, indicating that EGCs are able to sense tissue damage in the muscularis micro-environment to initiate an appropriate immune response (Fig. 5e). These results were further underscored by showing that neurosphere-derived EGCs stimulated with IL1-α and/or IL1-β produced increased amounts of Ccl2 compared to unstimulated EGCs (Supplementary Fig. 5d). Interestingly, there was also an overrepresentation of genes involved in the regulation of myeloid differentiation during early muscularis inflammation in EGCs (Fig. 5e and Supplementary Fig. 5e). These results suggest that activation of EGCs by cytokines including IL-1 could lead to both the recruitment and differentiation of monocytes during the early stages of muscularis inflammation.

To determine whether EGCs are able to stimulate monocyte differentiation during muscularis inflammation, we analyzed the expression of ligand-receptor pairs based on differentially expressed genes in PLP1+ EGCs 3 h post-injury and Ly6c+ monocytes undergoing differentiation into Ccr2+ int Mφs. Their expression data was combined with prior knowledge of signaling and gene regulatory networks using Nichenet28. To identify genes regulated by the identified ligands, putative ligand-gene interactions were scored by NicheNet according to their “regulatory potential” (Fig. 5f). We next assessed whether the expression of the receptors for the putative ligand-receptor interaction were altered when Ly6c+ monocytes underwent differentiation into Ccr2+ int Mφs (Supplementary Fig. 5f–h). By determining a threshold for the receptor expression, we identified the following ligand-receptor interactions between EGCs and differentiating monocytes: Csf1-Csf1r, Tgfb1-Tgfbr2/Acvrl1/Tgfbr1, Ccl2-Ccr5/Ccr1/Ccr2, Lif-Lifr/Il6st, Cyr61-Itgam/Itgb2, and Psap-Lrp1 (Fig. 5g and Supplementary Fig. 5g). Taken together, damage to the muscularis micro-environment leads to activation of EGCs, that are able to recruit monocytes to the site of inflammation via CCL2 and that produce factors that have the potential to promote anti-inflammatory Mφ differentiation (Fig. 5h).

EGCs promote the differentiation of monocytes into pro-resolving CD206± Mφs in vitro

To directly assess the functional interaction between EGCs and monocytes, neurosphere-derived EGCs were analyzed by bulk RNAseq. The results revealed high expression of cytokines involved in the induction of anti-inflammatory Mφ differentiation (Supplementary Fig. 6a–c), similar to those observed in vivo in EGCs, including Lif, Csf1, Tgfb1 and Ccl2 (Fig. 5d, f). To demonstrate that EGC-derived factors are able to stimulate monocyte differentiation, an ex vivo model was set-up to co-culture bone marrow-derived monocytes with the supernatant of EGCs (Fig. 6a)29. Co-culture of bone marrow monocytes with EGC supernatant resulted in an upregulation of several anti-inflammatory markers such as Arg1, Il10 and Mrc1, while pro-inflammatory markers were downregulated, including Il6 and Il12 (Fig. 6b). In addition, when bone marrow monocytes were exposed to bacterial components (LPS), a similar anti-inflammatory effect of EGC supernatant on monocytes (EGCs+LPS) was observed compared to LPS alone on monocytes (Supplementary Fig. 6d). Finally, to confirm that muscularis monocytes responded to EGC supernatant in a similar manner as bone marrow monocytes given their different origin, ex vivo experiments were performed on sorted Ly6C+ monocytes from the muscularis 24 h post-injury (Fig. 6c). Also in this setting, monocytes acquired an anti-inflammatory phenotype upon co-culture with EGC supernatant with increased expression of Arg1 and decreased expression of il12 similar to that seen in bone marrow monocytes (Fig. 6d and Supplementary Fig. 6e). Furthermore, flow cytometric analysis of bone marrow monocytes stimulated with EGC supernatant confirmed the increased expression of CD206 at protein level, while CCR2 expression was reduced, along with increased survival compared to control monocytes (Fig. 6e–h). These results were further underscored by the ability of EGC secreted factors to induce the expression of CD206 on sorted Ly6C+ monocytes from the muscularis 24 h post-injury and decrease the expression of CCR2 (Fig. 6i). Taken together, our ex vivo data suggest a direct interaction between EGCs and monocytes that could support the resolution of inflammation.

Fig. 6: EGCs stimulate the differentiation of monocytes into anti-inflammatory CD206+ Mφs in part via CSF-1 in vitro.figure 6

a Experimental outline of in vitro primary bone marrow monocytes stimulated with supernatant of EGCs. b Bone marrow-derived monocytes were stimulated for 24 h with/without supernatant of EGCs. Relative mRNA levels for pro- and anti-inflammatory cytokines normalized to the housekeeping gene rpl32 in bone marrow monocytes cultured with/without EGC supernatant. c Experimental outline of in vitro experiment using sorted Ly6C+ MHCII− monocytes stimulated with/without EGC supernatant for 24 h. d Ly6C+ MHCII− monocytes were sorted from the muscularis of WT mice 24 h after the induction of muscularis inflammation and were stimulated for 24 h with/without supernatant of EGCs. Relative mRNA levels of pro- and anti-inflammatory mediators normalized to the housekeeping gene rpl32 in sorted Ly6C+ MHCII− monocytes stimulated with/without EGC supernatant. eh Bone marrow monocytes were cultured for 24–48 h with/without EGC supernatant and supplemented with anti-CSF1r antibody. e Contour plots of bone marrow monocytes showing expression of CD206 (top) or CCR2 (bottom) upon culture for 48 h with/without EGC supernatant and supplemented with anti-CSF1r antibody. f Brightfield images of monocytes upon culture for 24 h with/without EGC supernatant. g Quantification of 7-AAD+ cells in bone marrow monocytes cultured for 24 h or 48 h with/without EGC supernatant and supplemented with anti-CSF1r antibody. h Percentages of CCR2+ and CD206+ cells in live CD45+ CD11b+ Ly6G− CD64+ population. i Ly6C+ MHCII− monocytes were sorted from the muscularis of WT mice 24 h after the induction of muscularis inflammation and were cultured with/without EGC supernatant and supplemented with anti-CSF1r antibody for 48 h. Percentages of CCR2+ and CD206+ cells in live CD45+ CD11b+ Ly6G− CD64+ population. ad T-test. gi one-way ANOVA. *p < 0.05; **p < 0.01.

As cellular interaction analysis by NicheNet identified Csf1-Csf1r as the top candidate for potential ligand-receptor interaction between EGCs and monocytes (Fig. 5f), we next aimed to determine whether EGC-derived CSF1 had the potential to induce anti-inflammatory CD206+ Mφs in our ex vivo co-culture model by antibody-mediated CSF1r blockade. Anti-CSF1r treatment in combination with EGC supernatant attenuated the differentiation of both bone marrow and muscularis monocytes into anti-inflammatory Mφs with reduced CD206 expression, while increased CCR2 expression was only observed for bone marrow monocytes compared to cells stimulated with EGC supernatant alone (Fig. 6e–i). No effect was observed on survival, CCR2 and CD206 expression when bone marrow monocytes were treated with anti-CSF1r compared to control monocytes, while stimulation of bone marrow monocytes with CSF-1 increased survival and reduced CCR2 expression with no effect on CD206 expression (Supplementary Fig. 6f–h). These results underscore that CSF-1 together with other factors are crucial for the differentiation of monocytes into anti-inflammatory CD206+ Mφs. Altogether, these data provide evidence for a direct interaction between monocytes and EGC-derived ligands ex vivo which stimulate the differentiation into anti-inflammatory CD206+ Mφs.

EGCs are involved in the differentiation of monocytes into CD206± Mφs, which are able to limit damage to EGCs through CSF-1 signaling during muscularis inflammation

In order to definitively determine the contribution of EGCs in the differentiation of monocytes into anti-inflammatory CD206+ Mφs, 8-week-old PLPCreERT2/+ iDTR (PLP-iDTR) mice were injected with tamoxifen and a small part of the small intestine was exposed to saline or diphteria toxin (DT) at 12 weeks of age following the induction of muscularis inflammation. 72 h post-injury, there was a significant reduction of the volume and intensity of GFAP (Supplementary Fig. 7a, b) as well as in the number of Sox10+ EGCs (Supplementary Fig. 7a, c) in the DT treated PLP-iDTR mice compared to the control animals, thereby confirming EGC depletion upon DT administration. While no differences were observed in the percentage and cell numbers of the myeloid populations 72 h after the induction of muscularis inflammation (Fig. 7a and Supplementary Fig. 7d), there was a significant reduction of the MFI of CD206 in Ly6C− MHCIIhi Mφs of PLP-iDTR mice treated with DT compared with their control (Fig. 7b, c). These results are in line with our scRNA-seq data, where the highest CD206 expression was observed in the Mφ subpopulation that expresses high levels of MHCII genes. Therefore, we can conclude that EGCs are able to stimulate the differentiation of monocytes into CD206+ MHCIIhi Mφs in vivo during muscularis inflammation.

Fig. 7: EGCs are crucial for monocyte differentiation into anti-inflammatory CD206+ Mφs in part via CSF-1 in vivo.figure 7

ac A small portion of the small intestine of PLPCreERT2 iDTR mice was exposed to saline or DT after intestinal manipulation and mice were sacrificed 72 h after the induction of muscularis inflammation. a Percentages of Ly6C+ MHCII− monocytes and Ly6C− MHCIIhi Mφs in live CD45+ CD11b+ Ly6G− CD64+ population. b Mean fluorescent intensity (MFI) of CD206 in Ly6C+ MHCII− monocytes and Ly6C− MHCIIhi Mφs. c Histogram of CD206 expression in Ly6C− MHCIIhi Mφs in control and DT exposed PLPCreERT2 iDTR mice 72 h after muscularis inflammation. dh Wild-type mice were gavaged daily with vehicle or PLX-3397 (50 mg/kg) starting from the day of the manipulation and sacrificed 72 h after the induction of muscularis inflammation. D Percentages of Ly6C+ MHCII− monocytes and Ly6C− MHCIIhi Mφs in live CD45+ CD11b+ Ly6G− CD64+ population. e Mean fluorescent intensity (MFI) of CD206 in Ly6C+ MHCII− monocytes and Ly6C− MHCIIhi Mφs. f Histogram of CD206 expression in Ly6C− MHCIIhi Mφs in control and PLX treated mice 72 h after muscularis inflammation. g Immunofluorescent images of muscularis whole-mounts in control and PLX treated mice 72 h after muscularis inflammation stained for SOX10 (green), HuC/D (red) and Ki-67 (purple). Scale bar 25 µm. h Quantification of the number of SOX10+ cells per field in control and PLX treated mice 72 h after muscularis inflammation (average of 4–5 pictures/mouse). i Quantification of the number of Ki-67+ SOX10+ cells per field in control and PLX treated mice 72 h after muscularis inflammation (N = 4–5 pictures/mouse). a, b; d, e; h, i. T-test. *p < 0.05; **p < 0.01.

Based on the evidence that EGC-derived CSF-1 is able to stimulate the differentiation of monocytes into CD206+ Mφs with an anti-inflammatory phenotype in vitro, we hypothesized that blocking monocyte differentiation towards anti-inflammatory CD206+ Mφs in vivo via CSF1R inhibition might have neurodegenerative effects on EGCs. To test this hypothesis, WT mice were treated daily with pexidartinib (PLX-3397), an oral tyrosine kinase inhibitor of CSF1R, from the day of the induction of muscularis inflammation until the sacrifice at 72 h post-injury. Although long-term CSF1R inhibition can lead to Mφ depletion in vivo30,31, short-term PLX-3397 treatment did not result in an overall reduction of differentiated Mφs. Rather, we observed an increased percentage and cell number of neutrophils, monocytes and MHCIIhi Mφs compared to control treated animals 72 h post-injury (Fig. 7d and Supplementary Fig. 7e, f), showing normal development of the Mφ compartment with increased muscularis inflammation. These results c

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